Long Lived Particles in MG5/PY8
Dear MG5 team
I'm trying to generate an event with long-lived particles and their decay products in the final state than shower the event in pythia8. I tried the following separately;
width = 2.81630690E-16
decay channels;
5.00000000E-01 3 1000022 -11 11 # BR(Chi_2 -> Chi_1 Fe_1^* Fe_1 )
5.00000000E-01 3 1000022 -13 13 # BR(Chi_2 -> Chi_1 Fe_2^* Fe_2 )
MG5 version;
version = 3.0.1
date = 2018-12-20
1) decaying the desired particle in madspin then feeding it to pythia
2) letting pythia decay the desired particle
3) adding the time of flight info
and the corresponding problems that I get is as follows;
1) the generated pythia events does not have long lived particles everything occurs in the prompt decay, I do not observe any displaced vertices etc, I tried to write the details about the particle in pythia card, but the result was the same
2) pythia just sets the width zero and tells me
PYTHIA Warning in SLHAinterface:
PYTHIA Warning in SLHAinterface:
...
1000023 ~chi_20 2 0 0 500.00000 0.00000 500.00000 500.00000 7.00659e+02 1 0 0 0 0
0 0 0.0000000 100 1000022 -11 11
1 0 0.0000000 100 1000022 -13 13
3) I tried both setting this from the run card and with madevent add_time_of_flight module but both gave me the following error
ValueError : could not convert string to float: ]]>
log file:
help add_time_of_flight
add_time_of_flight run_01
Traceback (most recent call last):
File "/home/
return self.onecmd_
File "/home/
return func(arg, **opt)
File "/home/
param_card = check_param_
File "/home/
self.
File "/home/
param.
File "/home/
self.value = float(data[0])
ValueError: could not convert string to float: ]]>
How can I possibly generate and shower long-lived particles with displaced vertices? Thank you very much
Best regards
Jack
Question information
- Language:
- English Edit question
- Status:
- Solved
- Assignee:
- No assignee Edit question
- Solved by:
- Olivier Mattelaer
- Solved:
- Last query:
- Last reply:
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Revision history for this message
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#1 |
Hi again
I turned around the problem by modifying MG5_aMC_
...L101
try: #modification
except: #modification
return #modification
self.value = float(data[0])
self.format = 'decay_table'
But I'm not sure how safe it is.
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Revision history for this message
|
#2 |
Hi,
If the lhe file is correctly written with the displaced vertex information, PY8 is suppose to use that information without any need of any additional flag on their side. Consequently if it is not the case, you can submit a bug report to Pythia8 authors.
Concerning your bug when running "add_time_
I do not reproduce the error when I run the following script:
import model heft
generate g g > z h > b b~ b b~
output
launch
launch -i
add_time_of_flight run_01
And this on both 2.6.6 and 3.0.1.
Now the problem seems to be a problem with your param_card format.
Difficult to know more without seeing the file but my guess is that you are missing a return line at the end of the file (or something like that). Can you copy the banner of the event file here? (or just the part of the param_card?
Concerning your modification, it is quite dangerous and can lead to bias in general.
Cheers,
Olivier
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Revision history for this message
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#3 |
Hi Oliver
Thanks for the quick response
>Now the problem seems to be a problem with your param_card format.
>Difficult to know more without seeing the file but my guess is that you are missing a return line at the end of the file (or something >like that). Can you copy the banner of the event file here? (or just the part of the param_card?
I'm adding the banner below and as you said there is ']]>' right before </slha> but I don't see it anywhere in the param card.
>Concerning your modification, it is quite dangerous and can lead to bias in general.
Thanks, I'm changing it back to normal
Best regards
Jack
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# W. Porod, Comput. Phys. Commun. 153 (2003) 275-315, hep-ph/0301101
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# F. Staub; arXiv:0806.0538 (online manual)
# F. Staub; Comput. Phys. Commun. 181 (2010) 1077-1086; arXiv:0909.2863
# F. Staub; Comput. Phys. Commun. 182 (2011) 808-833; arXiv:1002.0840
# F. Staub; Comput. Phys. Commun. 184 (2013) 1792-1809; arXiv:1207.0906
# F. Staub; Comput. Phys. Commun. 185 (2014) 1773-1790; arXiv:1309.7223
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3 0.00000000E+00 # M3
300 0.00000000E+00 # MDB
301 0.00000000E+00 # MDW
302 0.00000000E+00 # MDO
Block Yd Q= 1.50000000E+03 # (SUSY Scale)
1 1 3.04917106E-05 # Real(Yd(1,1),dp)
1 2 1.93632489E-11 # Real(Yd(1,2),dp)
1 3 -4.63469474E-10 # Real(Yd(1,3),dp)
2 1 3.67888991E-10 # Real(Yd(2,1),dp)
2 2 5.79320003E-04 # Real(Yd(2,2),dp)
2 3 6.07218576E-08 # Real(Yd(2,3),dp)
3 1 -4.53070301E-07 # Real(Yd(3,1),dp)
3 2 3.12428739E-06 # Real(Yd(3,2),dp)
3 3 2.95022192E-02 # Real(Yd(3,3),dp)
Block IMYd Q= 1.50000000E+03 # (SUSY Scale)
1 1 0.00000000E+00 # Aimag(Yd(1,1))
1 2 0.00000000E+00 # Aimag(Yd(1,2))
1 3 0.00000000E+00 # Aimag(Yd(1,3))
2 1 0.00000000E+00 # Aimag(Yd(2,1))
2 2 0.00000000E+00 # Aimag(Yd(2,2))
2 3 0.00000000E+00 # Aimag(Yd(2,3))
3 1 0.00000000E+00 # Aimag(Yd(3,1))
3 2 0.00000000E+00 # Aimag(Yd(3,2))
3 3 0.00000000E+00 # Aimag(Yd(3,3))
Block Ye Q= 1.50000000E+03 # (SUSY Scale)
1 1 6.54148017E-06 # Real(Ye(1,1),dp)
1 2 0.00000000E+00 # Real(Ye(1,2),dp)
1 3 0.00000000E+00 # Real(Ye(1,3),dp)
2 1 0.00000000E+00 # Real(Ye(2,1),dp)
2 2 1.35257062E-03 # Real(Ye(2,2),dp)
2 3 0.00000000E+00 # Real(Ye(2,3),dp)
3 1 0.00000000E+00 # Real(Ye(3,1),dp)
3 2 0.00000000E+00 # Real(Ye(3,2),dp)
3 3 2.27440507E-02 # Real(Ye(3,3),dp)
Block IMYe Q= 1.50000000E+03 # (SUSY Scale)
1 1 0.00000000E+00 # Aimag(Ye(1,1))
1 2 0.00000000E+00 # Aimag(Ye(1,2))
1 3 0.00000000E+00 # Aimag(Ye(1,3))
2 1 0.00000000E+00 # Aimag(Ye(2,1))
2 2 0.00000000E+00 # Aimag(Ye(2,2))
2 3 0.00000000E+00 # Aimag(Ye(2,3))
3 1 0.00000000E+00 # Aimag(Ye(3,1))
3 2 0.00000000E+00 # Aimag(Ye(3,2))
3 3 0.00000000E+00 # Aimag(Ye(3,3))
Block Yu Q= 1.50000000E+03 # (SUSY Scale)
1 1 7.38619768E-06 # Real(Yu(1,1),dp)
1 2 1.71231698E-06 # Real(Yu(1,2),dp)
1 3 2.64500086E-08 # Real(Yu(1,3),dp)
2 1 -8.55906333E-04 # Real(Yu(2,1),dp)
2 2 3.68957704E-03 # Real(Yu(2,2),dp)
2 3 1.57318790E-04 # Real(Yu(2,3),dp)
3 1 5.54601646E-03 # Real(Yu(3,1),dp)
3 2 -3.82440564E-02 # Real(Yu(3,2),dp)
3 3 9.23906555E-01 # Real(Yu(3,3),dp)
Block IMYu Q= 1.50000000E+03 # (SUSY Scale)
1 1 0.00000000E+00 # Aimag(Yu(1,1))
1 2 0.00000000E+00 # Aimag(Yu(1,2))
1 3 0.00000000E+00 # Aimag(Yu(1,3))
2 1 0.00000000E+00 # Aimag(Yu(2,1))
2 2 0.00000000E+00 # Aimag(Yu(2,2))
2 3 0.00000000E+00 # Aimag(Yu(2,3))
3 1 0.00000000E+00 # Aimag(Yu(3,1))
3 2 0.00000000E+00 # Aimag(Yu(3,2))
3 3 0.00000000E+00 # Aimag(Yu(3,3))
Block Td Q= 1.50000000E+03 # (SUSY Scale)
1 1 0.00000000E+00 # Real(Td(1,1),dp)
1 2 0.00000000E+00 # Real(Td(1,2),dp)
1 3 0.00000000E+00 # Real(Td(1,3),dp)
2 1 0.00000000E+00 # Real(Td(2,1),dp)
2 2 0.00000000E+00 # Real(Td(2,2),dp)
2 3 0.00000000E+00 # Real(Td(2,3),dp)
3 1 0.00000000E+00 # Real(Td(3,1),dp)
3 2 0.00000000E+00 # Real(Td(3,2),dp)
3 3 0.00000000E+00 # Real(Td(3,3),dp)
Block IMTd Q= 1.50000000E+03 # (SUSY Scale)
1 1 0.00000000E+00 # Aimag(Td(1,1))
1 2 0.00000000E+00 # Aimag(Td(1,2))
1 3 0.00000000E+00 # Aimag(Td(1,3))
2 1 0.00000000E+00 # Aimag(Td(2,1))
2 2 0.00000000E+00 # Aimag(Td(2,2))
2 3 0.00000000E+00 # Aimag(Td(2,3))
3 1 0.00000000E+00 # Aimag(Td(3,1))
3 2 0.00000000E+00 # Aimag(Td(3,2))
3 3 0.00000000E+00 # Aimag(Td(3,3))
Block Te Q= 1.50000000E+03 # (SUSY Scale)
1 1 0.00000000E+00 # Real(Te(1,1),dp)
1 2 0.00000000E+00 # Real(Te(1,2),dp)
1 3 0.00000000E+00 # Real(Te(1,3),dp)
2 1 0.00000000E+00 # Real(Te(2,1),dp)
2 2 0.00000000E+00 # Real(Te(2,2),dp)
2 3 0.00000000E+00 # Real(Te(2,3),dp)
3 1 0.00000000E+00 # Real(Te(3,1),dp)
3 2 0.00000000E+00 # Real(Te(3,2),dp)
3 3 0.00000000E+00 # Real(Te(3,3),dp)
Block IMTe Q= 1.50000000E+03 # (SUSY Scale)
1 1 0.00000000E+00 # Aimag(Te(1,1))
1 2 0.00000000E+00 # Aimag(Te(1,2))
1 3 0.00000000E+00 # Aimag(Te(1,3))
2 1 0.00000000E+00 # Aimag(Te(2,1))
2 2 0.00000000E+00 # Aimag(Te(2,2))
2 3 0.00000000E+00 # Aimag(Te(2,3))
3 1 0.00000000E+00 # Aimag(Te(3,1))
3 2 0.00000000E+00 # Aimag(Te(3,2))
3 3 0.00000000E+00 # Aimag(Te(3,3))
Block Tu Q= 1.50000000E+03 # (SUSY Scale)
1 1 0.00000000E+00 # Real(Tu(1,1),dp)
1 2 0.00000000E+00 # Real(Tu(1,2),dp)
1 3 0.00000000E+00 # Real(Tu(1,3),dp)
2 1 0.00000000E+00 # Real(Tu(2,1),dp)
2 2 0.00000000E+00 # Real(Tu(2,2),dp)
2 3 0.00000000E+00 # Real(Tu(2,3),dp)
3 1 0.00000000E+00 # Real(Tu(3,1),dp)
3 2 0.00000000E+00 # Real(Tu(3,2),dp)
3 3 0.00000000E+00 # Real(Tu(3,3),dp)
Block IMTu Q= 1.50000000E+03 # (SUSY Scale)
1 1 0.00000000E+00 # Aimag(Tu(1,1))
1 2 0.00000000E+00 # Aimag(Tu(1,2))
1 3 0.00000000E+00 # Aimag(Tu(1,3))
2 1 0.00000000E+00 # Aimag(Tu(2,1))
2 2 0.00000000E+00 # Aimag(Tu(2,2))
2 3 0.00000000E+00 # Aimag(Tu(2,3))
3 1 0.00000000E+00 # Aimag(Tu(3,1))
3 2 0.00000000E+00 # Aimag(Tu(3,2))
3 3 0.00000000E+00 # Aimag(Tu(3,3))
Block MSQ2 Q= 1.50000000E+03 # (SUSY Scale)
1 1 6.25000000E+06 # Real(mq2(1,1),dp)
1 2 -3.40483057E+00 # Real(mq2(1,2),dp)
1 3 8.11192123E+01 # Real(mq2(1,3),dp)
2 1 -3.40483057E+00 # Real(mq2(2,1),dp)
2 2 6.25000000E+06 # Real(mq2(2,2),dp)
2 3 -5.59387671E+02 # Real(mq2(2,3),dp)
3 1 8.11192123E+01 # Real(mq2(3,1),dp)
3 2 -5.59387671E+02 # Real(mq2(3,2),dp)
3 3 1.25000000E+07 # Real(mq2(3,3),dp)
Block IMMSQ2 Q= 1.50000000E+03 # (SUSY Scale)
1 1 0.00000000E+00 # Aimag(mq2(1,1))
1 2 0.00000000E+00 # Aimag(mq2(1,2))
1 3 0.00000000E+00 # Aimag(mq2(1,3))
2 1 0.00000000E+00 # Aimag(mq2(2,1))
2 2 0.00000000E+00 # Aimag(mq2(2,2))
2 3 0.00000000E+00 # Aimag(mq2(2,3))
3 1 0.00000000E+00 # Aimag(mq2(3,1))
3 2 0.00000000E+00 # Aimag(mq2(3,2))
3 3 0.00000000E+00 # Aimag(mq2(3,3))
Block MSL2 Q= 1.50000000E+03 # (SUSY Scale)
1 1 2.24973148E+06 # Real(ml2(1,1),dp)
1 2 0.00000000E+00 # Real(ml2(1,2),dp)
1 3 0.00000000E+00 # Real(ml2(1,3),dp)
2 1 0.00000000E+00 # Real(ml2(2,1),dp)
2 2 2.24973148E+06 # Real(ml2(2,2),dp)
2 3 0.00000000E+00 # Real(ml2(2,3),dp)
3 1 0.00000000E+00 # Real(ml2(3,1),dp)
3 2 0.00000000E+00 # Real(ml2(3,2),dp)
3 3 2.24973047E+06 # Real(ml2(3,3),dp)
Block IMMSL2 Q= 1.50000000E+03 # (SUSY Scale)
1 1 0.00000000E+00 # Aimag(ml2(1,1))
1 2 0.00000000E+00 # Aimag(ml2(1,2))
1 3 0.00000000E+00 # Aimag(ml2(1,3))
2 1 0.00000000E+00 # Aimag(ml2(2,1))
2 2 0.00000000E+00 # Aimag(ml2(2,2))
2 3 0.00000000E+00 # Aimag(ml2(2,3))
3 1 0.00000000E+00 # Aimag(ml2(3,1))
3 2 0.00000000E+00 # Aimag(ml2(3,2))
3 3 0.00000000E+00 # Aimag(ml2(3,3))
Block MSD2 Q= 1.50000000E+03 # (SUSY Scale)
1 1 6.25000000E+06 # Real(md2(1,1),dp)
1 2 -1.63419771E-09 # Real(md2(1,2),dp)
1 3 1.99342952E-06 # Real(md2(1,3),dp)
2 1 -1.63419771E-09 # Real(md2(2,1),dp)
2 2 6.25000000E+06 # Real(md2(2,2),dp)
2 3 -2.61173380E-04 # Real(md2(2,3),dp)
3 1 1.99342952E-06 # Real(md2(3,1),dp)
3 2 -2.61173380E-04 # Real(md2(3,2),dp)
3 3 1.25000000E+07 # Real(md2(3,3),dp)
Block IMMSD2 Q= 1.50000000E+03 # (SUSY Scale)
1 1 0.00000000E+00 # Aimag(md2(1,1))
1 2 0.00000000E+00 # Aimag(md2(1,2))
1 3 0.00000000E+00 # Aimag(md2(1,3))
2 1 0.00000000E+00 # Aimag(md2(2,1))
2 2 0.00000000E+00 # Aimag(md2(2,2))
2 3 0.00000000E+00 # Aimag(md2(2,3))
3 1 0.00000000E+00 # Aimag(md2(3,1))
3 2 0.00000000E+00 # Aimag(md2(3,2))
3 3 0.00000000E+00 # Aimag(md2(3,3))
Block MSU2 Q= 1.50000000E+03 # (SUSY Scale)
1 1 6.25000000E+06 # Real(mu2(1,1),dp)
1 2 0.00000000E+00 # Real(mu2(1,2),dp)
1 3 1.39643313E-08 # Real(mu2(1,3),dp)
2 1 0.00000000E+00 # Real(mu2(2,1),dp)
2 2 6.25000000E+06 # Real(mu2(2,2),dp)
2 3 8.29722515E-05 # Real(mu2(2,3),dp)
3 1 1.39643313E-08 # Real(mu2(3,1),dp)
3 2 8.29722515E-05 # Real(mu2(3,2),dp)
3 3 1.25000000E+07 # Real(mu2(3,3),dp)
Block IMMSU2 Q= 1.50000000E+03 # (SUSY Scale)
1 1 0.00000000E+00 # Aimag(mu2(1,1))
1 2 0.00000000E+00 # Aimag(mu2(1,2))
1 3 0.00000000E+00 # Aimag(mu2(1,3))
2 1 0.00000000E+00 # Aimag(mu2(2,1))
2 2 0.00000000E+00 # Aimag(mu2(2,2))
2 3 0.00000000E+00 # Aimag(mu2(2,3))
3 1 0.00000000E+00 # Aimag(mu2(3,1))
3 2 0.00000000E+00 # Aimag(mu2(3,2))
3 3 0.00000000E+00 # Aimag(mu2(3,3))
Block MSE2 Q= 1.50000000E+03 # (SUSY Scale)
1 1 2.25210023E+06 # Real(me2(1,1),dp)
1 2 0.00000000E+00 # Real(me2(1,2),dp)
1 3 0.00000000E+00 # Real(me2(1,3),dp)
2 1 0.00000000E+00 # Real(me2(2,1),dp)
2 2 2.25210022E+06 # Real(me2(2,2),dp)
2 3 0.00000000E+00 # Real(me2(2,3),dp)
3 1 0.00000000E+00 # Real(me2(3,1),dp)
3 2 0.00000000E+00 # Real(me2(3,2),dp)
3 3 2.25209819E+06 # Real(me2(3,3),dp)
Block IMMSE2 Q= 1.50000000E+03 # (SUSY Scale)
1 1 0.00000000E+00 # Aimag(me2(1,1))
1 2 0.00000000E+00 # Aimag(me2(1,2))
1 3 0.00000000E+00 # Aimag(me2(1,3))
2 1 0.00000000E+00 # Aimag(me2(2,1))
2 2 0.00000000E+00 # Aimag(me2(2,2))
2 3 0.00000000E+00 # Aimag(me2(2,3))
3 1 0.00000000E+00 # Aimag(me2(3,1))
3 2 0.00000000E+00 # Aimag(me2(3,2))
3 3 0.00000000E+00 # Aimag(me2(3,3))
Block MASS # Mass spectrum
# PDG code mass particle
2000003 2.56854968E+03 # SsR
2000001 2.56854970E+03 # SdR
1000001 2.57560535E+03 # SdL
1000003 2.57561205E+03 # SsL
2000005 3.59318809E+03 # Sb2
1000005 3.60691618E+03 # Sb1
2000004 2.56940276E+03 # ScR
2000002 2.56940301E+03 # SuR
1000002 2.57505076E+03 # SuL
1000004 2.57506551E+03 # ScL
1000006 3.60399143E+03 # St1
2000006 3.61257196E+03 # St2
2000015 1.50200195E+03 # Stau2
2000013 1.50214205E+03 # SmuR
2000011 1.50214259E+03 # SeR
1000011 1.50374555E+03 # SeL
1000013 1.50374603E+03 # SmuL
1000015 1.50386823E+03 # Stau1
1000016 1.50239101E+03 # Snu_tau
1000014 1.50239761E+03 # Snu_mu
1000012 1.50239763E+03 # Snu_e
25 1.10694718E+02 # hh_1
35 1.85637001E+03 # hh_2
45 2.25202843E+03 # hh_3
55 2.68990385E+03 # hh_4
36 6.35466142E+02 # Ah_2
46 2.63244944E+03 # Ah_3
56 2.68885973E+03 # Ah_4
37 6.05990017E+02 # Hpm_2
47 1.84692168E+03 # Hpm_3
57 2.68927708E+03 # Hpm_4
22 0.00000000E+00 # VP
23 9.11887000E+01 # VZ
21 0.00000000E+00 # VG
24 7.92402623E+01 # VWm
1 5.00000000E-03 # Fd_1
3 9.50000000E-02 # Fd_2
5 4.18000000E+00 # Fd_3
2 2.50000000E-03 # Fu_1
4 1.27000000E+00 # Fu_2
6 1.73500000E+02 # Fu_3
11 5.10998930E-04 # Fe_1
13 1.05658372E-01 # Fe_2
15 1.77669000E+00 # Fe_3
12 0.00000000E+00 # Fv_1
14 0.00000000E+00 # Fv_2
16 0.00000000E+00 # Fv_3
1000021 2.00866180E+03 # Glu_1
2000021 2.00866696E+03 # Glu_2
3000021 3.94150134E+03 # phiO
3000022 1.64728179E+03 # sigmaO
1000022 1.99873694E+02 # Chi_1
1000023 2.03646245E+02 # Chi_2
1000025 4.02591269E+02 # Chi_3
1000035 4.21716191E+02 # Chi_4
1000045 5.37139248E+02 # Chi_5
1000055 5.48667802E+02 # Chi_6
1000024 3.99673292E+02 # Cha_1
1000037 5.36418776E+02 # Cha_2
1000047 5.49341767E+02 # Cha_3
Block LSP # LSP and NLSP
1 1000022 # LSP
2 1000023 # NLSP
Block DSQMIX Q= 1.50000000E+03 # ()
1 1 -9.71812783E-01 # Real(ZD(1,1),dp)
1 2 -2.35753800E-01 # Real(ZD(1,2),dp)
1 3 -1.97667271E-05 # Real(ZD(1,3),dp)
1 4 5.23078054E-05 # Real(ZD(1,4),dp)
1 5 2.41087923E-04 # Real(ZD(1,5),dp)
1 6 -3.41727910E-08 # Real(ZD(1,6),dp)
2 1 -2.35753921E-01 # Real(ZD(2,1),dp)
2 2 9.71812255E-01 # Real(ZD(2,2),dp)
2 3 2.09708000E-04 # Real(ZD(2,3),dp)
2 4 1.26769005E-05 # Real(ZD(2,4),dp)
2 5 -9.92817422E-04 # Real(ZD(2,5),dp)
2 6 3.62538744E-07 # Real(ZD(2,6),dp)
3 1 2.74682393E-05 # Real(ZD(3,1),dp)
3 2 -1.89413290E-04 # Real(ZD(3,2),dp)
3 3 9.09363098E-01 # Real(ZD(3,3),dp)
3 4 2.11589465E-11 # Real(ZD(3,4),dp)
3 5 -2.77214882E-09 # Real(ZD(3,5),dp)
3 6 -4.16003268E-01 # Real(ZD(3,6),dp)
4 1 5.38220212E-05 # Real(ZD(4,1),dp)
4 2 4.37358094E-09 # Real(ZD(4,2),dp)
4 3 -1.64982017E-09 # Real(ZD(4,3),dp)
4 4 9.99999999E-01 # Real(ZD(4,4),dp)
4 5 -7.65712983E-06 # Real(ZD(4,5),dp)
4 6 -3.69628624E-12 # Real(ZD(4,6),dp)
5 1 2.32137608E-07 # Real(ZD(5,1),dp)
5 2 1.02167006E-03 # Real(ZD(5,2),dp)
5 3 2.16068822E-07 # Real(ZD(5,3),dp)
5 4 7.65710889E-06 # Real(ZD(5,4),dp)
5 5 9.99999478E-01 # Real(ZD(5,5),dp)
5 6 4.84020844E-10 # Real(ZD(5,6),dp)
6 1 -1.26232717E-05 # Real(ZD(6,1),dp)
6 2 8.70465523E-05 # Real(ZD(6,2),dp)
6 3 -4.16003259E-01 # Real(ZD(6,3),dp)
6 4 -1.06518583E-11 # Real(ZD(6,4),dp)
6 5 1.39555930E-09 # Real(ZD(6,5),dp)
6 6 -9.09363118E-01 # Real(ZD(6,6),dp)
Block IMDSQMIX Q= 1.50000000E+03 # ()
1 1 0.00000000E+00 # Aimag(ZD(1,1))
1 2 0.00000000E+00 # Aimag(ZD(1,2))
1 3 0.00000000E+00 # Aimag(ZD(1,3))
1 4 0.00000000E+00 # Aimag(ZD(1,4))
1 5 0.00000000E+00 # Aimag(ZD(1,5))
1 6 0.00000000E+00 # Aimag(ZD(1,6))
2 1 0.00000000E+00 # Aimag(ZD(2,1))
2 2 0.00000000E+00 # Aimag(ZD(2,2))
2 3 0.00000000E+00 # Aimag(ZD(2,3))
2 4 0.00000000E+00 # Aimag(ZD(2,4))
2 5 0.00000000E+00 # Aimag(ZD(2,5))
2 6 0.00000000E+00 # Aimag(ZD(2,6))
3 1 0.00000000E+00 # Aimag(ZD(3,1))
3 2 0.00000000E+00 # Aimag(ZD(3,2))
3 3 0.00000000E+00 # Aimag(ZD(3,3))
3 4 0.00000000E+00 # Aimag(ZD(3,4))
3 5 0.00000000E+00 # Aimag(ZD(3,5))
3 6 0.00000000E+00 # Aimag(ZD(3,6))
4 1 0.00000000E+00 # Aimag(ZD(4,1))
4 2 0.00000000E+00 # Aimag(ZD(4,2))
4 3 0.00000000E+00 # Aimag(ZD(4,3))
4 4 0.00000000E+00 # Aimag(ZD(4,4))
4 5 0.00000000E+00 # Aimag(ZD(4,5))
4 6 0.00000000E+00 # Aimag(ZD(4,6))
5 1 0.00000000E+00 # Aimag(ZD(5,1))
5 2 0.00000000E+00 # Aimag(ZD(5,2))
5 3 0.00000000E+00 # Aimag(ZD(5,3))
5 4 0.00000000E+00 # Aimag(ZD(5,4))
5 5 0.00000000E+00 # Aimag(ZD(5,5))
5 6 0.00000000E+00 # Aimag(ZD(5,6))
6 1 0.00000000E+00 # Aimag(ZD(6,1))
6 2 0.00000000E+00 # Aimag(ZD(6,2))
6 3 0.00000000E+00 # Aimag(ZD(6,3))
6 4 0.00000000E+00 # Aimag(ZD(6,4))
6 5 0.00000000E+00 # Aimag(ZD(6,5))
6 6 0.00000000E+00 # Aimag(ZD(6,6))
Block SNUMIX Q= 1.50000000E+03 # ()
1 1 1.00000000E+00 # Real(ZV(1,1),dp)
1 2 0.00000000E+00 # Real(ZV(1,2),dp)
1 3 0.00000000E+00 # Real(ZV(1,3),dp)
2 1 0.00000000E+00 # Real(ZV(2,1),dp)
2 2 1.00000000E+00 # Real(ZV(2,2),dp)
2 3 0.00000000E+00 # Real(ZV(2,3),dp)
3 1 0.00000000E+00 # Real(ZV(3,1),dp)
3 2 0.00000000E+00 # Real(ZV(3,2),dp)
3 3 1.00000000E+00 # Real(ZV(3,3),dp)
Block IMSNUMIX Q= 1.50000000E+03 # ()
1 1 0.00000000E+00 # Aimag(ZV(1,1))
1 2 0.00000000E+00 # Aimag(ZV(1,2))
1 3 0.00000000E+00 # Aimag(ZV(1,3))
2 1 0.00000000E+00 # Aimag(ZV(2,1))
2 2 0.00000000E+00 # Aimag(ZV(2,2))
2 3 0.00000000E+00 # Aimag(ZV(2,3))
3 1 0.00000000E+00 # Aimag(ZV(3,1))
3 2 0.00000000E+00 # Aimag(ZV(3,2))
3 3 0.00000000E+00 # Aimag(ZV(3,3))
Block USQMIX Q= 1.50000000E+03 # ()
1 1 9.82210353E-01 # Real(ZU(1,1),dp)
1 2 1.87783903E-01 # Real(ZU(1,2),dp)
1 3 1.56385066E-05 # Real(ZU(1,3),dp)
1 4 -8.63356262E-06 # Real(ZU(1,4),dp)
1 5 1.68456268E-04 # Real(ZU(1,5),dp)
1 6 -8.29861840E-06 # Real(ZU(1,6),dp)
2 1 1.87781448E-01 # Real(ZU(2,1),dp)
2 2 -9.82201338E-01 # Real(ZU(2,2),dp)
2 3 -3.48109878E-04 # Real(ZU(2,3),dp)
2 4 3.35148517E-07 # Real(ZU(2,4),dp)
2 5 4.30164817E-03 # Real(ZU(2,5),dp)
2 6 1.84708001E-04 # Real(ZU(2,6),dp)
3 1 -2.99253764E-05 # Real(ZU(3,1),dp)
3 2 2.06358294E-04 # Real(ZU(3,2),dp)
3 3 -8.64810940E-01 # Real(ZU(3,3),dp)
3 4 -1.15863827E-10 # Real(ZU(3,4),dp)
3 5 -6.89126463E-07 # Real(ZU(3,5),dp)
3 6 -5.02097595E-01 # Real(ZU(3,6),dp)
4 1 8.41647266E-06 # Real(ZU(4,1),dp)
4 2 1.95287155E-06 # Real(ZU(4,2),dp)
4 3 3.80584862E-10 # Real(ZU(4,3),dp)
4 4 1.00000000E+00 # Real(ZU(4,4),dp)
4 5 5.82879932E-07 # Real(ZU(4,5),dp)
4 6 -5.86089897E-10 # Real(ZU(4,6),dp)
5 1 -9.73238127E-04 # Real(ZU(5,1),dp)
5 2 4.19348931E-03 # Real(ZU(5,2),dp)
5 3 2.25368958E-06 # Real(ZU(5,3),dp)
5 4 -5.82872648E-07 # Real(ZU(5,4),dp)
5 5 9.99990734E-01 # Real(ZU(5,5),dp)
5 6 -3.47273055E-06 # Real(ZU(5,6),dp)
6 1 -4.80597367E-05 # Real(ZU(6,1),dp)
6 2 3.31408108E-04 # Real(ZU(6,2),dp)
6 3 -5.02097517E-01 # Real(ZU(6,3),dp)
6 4 4.53670871E-10 # Real(ZU(6,4),dp)
6 5 2.69832241E-06 # Real(ZU(6,5),dp)
6 6 8.64810945E-01 # Real(ZU(6,6),dp)
Block IMUSQMIX Q= 1.50000000E+03 # ()
1 1 0.00000000E+00 # Aimag(ZU(1,1))
1 2 0.00000000E+00 # Aimag(ZU(1,2))
1 3 0.00000000E+00 # Aimag(ZU(1,3))
1 4 0.00000000E+00 # Aimag(ZU(1,4))
1 5 0.00000000E+00 # Aimag(ZU(1,5))
1 6 0.00000000E+00 # Aimag(ZU(1,6))
2 1 0.00000000E+00 # Aimag(ZU(2,1))
2 2 0.00000000E+00 # Aimag(ZU(2,2))
2 3 0.00000000E+00 # Aimag(ZU(2,3))
2 4 0.00000000E+00 # Aimag(ZU(2,4))
2 5 0.00000000E+00 # Aimag(ZU(2,5))
2 6 0.00000000E+00 # Aimag(ZU(2,6))
3 1 0.00000000E+00 # Aimag(ZU(3,1))
3 2 0.00000000E+00 # Aimag(ZU(3,2))
3 3 0.00000000E+00 # Aimag(ZU(3,3))
3 4 0.00000000E+00 # Aimag(ZU(3,4))
3 5 0.00000000E+00 # Aimag(ZU(3,5))
3 6 0.00000000E+00 # Aimag(ZU(3,6))
4 1 0.00000000E+00 # Aimag(ZU(4,1))
4 2 0.00000000E+00 # Aimag(ZU(4,2))
4 3 0.00000000E+00 # Aimag(ZU(4,3))
4 4 0.00000000E+00 # Aimag(ZU(4,4))
4 5 0.00000000E+00 # Aimag(ZU(4,5))
4 6 0.00000000E+00 # Aimag(ZU(4,6))
5 1 0.00000000E+00 # Aimag(ZU(5,1))
5 2 0.00000000E+00 # Aimag(ZU(5,2))
5 3 0.00000000E+00 # Aimag(ZU(5,3))
5 4 0.00000000E+00 # Aimag(ZU(5,4))
5 5 0.00000000E+00 # Aimag(ZU(5,5))
5 6 0.00000000E+00 # Aimag(ZU(5,6))
6 1 0.00000000E+00 # Aimag(ZU(6,1))
6 2 0.00000000E+00 # Aimag(ZU(6,2))
6 3 0.00000000E+00 # Aimag(ZU(6,3))
6 4 0.00000000E+00 # Aimag(ZU(6,4))
6 5 0.00000000E+00 # Aimag(ZU(6,5))
6 6 0.00000000E+00 # Aimag(ZU(6,6))
Block SELMIX Q= 1.50000000E+03 # ()
1 1 -9.99999996E-01 # Real(ZE(1,1),dp)
1 2 -5.87461830E-12 # Real(ZE(1,2),dp)
1 3 -0.00000000E+00 # Real(ZE(1,3),dp)
1 4 8.51889732E-05 # Real(ZE(1,4),dp)
1 5 4.03098572E-15 # Real(ZE(1,5),dp)
1 6 -0.00000000E+00 # Real(ZE(1,6),dp)
2 1 5.87377870E-12 # Real(ZE(2,1),dp)
2 2 -9.99845004E-01 # Real(ZE(2,2),dp)
2 3 0.00000000E+00 # Real(ZE(2,3),dp)
2 4 -5.00232070E-16 # Real(ZE(2,4),dp)
2 5 1.76058995E-02 # Real(ZE(2,5),dp)
2 6 0.00000000E+00 # Real(ZE(2,6),dp)
3 1 0.00000000E+00 # Real(ZE(3,1),dp)
3 2 0.00000000E+00 # Real(ZE(3,2),dp)
3 3 -9.64705547E-01 # Real(ZE(3,3),dp)
3 4 0.00000000E+00 # Real(ZE(3,4),dp)
3 5 0.00000000E+00 # Real(ZE(3,5),dp)
3 6 2.63330983E-01 # Real(ZE(3,6),dp)
4 1 8.51889732E-05 # Real(ZE(4,1),dp)
4 2 4.40903382E-16 # Real(ZE(4,2),dp)
4 3 0.00000000E+00 # Real(ZE(4,3),dp)
4 4 9.99999996E-01 # Real(ZE(4,4),dp)
4 5 2.50305834E-14 # Real(ZE(4,5),dp)
4 6 0.00000000E+00 # Real(ZE(4,6),dp)
5 1 -9.93997107E-14 # Real(ZE(5,1),dp)
5 2 1.76058995E-02 # Real(ZE(5,2),dp)
5 3 -0.00000000E+00 # Real(ZE(5,3),dp)
5 4 -2.50259986E-14 # Real(ZE(5,4),dp)
5 5 9.99845004E-01 # Real(ZE(5,5),dp)
5 6 -0.00000000E+00 # Real(ZE(5,6),dp)
6 1 -0.00000000E+00 # Real(ZE(6,1),dp)
6 2 -0.00000000E+00 # Real(ZE(6,2),dp)
6 3 -2.63330983E-01 # Real(ZE(6,3),dp)
6 4 -0.00000000E+00 # Real(ZE(6,4),dp)
6 5 -0.00000000E+00 # Real(ZE(6,5),dp)
6 6 -9.64705547E-01 # Real(ZE(6,6),dp)
Block IMSELMIX Q= 1.50000000E+03 # ()
1 1 0.00000000E+00 # Aimag(ZE(1,1))
1 2 0.00000000E+00 # Aimag(ZE(1,2))
1 3 0.00000000E+00 # Aimag(ZE(1,3))
1 4 0.00000000E+00 # Aimag(ZE(1,4))
1 5 0.00000000E+00 # Aimag(ZE(1,5))
1 6 0.00000000E+00 # Aimag(ZE(1,6))
2 1 0.00000000E+00 # Aimag(ZE(2,1))
2 2 0.00000000E+00 # Aimag(ZE(2,2))
2 3 0.00000000E+00 # Aimag(ZE(2,3))
2 4 0.00000000E+00 # Aimag(ZE(2,4))
2 5 0.00000000E+00 # Aimag(ZE(2,5))
2 6 0.00000000E+00 # Aimag(ZE(2,6))
3 1 0.00000000E+00 # Aimag(ZE(3,1))
3 2 0.00000000E+00 # Aimag(ZE(3,2))
3 3 0.00000000E+00 # Aimag(ZE(3,3))
3 4 0.00000000E+00 # Aimag(ZE(3,4))
3 5 0.00000000E+00 # Aimag(ZE(3,5))
3 6 0.00000000E+00 # Aimag(ZE(3,6))
4 1 0.00000000E+00 # Aimag(ZE(4,1))
4 2 0.00000000E+00 # Aimag(ZE(4,2))
4 3 0.00000000E+00 # Aimag(ZE(4,3))
4 4 0.00000000E+00 # Aimag(ZE(4,4))
4 5 0.00000000E+00 # Aimag(ZE(4,5))
4 6 0.00000000E+00 # Aimag(ZE(4,6))
5 1 0.00000000E+00 # Aimag(ZE(5,1))
5 2 0.00000000E+00 # Aimag(ZE(5,2))
5 3 0.00000000E+00 # Aimag(ZE(5,3))
5 4 0.00000000E+00 # Aimag(ZE(5,4))
5 5 0.00000000E+00 # Aimag(ZE(5,5))
5 6 0.00000000E+00 # Aimag(ZE(5,6))
6 1 0.00000000E+00 # Aimag(ZE(6,1))
6 2 0.00000000E+00 # Aimag(ZE(6,2))
6 3 0.00000000E+00 # Aimag(ZE(6,3))
6 4 0.00000000E+00 # Aimag(ZE(6,4))
6 5 0.00000000E+00 # Aimag(ZE(6,5))
6 6 0.00000000E+00 # Aimag(ZE(6,6))
Block SCALARMIX Q= 1.50000000E+03 # ()
1 1 4.47777587E-01 # ZH(1,1)
1 2 8.94067128E-01 # ZH(1,2)
1 3 7.57359142E-03 # ZH(1,3)
1 4 9.04676079E-03 # ZH(1,4)
2 1 -1.93164619E-02 # ZH(2,1)
2 2 -5.27642287E-04 # ZH(2,2)
2 3 1.01164393E-02 # ZH(2,3)
2 4 9.99762098E-01 # ZH(2,4)
3 1 -4.04217320E-03 # ZH(3,1)
3 2 1.03927961E-02 # ZH(3,2)
3 3 -9.99887367E-01 # ZH(3,3)
3 4 1.00450928E-02 # ZH(3,4)
4 1 8.93927160E-01 # ZH(4,1)
4 2 -4.47812106E-01 # ZH(4,2)
4 3 -8.09639635E-03 # ZH(4,3)
4 4 1.71172043E-02 # ZH(4,4)
Block PSEUDOSCALARMIX Q= 1.50000000E+03 # ()
1 1 4.47212381E-01 # ZA(1,1)
1 2 -8.94427798E-01 # ZA(1,2)
1 3 6.19643347E-09 # ZA(1,3)
1 4 2.95224978E-07 # ZA(1,4)
2 1 -5.00869061E-06 # ZA(2,1)
2 2 -2.83440918E-06 # ZA(2,2)
2 3 -1.50193834E-04 # ZA(2,3)
2 4 -9.99999989E-01 # ZA(2,4)
3 1 -6.57580231E-04 # ZA(3,1)
3 2 -3.28782121E-04 # ZA(3,2)
3 3 9.99999718E-01 # ZA(3,3)
3 4 -1.50189568E-04 # ZA(3,4)
4 1 -8.94427557E-01 # ZA(4,1)
4 2 -4.47212260E-01 # ZA(4,2)
4 3 -7.35192602E-04 # ZA(4,3)
4 4 5.85791490E-06 # ZA(4,4)
Block CHARGEMIX Q= 1.50000000E+03 # ()
1 1 4.47192363E-01 # ZP(1,1)
1 2 -8.94386379E-01 # ZP(1,2)
1 3 6.78218310E-03 # ZP(1,3)
1 4 6.78213038E-03 # ZP(1,4)
2 1 -1.32005490E-05 # ZP(2,1)
2 2 5.46869773E-06 # ZP(2,2)
2 3 -7.06307794E-01 # ZP(2,3)
2 4 7.07904866E-01 # ZP(2,4)
3 1 1.90962272E-02 # ZP(3,1)
3 2 -1.17395504E-03 # ZP(3,2)
3 3 -7.07775475E-01 # ZP(3,3)
3 4 -7.06178329E-01 # ZP(3,4)
4 1 -8.94233931E-01 # ZP(4,1)
4 2 -4.47293670E-01 # ZP(4,2)
4 3 -1.17123459E-02 # ZP(4,3)
4 4 -1.16991419E-02 # ZP(4,4)
Block NMIX Q= 1.50000000E+03 # ()
1 1 0.00000000E+00 # Real(ZN(1,1),dp)
1 2 0.00000000E+00 # Real(ZN(1,2),dp)
1 3 -0.00000000E+00 # Real(ZN(1,3),dp)
1 4 -0.00000000E+00 # Real(ZN(1,4),dp)
1 5 -0.00000000E+00 # Real(ZN(1,5),dp)
1 6 -0.00000000E+00 # Real(ZN(1,6),dp)
2 1 -6.91298735E-01 # Real(ZN(2,1),dp)
2 2 -7.82511750E-04 # Real(ZN(2,2),dp)
2 3 -1.08708978E-01 # Real(ZN(2,3),dp)
2 4 -2.63797660E-03 # Real(ZN(2,4),dp)
2 5 -7.14308850E-01 # Real(ZN(2,5),dp)
2 6 6.61157702E-03 # Real(ZN(2,6),dp)
3 1 9.76862231E-02 # Real(ZN(3,1),dp)
3 2 2.14348191E-01 # Real(ZN(3,2),dp)
3 3 -6.61982911E-01 # Real(ZN(3,3),dp)
3 4 6.47190072E-01 # Real(ZN(3,4),dp)
3 5 6.31755956E-03 # Real(ZN(3,5),dp)
3 6 2.95628110E-01 # Real(ZN(3,6),dp)
4 1 0.00000000E+00 # Real(ZN(4,1),dp)
4 2 -0.00000000E+00 # Real(ZN(4,2),dp)
4 3 0.00000000E+00 # Real(ZN(4,3),dp)
4 4 0.00000000E+00 # Real(ZN(4,4),dp)
4 5 -0.00000000E+00 # Real(ZN(4,5),dp)
4 6 0.00000000E+00 # Real(ZN(4,6),dp)
5 1 0.00000000E+00 # Real(ZN(5,1),dp)
5 2 -0.00000000E+00 # Real(ZN(5,2),dp)
5 3 0.00000000E+00 # Real(ZN(5,3),dp)
5 4 -0.00000000E+00 # Real(ZN(5,4),dp)
5 5 0.00000000E+00 # Real(ZN(5,5),dp)
5 6 0.00000000E+00 # Real(ZN(5,6),dp)
6 1 2.85379829E-02 # Real(ZN(6,1),dp)
6 2 -6.71669268E-01 # Real(ZN(6,2),dp)
6 3 -2.33469244E-01 # Real(ZN(6,3),dp)
6 4 2.74682607E-01 # Real(ZN(6,4),dp)
6 5 1.64901062E-03 # Real(ZN(6,5),dp)
6 6 -6.46594800E-01 # Real(ZN(6,6),dp)
Block IMNMIX Q= 1.50000000E+03 # ()
1 1 7.14337054E-01 # Aimag(ZN(1,1))
1 2 3.13757864E-03 # Aimag(ZN(1,2))
1 3 -4.27194086E-02 # Aimag(ZN(1,3))
1 4 -1.38215436E-01 # Aimag(ZN(1,4))
1 5 -6.84472869E-01 # Aimag(ZN(1,5))
1 6 -1.67679785E-02 # Aimag(ZN(1,6))
2 1 0.00000000E+00 # Aimag(ZN(2,1))
2 2 0.00000000E+00 # Aimag(ZN(2,2))
2 3 0.00000000E+00 # Aimag(ZN(2,3))
2 4 0.00000000E+00 # Aimag(ZN(2,4))
2 5 0.00000000E+00 # Aimag(ZN(2,5))
2 6 0.00000000E+00 # Aimag(ZN(2,6))
3 1 0.00000000E+00 # Aimag(ZN(3,1))
3 2 0.00000000E+00 # Aimag(ZN(3,2))
3 3 0.00000000E+00 # Aimag(ZN(3,3))
3 4 0.00000000E+00 # Aimag(ZN(3,4))
3 5 0.00000000E+00 # Aimag(ZN(3,5))
3 6 0.00000000E+00 # Aimag(ZN(3,6))
4 1 3.79443006E-02 # Aimag(ZN(4,1))
4 2 -1.45441511E-02 # Aimag(ZN(4,2))
4 3 7.02556114E-01 # Aimag(ZN(4,3))
4 4 6.93024117E-01 # Aimag(ZN(4,4))
4 5 -1.45656887E-01 # Aimag(ZN(4,5))
4 6 5.71423546E-02 # Aimag(ZN(4,6))
5 1 5.64330160E-03 # Aimag(ZN(5,1))
5 2 -7.09008644E-01 # Aimag(ZN(5,2))
5 3 6.56159148E-03 # Aimag(ZN(5,3))
5 4 -7.93825147E-02 # Aimag(ZN(5,4))
5 5 1.09503756E-03 # Aimag(ZN(5,5))
5 6 7.00663299E-01 # Aimag(ZN(5,6))
6 1 0.00000000E+00 # Aimag(ZN(6,1))
6 2 0.00000000E+00 # Aimag(ZN(6,2))
6 3 0.00000000E+00 # Aimag(ZN(6,3))
6 4 0.00000000E+00 # Aimag(ZN(6,4))
6 5 0.00000000E+00 # Aimag(ZN(6,5))
6 6 0.00000000E+00 # Aimag(ZN(6,6))
Block UMIX Q= 1.50000000E+03 # ()
1 1 -2.13892119E-01 # Real(UM(1,1),dp)
1 2 9.46452464E-01 # Real(UM(1,2),dp)
1 3 -2.41822031E-01 # Real(UM(1,3),dp)
2 1 5.24728839E-01 # Real(UM(2,1),dp)
2 2 -9.74861808E-02 # Real(UM(2,2),dp)
2 3 -8.45669019E-01 # Real(UM(2,3),dp)
3 1 -8.23959833E-01 # Real(UM(3,1),dp)
3 2 -3.07772932E-01 # Real(UM(3,2),dp)
3 3 -4.75779377E-01 # Real(UM(3,3),dp)
Block IMUMIX Q= 1.50000000E+03 # ()
1 1 -0.00000000E+00 # Aimag(UM(1,1))
1 2 -0.00000000E+00 # Aimag(UM(1,2))
1 3 -0.00000000E+00 # Aimag(UM(1,3))
2 1 -0.00000000E+00 # Aimag(UM(2,1))
2 2 -0.00000000E+00 # Aimag(UM(2,2))
2 3 -0.00000000E+00 # Aimag(UM(2,3))
3 1 -0.00000000E+00 # Aimag(UM(3,1))
3 2 -0.00000000E+00 # Aimag(UM(3,2))
3 3 -0.00000000E+00 # Aimag(UM(3,3))
Block VMIX Q= 1.50000000E+03 # ()
1 1 -2.00411515E-01 # Real(UP(1,1),dp)
1 2 9.19982137E-01 # Real(UP(1,2),dp)
1 3 -3.36850252E-01 # Real(UP(1,3),dp)
2 1 -8.52308103E-01 # Real(UP(2,1),dp)
2 2 5.82932296E-03 # Real(UP(2,2),dp)
2 3 5.23007568E-01 # Real(UP(2,3),dp)
3 1 -4.83121229E-01 # Real(UP(3,1),dp)
3 2 -3.91916939E-01 # Real(UP(3,2),dp)
3 3 -7.82939967E-01 # Real(UP(3,3),dp)
Block IMVMIX Q= 1.50000000E+03 # ()
1 1 0.00000000E+00 # Aimag(UP(1,1))
1 2 0.00000000E+00 # Aimag(UP(1,2))
1 3 0.00000000E+00 # Aimag(UP(1,3))
2 1 0.00000000E+00 # Aimag(UP(2,1))
2 2 0.00000000E+00 # Aimag(UP(2,2))
2 3 0.00000000E+00 # Aimag(UP(2,3))
3 1 0.00000000E+00 # Aimag(UP(3,1))
3 2 0.00000000E+00 # Aimag(UP(3,2))
3 3 0.00000000E+00 # Aimag(UP(3,3))
Block UELMIX Q= 1.50000000E+03 # ()
1 1 1.00000000E+00 # Real(ZEL(1,1),dp)
1 2 0.00000000E+00 # Real(ZEL(1,2),dp)
1 3 0.00000000E+00 # Real(ZEL(1,3),dp)
2 1 0.00000000E+00 # Real(ZEL(2,1),dp)
2 2 1.00000000E+00 # Real(ZEL(2,2),dp)
2 3 0.00000000E+00 # Real(ZEL(2,3),dp)
3 1 0.00000000E+00 # Real(ZEL(3,1),dp)
3 2 0.00000000E+00 # Real(ZEL(3,2),dp)
3 3 1.00000000E+00 # Real(ZEL(3,3),dp)
Block IMUELMIX Q= 1.50000000E+03 # ()
1 1 0.00000000E+00 # Aimag(ZEL(1,1))
1 2 0.00000000E+00 # Aimag(ZEL(1,2))
1 3 0.00000000E+00 # Aimag(ZEL(1,3))
2 1 0.00000000E+00 # Aimag(ZEL(2,1))
2 2 0.00000000E+00 # Aimag(ZEL(2,2))
2 3 0.00000000E+00 # Aimag(ZEL(2,3))
3 1 0.00000000E+00 # Aimag(ZEL(3,1))
3 2 0.00000000E+00 # Aimag(ZEL(3,2))
3 3 0.00000000E+00 # Aimag(ZEL(3,3))
Block UERMIX Q= 1.50000000E+03 # ()
1 1 1.00000000E+00 # Real(ZER(1,1),dp)
1 2 0.00000000E+00 # Real(ZER(1,2),dp)
1 3 0.00000000E+00 # Real(ZER(1,3),dp)
2 1 0.00000000E+00 # Real(ZER(2,1),dp)
2 2 1.00000000E+00 # Real(ZER(2,2),dp)
2 3 0.00000000E+00 # Real(ZER(2,3),dp)
3 1 0.00000000E+00 # Real(ZER(3,1),dp)
3 2 0.00000000E+00 # Real(ZER(3,2),dp)
3 3 1.00000000E+00 # Real(ZER(3,3),dp)
Block IMUERMIX Q= 1.50000000E+03 # ()
1 1 0.00000000E+00 # Aimag(ZER(1,1))
1 2 0.00000000E+00 # Aimag(ZER(1,2))
1 3 0.00000000E+00 # Aimag(ZER(1,3))
2 1 0.00000000E+00 # Aimag(ZER(2,1))
2 2 0.00000000E+00 # Aimag(ZER(2,2))
2 3 0.00000000E+00 # Aimag(ZER(2,3))
3 1 0.00000000E+00 # Aimag(ZER(3,1))
3 2 0.00000000E+00 # Aimag(ZER(3,2))
3 3 0.00000000E+00 # Aimag(ZER(3,3))
Block UDLMIX Q= 1.50000000E+03 # ()
1 1 1.00000000E+00 # Real(ZDL(1,1),dp)
1 2 -6.40187274E-07 # Real(ZDL(1,2),dp)
1 3 1.53572605E-05 # Real(ZDL(1,3),dp)
2 1 6.41814853E-07 # Real(ZDL(2,1),dp)
2 2 9.99999994E-01 # Real(ZDL(2,2),dp)
2 3 -1.05981352E-04 # Real(ZDL(2,3),dp)
3 1 -1.53571925E-05 # Real(ZDL(3,1),dp)
3 2 1.05981362E-04 # Real(ZDL(3,2),dp)
3 3 9.99999994E-01 # Real(ZDL(3,3),dp)
Block IMUDLMIX Q= 1.50000000E+03 # ()
1 1 0.00000000E+00 # Aimag(ZDL(1,1))
1 2 0.00000000E+00 # Aimag(ZDL(1,2))
1 3 0.00000000E+00 # Aimag(ZDL(1,3))
2 1 0.00000000E+00 # Aimag(ZDL(2,1))
2 2 0.00000000E+00 # Aimag(ZDL(2,2))
2 3 -0.00000000E+00 # Aimag(ZDL(2,3))
3 1 -0.00000000E+00 # Aimag(ZDL(3,1))
3 2 0.00000000E+00 # Aimag(ZDL(3,2))
3 3 0.00000000E+00 # Aimag(ZDL(3,3))
Block UDRMIX Q= 1.50000000E+03 # ()
1 1 1.00000000E+00 # Real(ZDR(1,1),dp)
1 2 -6.72897973E-08 # Real(ZDR(1,2),dp)
1 3 3.15821226E-08 # Real(ZDR(1,3),dp)
2 1 6.72899280E-08 # Real(ZDR(2,1),dp)
2 2 1.00000000E+00 # Real(ZDR(2,2),dp)
2 3 -4.13931484E-06 # Real(ZDR(2,3),dp)
3 1 -3.15818440E-08 # Real(ZDR(3,1),dp)
3 2 4.13931484E-06 # Real(ZDR(3,2),dp)
3 3 1.00000000E+00 # Real(ZDR(3,3),dp)
Block IMUDRMIX Q= 1.50000000E+03 # ()
1 1 0.00000000E+00 # Aimag(ZDR(1,1))
1 2 -0.00000000E+00 # Aimag(ZDR(1,2))
1 3 0.00000000E+00 # Aimag(ZDR(1,3))
2 1 0.00000000E+00 # Aimag(ZDR(2,1))
2 2 0.00000000E+00 # Aimag(ZDR(2,2))
2 3 0.00000000E+00 # Aimag(ZDR(2,3))
3 1 0.00000000E+00 # Aimag(ZDR(3,1))
3 2 0.00000000E+00 # Aimag(ZDR(3,2))
3 3 0.00000000E+00 # Aimag(ZDR(3,3))
Block UULMIX Q= 1.50000000E+03 # ()
1 1 9.74159113E-01 # Real(ZUL(1,1),dp)
1 2 2.25835711E-01 # Real(ZUL(1,2),dp)
1 3 3.50053929E-03 # Real(ZUL(1,3),dp)
2 1 -2.25783196E-01 # Real(ZUL(2,1),dp)
2 2 9.73287097E-01 # Real(ZUL(2,2),dp)
2 3 4.16434389E-02 # Real(ZUL(2,3),dp)
3 1 5.99754591E-03 # Real(ZUL(3,1),dp)
3 2 -4.13576984E-02 # Real(ZUL(3,2),dp)
3 3 9.99126404E-01 # Real(ZUL(3,3),dp)
Block IMUULMIX Q= 1.50000000E+03 # ()
1 1 0.00000000E+00 # Aimag(ZUL(1,1))
1 2 0.00000000E+00 # Aimag(ZUL(1,2))
1 3 0.00000000E+00 # Aimag(ZUL(1,3))
2 1 0.00000000E+00 # Aimag(ZUL(2,1))
2 2 0.00000000E+00 # Aimag(ZUL(2,2))
2 3 0.00000000E+00 # Aimag(ZUL(2,3))
3 1 0.00000000E+00 # Aimag(ZUL(3,1))
3 2 -0.00000000E+00 # Aimag(ZUL(3,2))
3 3 0.00000000E+00 # Aimag(ZUL(3,3))
Block UURMIX Q= 1.50000000E+03 # ()
1 1 1.00000000E+00 # Real(ZUR(1,1),dp)
1 2 4.82796470E-10 # Real(ZUR(1,2),dp)
1 3 9.89795381E-11 # Real(ZUR(1,3),dp)
2 1 -4.82796529E-10 # Real(ZUR(2,1),dp)
2 2 1.00000000E+00 # Real(ZUR(2,2),dp)
2 3 5.88717512E-07 # Real(ZUR(2,3),dp)
3 1 -9.89792539E-11 # Real(ZUR(3,1),dp)
3 2 -5.88717512E-07 # Real(ZUR(3,2),dp)
3 3 1.00000000E+00 # Real(ZUR(3,3),dp)
Block IMUURMIX Q= 1.50000000E+03 # ()
1 1 0.00000000E+00 # Aimag(ZUR(1,1))
1 2 0.00000000E+00 # Aimag(ZUR(1,2))
1 3 0.00000000E+00 # Aimag(ZUR(1,3))
2 1 -0.00000000E+00 # Aimag(ZUR(2,1))
2 2 0.00000000E+00 # Aimag(ZUR(2,2))
2 3 0.00000000E+00 # Aimag(ZUR(2,3))
3 1 0.00000000E+00 # Aimag(ZUR(3,1))
3 2 0.00000000E+00 # Aimag(ZUR(3,2))
3 3 0.00000000E+00 # Aimag(ZUR(3,3))
Block ZG Q= 1.50000000E+03 # ()
1 1 0.00000000E+00 # Real(ZG(1,1),dp)
1 2 -0.00000000E+00 # Real(ZG(1,2),dp)
2 1 -7.07107229E-01 # Real(ZG(2,1),dp)
2 2 -7.07106334E-01 # Real(ZG(2,2),dp)
Block IMZG Q= 1.50000000E+03 # ()
1 1 7.07106334E-01 # Aimag(ZG(1,1))
1 2 -7.07107229E-01 # Aimag(ZG(1,2))
2 1 0.00000000E+00 # Aimag(ZG(2,1))
2 2 0.00000000E+00 # Aimag(ZG(2,2))
Block SPheno # SPheno internal parameters
1 -1.00000000E+00 # ErrorLevel
2 0.00000000E+00 # SPA_conventions
11 1.00000000E+00 # Branching ratios
13 1.00000000E+00 # 3 Body decays
31 1.50000000E+03 # GUT scale
33 1.50000000E+03 # Renormalization scale
34 1.00000000E-04 # Precision
35 4.00000000E+01 # Iterations
38 2.00000000E+00 # RGE level
40 7.29735257E-03 # Alpha
41 2.49520000E+00 # Gamma_Z
42 2.06000000E+00 # Gamma_W
50 1.00000000E+00 # Rotate negative fermion masses
51 0.00000000E+00 # Switch to SCKM matrix
52 0.00000000E+00 # Ignore negative masses
53 0.00000000E+00 # Ignore negative masses at MZ
55 1.00000000E+00 # Calculate one loop masses
56 1.00000000E+00 # Calculate two-loop Higgs masses
57 1.00000000E+00 # Calculate low energy
60 1.00000000E+00 # Include kinetic mixing
65 1.00000000E+00 # Solution of tadpole equation
8 3.00000000E+00 # Two-Loop Method: diagrammatic
9 1.00000000E+00 # Gauge-less limit
Block HiggsLHC7 # Higgs production cross section at LHC7 [pb] (rescaled SM values from HXSWG)
1 25 1.99229160E+01 # Gluon fusion
2 25 1.38821686E+00 # Vector boson fusion
3 25 8.36470724E-01 # W-H production
4 25 4.63431529E-01 # Z-H production
5 25 1.23359170E-01 # t-t-H production
1 36 8.55466763E-07 # Gluon fusion
Block HiggsLHC8 # Higgs production cross section at LHC8 [pb] (rescaled SM values from HXSWG)
1 25 2.51511637E+01 # Gluon fusion
2 25 1.77804684E+00 # Vector boson fusion
3 25 1.03643434E+00 # W-H production
4 25 5.76048115E-01 # Z-H production
5 25 1.85452971E-01 # t-t-H production
1 36 1.31822273E-06 # Gluon fusion
Block HiggsLHC13 # Higgs production cross section at LHC13 [pb] (rescaled SM values from SusHI 1.5.0)
1 25 5.75566868E+01 # Gluon fusion
1 36 5.13569985E-06 # Gluon fusion
Block HiggsLHC14 # Higgs production cross section at LHC14 [pb] (rescaled SM values from SusHI 1.5.0)
1 25 6.46183382E+01 # Gluon fusion
1 36 6.13863681E-06 # Gluon fusion
Block HiggsFCC100 # Higgs production cross section at FCC-pp [pb] (rescaled SM values from SusHI 1.5.0)
1 25 8.95954842E+02 # Gluon fusion
1 36 3.08512062E-04 # Gluon fusion
Block HPPloops # Loop contributions to H-Photon-Photon coupling
25 24 8.74758683E+00 # h( 1)-VWm( 1)-loop
25 2000003 -8.16538062E-06 # h( 1)-Sd( 1)-loop
25 2000001 -8.16611466E-06 # h( 1)-Sd( 2)-loop
25 1000001 -3.52392170E-05 # h( 1)-Sd( 3)-loop
25 1000003 -3.52397783E-05 # h( 1)-Sd( 4)-loop
25 2000005 1.37075219E-06 # h( 1)-Sd( 5)-loop
25 1000005 -2.36153647E-05 # h( 1)-Sd( 6)-loop
25 2000004 6.52976672E-05 # h( 1)-Su( 1)-loop
25 2000002 6.52855378E-05 # h( 1)-Su( 2)-loop
25 1000002 1.08510406E-04 # h( 1)-Su( 3)-loop
25 1000004 1.04818338E-04 # h( 1)-Su( 4)-loop
25 1000006 -4.98923776E-04 # h( 1)-Su( 5)-loop
25 2000006 -1.62675474E-03 # h( 1)-Su( 6)-loop
25 2000015 -1.40453106E-04 # h( 1)-Se( 1)-loop
25 2000013 -1.95086476E-04 # h( 1)-Se( 2)-loop
25 2000011 -1.95311500E-04 # h( 1)-Se( 3)-loop
25 1000011 -1.51955562E-04 # h( 1)-Se( 4)-loop
25 1000013 -1.52183262E-04 # h( 1)-Se( 5)-loop
25 1000015 -2.07588885E-04 # h( 1)-Se( 6)-loop
25 37 -2.72076419E-04 # h( 1)-Hpm( 2)-loop
25 47 4.31159682E-05 # h( 1)-Hpm( 3)-loop
25 57 -2.43465801E-04 # h( 1)-Hpm( 4)-loop
25 1000024 8.91650482E-02 # h( 1)-Cha( 1)-loop
25 1000037 -1.60331334E-02 # h( 1)-Cha( 2)-loop
25 1000047 -9.18639817E-02 # h( 1)-Cha( 3)-loop
25 11 2.39258884E-08 # h( 1)-Fe( 1)-loop
25 13 3.18306968E-04 # h( 1)-Fe( 2)-loop
25 15 2.75418936E-02 # h( 1)-Fe( 3)-loop
25 1 3.59041197E-07 # h( 1)-Fd( 1)-loop
25 3 6.94067652E-05 # h( 1)-Fd( 2)-loop
25 5 2.56175170E-02 # h( 1)-Fd( 3)-loop
25 2 3.44386405E-07 # h( 1)-Fu( 1)-loop
25 4 1.51456267E-02 # h( 1)-Fu( 2)-loop
25 6 -1.73559241E+00 # h( 1)-Fu( 3)-loop
35 24 1.82892697E-02 # h( 2)-VWm( 1)-loop
35 2000003 -1.26033491E-06 # h( 2)-Sd( 1)-loop
35 2000001 -1.26119380E-06 # h( 2)-Sd( 2)-loop
35 1000001 7.90216197E-04 # h( 2)-Sd( 3)-loop
35 1000003 7.90211015E-04 # h( 2)-Sd( 4)-loop
35 2000005 6.75073119E-05 # h( 2)-Sd( 5)-loop
35 1000005 3.20831992E-04 # h( 2)-Sd( 6)-loop
35 2000004 1.00231188E-05 # h( 2)-Su( 1)-loop
35 2000002 1.00823510E-05 # h( 2)-Su( 2)-loop
35 1000002 -3.16734866E-03 # h( 2)-Su( 3)-loop
35 1000004 -3.16724914E-03 # h( 2)-Su( 4)-loop
35 1000006 -1.16513379E-03 # h( 2)-Su( 5)-loop
35 2000006 -3.85877827E-04 # h( 2)-Su( 6)-loop
35 2000015 5.02067619E-04 # h( 2)-Se( 1)-loop
35 2000013 -3.40769572E-05 # h( 2)-Se( 2)-loop
35 2000011 -3.64827121E-05 # h( 2)-Se( 3)-loop
35 1000011 7.66791448E-03 # h( 2)-Se( 4)-loop
35 1000013 7.66550926E-03 # h( 2)-Se( 5)-loop
35 1000015 7.12951414E-03 # h( 2)-Se( 6)-loop
35 37 5.34440849E-05 # h( 2)-Hpm( 2)-loop
35 47 -1.72662012E-06 # h( 2)-Hpm( 3)-loop
35 57 1.55836311E-03 # h( 2)-Hpm( 4)-loop
35 1000024 2.09117445E-02 # h( 2)-Cha( 1)-loop
35 1000037 -1.60271634E-01 # h( 2)-Cha( 2)-loop
35 1000047 1.61007578E-01 # h( 2)-Cha( 3)-loop
35 11 -5.77601047E-12 # h( 2)-Fe( 1)-loop
35 13 -1.01170971E-07 # h( 2)-Fe( 2)-loop
35 15 -1.39388092E-05 # h( 2)-Fe( 3)-loop
35 1 -5.96730695E-11 # h( 2)-Fd( 1)-loop
35 3 -1.53240267E-08 # h( 2)-Fd( 2)-loop
35 5 -1.34988479E-05 # h( 2)-Fd( 3)-loop
35 2 -8.41763560E-13 # h( 2)-Fu( 1)-loop
35 4 -8.35628734E-08 # h( 2)-Fu( 2)-loop
35 6 -1.18431043E-04 # h( 2)-Fu( 3)-loop
45 24 1.43560001E-02 # h( 3)-VWm( 1)-loop
45 2000003 1.18714543E-04 # h( 3)-Sd( 1)-loop
45 2000001 1.18714482E-04 # h( 3)-Sd( 2)-loop
45 1000001 6.64982179E-05 # h( 3)-Sd( 3)-loop
45 1000003 6.64977781E-05 # h( 3)-Sd( 4)-loop
45 2000005 5.40471333E-05 # h( 3)-Sd( 5)-loop
45 1000005 3.53192774E-05 # h( 3)-Sd( 6)-loop
45 2000004 -9.48983048E-04 # h( 3)-Su( 1)-loop
45 2000002 -9.49009408E-04 # h( 3)-Su( 2)-loop
45 1000002 2.06055890E-04 # h( 3)-Su( 3)-loop
45 1000004 2.05996428E-04 # h( 3)-Su( 4)-loop
45 1000006 1.48888410E-05 # h( 3)-Su( 5)-loop
45 2000006 -3.87403905E-04 # h( 3)-Su( 6)-loop
45 2000015 3.48119206E-03 # h( 3)-Se( 1)-loop
45 2000013 3.86262628E-03 # h( 3)-Se( 2)-loop
45 2000011 3.86434342E-03 # h( 3)-Se( 3)-loop
45 1000011 -1.84415557E-03 # h( 3)-Se( 4)-loop
45 1000013 -1.84243800E-03 # h( 3)-Se( 5)-loop
45 1000015 -1.46088035E-03 # h( 3)-Se( 6)-loop
45 37 1.87952676E-06 # h( 3)-Hpm( 2)-loop
45 47 -4.00782054E-07 # h( 3)-Hpm( 3)-loop
45 57 -1.42371550E-03 # h( 3)-Hpm( 4)-loop
45 1000024 -2.01794990E-02 # h( 3)-Cha( 1)-loop
45 1000037 -8.33297326E-04 # h( 3)-Cha( 2)-loop
45 1000047 -8.41178463E-03 # h( 3)-Cha( 3)-loop
45 11 -8.42730295E-13 # h( 3)-Fe( 1)-loop
45 13 -1.49814792E-08 # h( 3)-Fe( 2)-loop
45 15 -2.10229572E-06 # h( 3)-Fe( 3)-loop
45 1 -8.60158506E-12 # h( 3)-Fd( 1)-loop
45 3 -2.24256439E-09 # h( 3)-Fd( 2)-loop
45 5 -2.04390938E-06 # h( 3)-Fd( 3)-loop
45 2 1.13831393E-11 # h( 3)-Fu( 1)-loop
45 4 1.17398263E-06 # h( 3)-Fu( 2)-loop
45 6 2.20116525E-03 # h( 3)-Fu( 3)-loop
55 24 -8.25236183E-04 # h( 4)-VWm( 1)-loop
55 2000003 1.12676698E-05 # h( 4)-Sd( 1)-loop
55 2000001 1.12680421E-05 # h( 4)-Sd( 2)-loop
55 1000001 7.22233531E-05 # h( 4)-Sd( 3)-loop
55 1000003 7.22230992E-05 # h( 4)-Sd( 4)-loop
55 2000005 7.51453267E-06 # h( 4)-Sd( 5)-loop
55 1000005 3.42848815E-05 # h( 4)-Sd( 6)-loop
55 2000004 -8.99834809E-05 # h( 4)-Su( 1)-loop
55 2000002 -9.00733843E-05 # h( 4)-Su( 2)-loop
55 1000002 -2.44235051E-04 # h( 4)-Su( 3)-loop
55 1000004 -2.42900780E-04 # h( 4)-Su( 4)-loop
55 1000006 1.27394404E-03 # h( 4)-Su( 5)-loop
55 2000006 -6.39305283E-04 # h( 4)-Su( 6)-loop
55 2000015 4.66644325E-04 # h( 4)-Se( 1)-loop
55 2000013 5.03453719E-04 # h( 4)-Se( 2)-loop
55 2000011 5.03599052E-04 # h( 4)-Se( 3)-loop
55 1000011 7.43536714E-04 # h( 4)-Se( 4)-loop
55 1000013 7.43668422E-04 # h( 4)-Se( 5)-loop
55 1000015 7.76639176E-04 # h( 4)-Se( 6)-loop
55 37 6.88068124E-06 # h( 4)-Hpm( 2)-loop
55 47 2.36034748E-04 # h( 4)-Hpm( 3)-loop
55 57 -1.03588405E-04 # h( 4)-Hpm( 4)-loop
55 1000024 1.10820679E-04 # h( 4)-Cha( 1)-loop
55 1000037 -5.36864056E-03 # h( 4)-Cha( 2)-loop
55 1000047 -2.66219107E-03 # h( 4)-Cha( 3)-loop
55 11 1.33736177E-10 # h( 4)-Fe( 1)-loop
55 13 2.40884146E-06 # h( 4)-Fe( 2)-loop
55 15 3.43483280E-04 # h( 4)-Fe( 3)-loop
55 1 1.34948776E-09 # h( 4)-Fd( 1)-loop
55 3 3.56666817E-07 # h( 4)-Fd( 2)-loop
55 5 3.34926319E-04 # h( 4)-Fd( 3)-loop
55 2 -3.46909093E-10 # h( 4)-Fu( 1)-loop
55 4 -3.70192175E-05 # h( 4)-Fu( 2)-loop
55 6 -8.47633751E-02 # h( 4)-Fu( 3)-loop
Block EFFHIGGSCOUPLINGS # values of loop-induced couplings
25 22 22 0.33296131E-04 # H-Photon-Photon
25 21 21 0.66089970E-04 # H-Gluon-Gluon
25 22 23 0.00000000E+00 # H-Photon-Z (not yet calculated by SPheno)
35 22 22 0.38760438E-06 # H-Photon-Photon
35 21 21 0.94320257E-08 # H-Gluon-Gluon
35 22 23 0.00000000E+00 # H-Photon-Z (not yet calculated by SPheno)
45 22 22 0.79367212E-06 # H-Photon-Photon
45 21 21 0.12538099E-06 # H-Gluon-Gluon
45 22 23 0.00000000E+00 # H-Photon-Z (not yet calculated by SPheno)
55 22 22 0.83185658E-06 # H-Photon-Photon
55 21 21 0.41085375E-05 # H-Gluon-Gluon
55 22 23 0.00000000E+00 # H-Photon-Z (not yet calculated by SPheno)
36 22 22 0.53899233E-06 # A-Photon-Photon
36 21 21 0.25226520E-09 # A-Gluon-Gluon
36 22 23 0.00000000E+00 # A-Photon-Z (not yet calculated by SPheno)
46 22 22 0.73173111E-06 # A-Photon-Photon
46 21 21 0.33936254E-08 # A-Gluon-Gluon
46 22 23 0.00000000E+00 # A-Photon-Z (not yet calculated by SPheno)
56 22 22 0.73202854E-06 # A-Photon-Photon
56 21 21 0.44662517E-05 # A-Gluon-Gluon
56 22 23 0.00000000E+00 # A-Photon-Z (not yet calculated by SPheno)
Block SPhenoLowEnergy # low energy observables
1 2.25414564E-02 # T-parameter (1-loop BSM)
2 2.57220633E-01 # S-parameter (1-loop BSM)
3 1.32722169E-02 # U-parameter (1-loop BSM)
20 -2.73830648E-16 # (g-2)_e
21 -1.17071094E-11 # (g-2)_mu
22 -3.30980495E-09 # (g-2)_tau
23 0.00000000E+00 # EDM(e)
24 0.00000000E+00 # EDM(mu)
25 0.00000000E+00 # EDM(tau)
39 -2.88898771E-05 # delta(rho)
Block FlavorKitQFV # quark flavor violating observables
Block FlavorKitLFV # lepton flavor violating observables
Block FWCOEF Q= 1.60000000E+02 # Wilson coefficients at scale Q
Block IMFWCOEF Q= 1.60000000E+02 # Im(Wilson coefficients) at scale Q
DECAY 2000003 2.30151175E+01 # SsR
# BR NDA ID1 ID2
3.27325641E-02 2 3 1000022 # BR(SsR -> Fd_2 Chi_1 )
3.06411181E-02 2 3 1000023 # BR(SsR -> Fd_2 Chi_2 )
5.89984777E-04 2 3 1000025 # BR(SsR -> Fd_2 Chi_3 )
4.67950808E-01 2 1000021 3 # BR(SsR -> Glu_1 Fd_2 )
4.67944696E-01 2 2000021 3 # BR(SsR -> Glu_2 Fd_2 )
DECAY 2000001 2.30150567E+01 # SdR
# BR NDA ID1 ID2
3.27326954E-02 2 1 1000022 # BR(SdR -> Fd_1 Chi_1 )
3.06411652E-02 2 1 1000023 # BR(SdR -> Fd_1 Chi_2 )
5.89540130E-04 2 1 1000025 # BR(SdR -> Fd_1 Chi_3 )
4.67952210E-01 2 1000021 1 # BR(SdR -> Glu_1 Fd_1 )
4.67945814E-01 2 2000021 1 # BR(SdR -> Glu_2 Fd_1 )
DECAY 1000001 5.12846480E+01 # SdL
# BR NDA ID1 ID2
1.79284013E-02 2 2 1000024 # BR(SdL -> Fu_1 Cha_1 )
1.03675453E-01 2 2 1000037 # BR(SdL -> Fu_1 Cha_2 )
2.54504558E-01 2 2 1000047 # BR(SdL -> Fu_1 Cha_3 )
3.31775626E-03 2 1 1000022 # BR(SdL -> Fd_1 Chi_1 )
3.21678962E-03 2 1 1000023 # BR(SdL -> Fd_1 Chi_2 )
7.10032876E-03 2 1 1000025 # BR(SdL -> Fd_1 Chi_3 )
8.96376428E-02 2 1 1000045 # BR(SdL -> Fd_1 Chi_5 )
8.11722141E-02 2 1 1000055 # BR(SdL -> Fd_1 Chi_6 )
1.95255000E-04 2 3 1000022 # BR(SdL -> Fd_2 Chi_1 )
1.89311389E-04 2 3 1000023 # BR(SdL -> Fd_2 Chi_2 )
4.17866915E-04 2 3 1000025 # BR(SdL -> Fd_2 Chi_3 )
5.27527401E-03 2 3 1000045 # BR(SdL -> Fd_2 Chi_5 )
4.77707967E-03 2 3 1000055 # BR(SdL -> Fd_2 Chi_6 )
2.02317095E-01 2 1000021 1 # BR(SdL -> Glu_1 Fd_1 )
1.19066000E-02 2 1000021 3 # BR(SdL -> Glu_1 Fd_2 )
2.02314375E-01 2 2000021 1 # BR(SdL -> Glu_2 Fd_1 )
1.19064328E-02 2 2000021 3 # BR(SdL -> Glu_2 Fd_2 )
DECAY 1000003 5.13557434E+01 # SsL
# BR NDA ID1 ID2
1.78844045E-02 2 4 1000024 # BR(SsL -> Fu_2 Cha_1 )
1.03355883E-01 2 4 1000037 # BR(SsL -> Fu_2 Cha_2 )
2.53722619E-01 2 4 1000047 # BR(SsL -> Fu_2 Cha_3 )
1.18963040E-03 2 6 1000024 # BR(SsL -> Fu_3 Cha_1 )
1.75894312E-04 2 6 1000037 # BR(SsL -> Fu_3 Cha_2 )
6.51701605E-04 2 6 1000047 # BR(SsL -> Fu_3 Cha_3 )
1.94984030E-04 2 1 1000022 # BR(SsL -> Fd_1 Chi_1 )
1.89050237E-04 2 1 1000023 # BR(SsL -> Fd_1 Chi_2 )
4.17285323E-04 2 1 1000025 # BR(SsL -> Fd_1 Chi_3 )
5.26799279E-03 2 1 1000045 # BR(SsL -> Fd_1 Chi_5 )
4.77048073E-03 2 1 1000055 # BR(SsL -> Fd_1 Chi_6 )
3.31319174E-03 2 3 1000022 # BR(SsL -> Fd_2 Chi_1 )
3.21233739E-03 2 3 1000023 # BR(SsL -> Fd_2 Chi_2 )
7.09059185E-03 2 3 1000025 # BR(SsL -> Fd_2 Chi_3 )
8.95137213E-02 2 3 1000045 # BR(SsL -> Fd_2 Chi_5 )
8.10600902E-02 2 3 1000055 # BR(SsL -> Fd_2 Chi_6 )
1.18903361E-02 2 1000021 1 # BR(SsL -> Glu_1 Fd_1 )
2.02040837E-01 2 1000021 3 # BR(SsL -> Glu_1 Fd_2 )
1.18901763E-02 2 2000021 1 # BR(SsL -> Glu_2 Fd_1 )
2.02038000E-01 2 2000021 3 # BR(SsL -> Glu_2 Fd_2 )
DECAY 2000005 1.13831001E+02 # Sb2
# BR NDA ID1 ID2
7.99749533E-02 2 6 1000024 # BR(Sb2 -> Fu_3 Cha_1 )
1.21531837E-02 2 6 1000037 # BR(Sb2 -> Fu_3 Cha_2 )
4.07723126E-02 2 6 1000047 # BR(Sb2 -> Fu_3 Cha_3 )
7.97921628E-03 2 5 1000022 # BR(Sb2 -> Fd_3 Chi_1 )
7.85778951E-03 2 5 1000023 # BR(Sb2 -> Fd_3 Chi_2 )
1.86615058E-03 2 5 1000025 # BR(Sb2 -> Fd_3 Chi_3 )
4.50479710E-04 2 5 1000035 # BR(Sb2 -> Fd_3 Chi_4 )
1.08143965E-02 2 5 1000045 # BR(Sb2 -> Fd_3 Chi_5 )
8.85182785E-03 2 5 1000055 # BR(Sb2 -> Fd_3 Chi_6 )
4.14009401E-01 2 1000021 5 # BR(Sb2 -> Glu_1 Fd_3 )
4.15195400E-01 2 2000021 5 # BR(Sb2 -> Glu_2 Fd_3 )
DECAY 1000005 1.80400858E+02 # Sb1
# BR NDA ID1 ID2
1.53053755E-04 2 4 1000047 # BR(Sb1 -> Fu_2 Cha_3 )
2.34955486E-01 2 6 1000024 # BR(Sb1 -> Fu_3 Cha_1 )
3.51850378E-02 2 6 1000037 # BR(Sb1 -> Fu_3 Cha_2 )
1.31317209E-01 2 6 1000047 # BR(Sb1 -> Fu_3 Cha_3 )
2.25322701E-03 2 5 1000022 # BR(Sb1 -> Fd_3 Chi_1 )
1.91877689E-03 2 5 1000023 # BR(Sb1 -> Fd_3 Chi_2 )
2.28864012E-03 2 5 1000025 # BR(Sb1 -> Fd_3 Chi_3 )
1.00959023E-04 2 5 1000035 # BR(Sb1 -> Fd_3 Chi_4 )
3.26369375E-02 2 5 1000045 # BR(Sb1 -> Fd_3 Chi_5 )
3.02671700E-02 2 5 1000055 # BR(Sb1 -> Fd_3 Chi_6 )
2.64800737E-01 2 1000021 5 # BR(Sb1 -> Glu_1 Fd_3 )
2.64051544E-01 2 2000021 5 # BR(Sb1 -> Glu_2 Fd_3 )
DECAY 2000004 2.74969876E+01 # ScR
# BR NDA ID1 ID2
1.09626794E-01 2 4 1000022 # BR(ScR -> Fu_2 Chi_1 )
1.02620060E-01 2 4 1000023 # BR(ScR -> Fu_2 Chi_2 )
1.98822904E-03 2 4 1000025 # BR(ScR -> Fu_2 Chi_3 )
3.07926370E-04 2 4 1000035 # BR(ScR -> Fu_2 Chi_4 )
1.61281699E-04 2 4 1000055 # BR(ScR -> Fu_2 Chi_6 )
3.92618924E-01 2 1000021 4 # BR(ScR -> Glu_1 Fu_2 )
3.92626993E-01 2 2000021 4 # BR(ScR -> Glu_2 Fu_2 )
DECAY 2000002 2.74952355E+01 # SuR
# BR NDA ID1 ID2
1.09633717E-01 2 2 1000022 # BR(SuR -> Fu_1 Chi_1 )
1.02628452E-01 2 2 1000023 # BR(SuR -> Fu_1 Chi_2 )
1.97463055E-03 2 2 1000025 # BR(SuR -> Fu_1 Chi_3 )
2.96471820E-04 2 2 1000035 # BR(SuR -> Fu_1 Chi_4 )
1.61331144E-04 2 2 1000055 # BR(SuR -> Fu_1 Chi_6 )
3.92652210E-01 2 1000021 2 # BR(SuR -> Glu_1 Fu_1 )
3.92646854E-01 2 2000021 2 # BR(SuR -> Glu_2 Fu_1 )
DECAY 1000002 5.12843742E+01 # SuL
# BR NDA ID1 ID2
3.84969206E-03 2 2 1000022 # BR(SuL -> Fu_1 Chi_1 )
3.48287360E-03 2 2 1000023 # BR(SuL -> Fu_1 Chi_2 )
1.05898850E-02 2 2 1000025 # BR(SuL -> Fu_1 Chi_3 )
9.41779651E-02 2 2 1000045 # BR(SuL -> Fu_1 Chi_5 )
8.30927573E-02 2 2 1000055 # BR(SuL -> Fu_1 Chi_6 )
1.43449748E-04 2 4 1000045 # BR(SuL -> Fu_2 Chi_5 )
1.26571470E-04 2 4 1000055 # BR(SuL -> Fu_2 Chi_6 )
1.51829173E-02 2 -1000024 1 # BR(SuL -> Cha_1^* Fd_1 )
5.55016712E-04 2 -1000024 3 # BR(SuL -> Cha_1^* Fd_2 )
2.63845961E-01 2 -1000037 1 # BR(SuL -> Cha_2^* Fd_1 )
9.64408921E-03 2 -1000037 3 # BR(SuL -> Cha_2^* Fd_2 )
8.44007281E-02 2 -1000047 1 # BR(SuL -> Cha_3^* Fd_1 )
3.08497289E-03 2 -1000047 3 # BR(SuL -> Cha_3^* Fd_2 )
2.13566287E-01 2 1000021 2 # BR(SuL -> Glu_1 Fu_1 )
3.25312310E-04 2 1000021 4 # BR(SuL -> Glu_1 Fu_2 )
2.13563412E-01 2 2000021 2 # BR(SuL -> Glu_2 Fu_1 )
3.25296885E-04 2 2000021 4 # BR(SuL -> Glu_2 Fu_2 )
DECAY 1000004 5.13537661E+01 # ScL
# BR NDA ID1 ID2
1.42451325E-04 2 2 1000045 # BR(ScL -> Fu_1 Chi_5 )
1.25684113E-04 2 2 1000055 # BR(ScL -> Fu_1 Chi_6 )
3.83844330E-03 2 4 1000022 # BR(ScL -> Fu_2 Chi_1 )
3.47321759E-03 2 4 1000023 # BR(ScL -> Fu_2 Chi_2 )
1.05616029E-02 2 4 1000025 # BR(ScL -> Fu_2 Chi_3 )
9.38885928E-02 2 4 1000045 # BR(ScL -> Fu_2 Chi_5 )
8.28416691E-02 2 4 1000055 # BR(ScL -> Fu_2 Chi_6 )
5.91350946E-04 2 6 1000025 # BR(ScL -> Fu_3 Chi_3 )
6.58532850E-04 2 6 1000035 # BR(ScL -> Fu_3 Chi_4 )
1.70680680E-04 2 6 1000045 # BR(ScL -> Fu_3 Chi_5 )
2.46595222E-04 2 6 1000055 # BR(ScL -> Fu_3 Chi_6 )
5.54093975E-04 2 -1000024 1 # BR(ScL -> Cha_1^* Fd_1 )
1.51605914E-02 2 -1000024 3 # BR(ScL -> Cha_1^* Fd_2 )
9.63086655E-03 2 -1000037 1 # BR(ScL -> Cha_2^* Fd_1 )
2.63486315E-01 2 -1000037 3 # BR(ScL -> Cha_2^* Fd_2 )
3.08089267E-03 2 -1000047 1 # BR(ScL -> Cha_3^* Fd_1 )
8.42875960E-02 2 -1000047 3 # BR(ScL -> Cha_3^* Fd_2 )
3.23046393E-04 2 1000021 2 # BR(ScL -> Glu_1 Fu_1 )
2.12925892E-01 2 1000021 4 # BR(ScL -> Glu_1 Fu_2 )
3.43407669E-04 2 1000021 6 # BR(ScL -> Glu_1 Fu_3 )
3.23042045E-04 2 2000021 2 # BR(ScL -> Glu_2 Fu_1 )
2.12915815E-01 2 2000021 4 # BR(ScL -> Glu_2 Fu_2 )
3.45071270E-04 2 2000021 6 # BR(ScL -> Glu_2 Fu_3 )
DECAY 1000006 2.03058234E+02 # St1
# BR NDA ID1 ID2
1.90252367E-02 2 6 1000022 # BR(St1 -> Fu_3 Chi_1 )
5.73816164E-03 2 6 1000023 # BR(St1 -> Fu_3 Chi_2 )
1.36920289E-01 2 6 1000025 # BR(St1 -> Fu_3 Chi_3 )
1.38494385E-01 2 6 1000035 # BR(St1 -> Fu_3 Chi_4 )
3.48113256E-02 2 6 1000045 # BR(St1 -> Fu_3 Chi_5 )
2.17222458E-02 2 6 1000055 # BR(St1 -> Fu_3 Chi_6 )
1.08519174E-04 2 -1000024 3 # BR(St1 -> Cha_1^* Fd_2 )
9.99012489E-02 2 -1000024 5 # BR(St1 -> Cha_1^* Fd_3 )
7.64162349E-02 2 -1000037 5 # BR(St1 -> Cha_2^* Fd_3 )
2.53157900E-03 2 -1000047 5 # BR(St1 -> Cha_3^* Fd_3 )
3.00505589E-04 2 1000021 4 # BR(St1 -> Glu_1 Fu_2 )
2.16075585E-01 2 1000021 6 # BR(St1 -> Glu_1 Fu_3 )
3.00504975E-04 2 2000021 4 # BR(St1 -> Glu_2 Fu_2 )
2.47535172E-01 2 2000021 6 # BR(St1 -> Glu_2 Fu_3 )
DECAY 2000006 2.15936137E+02 # St2
# BR NDA ID1 ID2
1.38336698E-02 2 6 1000022 # BR(St2 -> Fu_3 Chi_1 )
1.41609015E-02 2 6 1000023 # BR(St2 -> Fu_3 Chi_2 )
1.05800432E-01 2 6 1000025 # BR(St2 -> Fu_3 Chi_3 )
1.33912866E-01 2 6 1000035 # BR(St2 -> Fu_3 Chi_4 )
3.44589720E-03 2 6 1000045 # BR(St2 -> Fu_3 Chi_5 )
4.99061203E-02 2 6 1000055 # BR(St2 -> Fu_3 Chi_6 )
3.01206490E-04 2 -1000024 3 # BR(St2 -> Cha_1^* Fd_2 )
1.46049481E-01 2 -1000024 5 # BR(St2 -> Cha_1^* Fd_3 )
2.32024176E-02 2 -1000037 5 # BR(St2 -> Cha_2^* Fd_3 )
6.98153781E-02 2 -1000047 5 # BR(St2 -> Cha_3^* Fd_3 )
2.34434579E-01 2 1000021 6 # BR(St2 -> Glu_1 Fu_3 )
2.04854943E-01 2 2000021 6 # BR(St2 -> Glu_2 Fu_3 )
DECAY 2000015 8.18637837E+00 # Stau2
# BR NDA ID1 ID2
1.02082535E-02 2 16 1000024 # BR(Stau2 -> Fv_3 Cha_1 )
2.29151087E-02 2 16 1000037 # BR(Stau2 -> Fv_3 Cha_2 )
4.80804462E-02 2 16 1000047 # BR(Stau2 -> Fv_3 Cha_3 )
4.48198185E-01 2 15 1000022 # BR(Stau2 -> Fe_3 Chi_1 )
4.20256915E-01 2 15 1000023 # BR(Stau2 -> Fe_3 Chi_2 )
1.30717819E-02 2 15 1000025 # BR(Stau2 -> Fe_3 Chi_3 )
2.29748327E-03 2 15 1000035 # BR(Stau2 -> Fe_3 Chi_4 )
1.98408505E-02 2 15 1000045 # BR(Stau2 -> Fe_3 Chi_5 )
1.51309759E-02 2 15 1000055 # BR(Stau2 -> Fe_3 Chi_6 )
DECAY 2000013 7.57672843E+00 # SmuR
# BR NDA ID1 ID2
1.10283127E-04 2 14 1000037 # BR(SmuR -> Fv_2 Cha_2 )
2.34103666E-04 2 14 1000047 # BR(SmuR -> Fv_2 Cha_3 )
5.11017189E-01 2 13 1000022 # BR(SmuR -> Fe_2 Chi_1 )
4.77934346E-01 2 13 1000023 # BR(SmuR -> Fe_2 Chi_2 )
8.55792644E-03 2 13 1000025 # BR(SmuR -> Fe_2 Chi_3 )
1.27280242E-03 2 13 1000035 # BR(SmuR -> Fe_2 Chi_4 )
1.20848406E-04 2 13 1000045 # BR(SmuR -> Fe_2 Chi_5 )
7.05962644E-04 2 13 1000055 # BR(SmuR -> Fe_2 Chi_6 )
DECAY 2000011 7.57401359E+00 # SeR
# BR NDA ID1 ID2
5.11320380E-01 2 11 1000022 # BR(SeR -> Fe_1 Chi_1 )
4.78213147E-01 2 11 1000023 # BR(SeR -> Fe_1 Chi_2 )
8.53737326E-03 2 11 1000025 # BR(SeR -> Fe_1 Chi_3 )
1.26878456E-03 2 11 1000035 # BR(SeR -> Fe_1 Chi_4 )
6.35148272E-04 2 11 1000055 # BR(SeR -> Fe_1 Chi_6 )
DECAY 1000011 1.59582153E+01 # SeL
# BR NDA ID1 ID2
3.05089932E-02 2 12 1000024 # BR(SeL -> Fv_1 Cha_1 )
1.61927710E-01 2 12 1000037 # BR(SeL -> Fv_1 Cha_2 )
3.93609722E-01 2 12 1000047 # BR(SeL -> Fv_1 Cha_3 )
6.16871294E-02 2 11 1000022 # BR(SeL -> Fe_1 Chi_1 )
5.70346458E-02 2 11 1000023 # BR(SeL -> Fe_1 Chi_2 )
2.41753784E-02 2 11 1000025 # BR(SeL -> Fe_1 Chi_3 )
1.46375070E-01 2 11 1000045 # BR(SeL -> Fe_1 Chi_5 )
1.24665730E-01 2 11 1000055 # BR(SeL -> Fe_1 Chi_6 )
DECAY 1000013 1.59556395E+01 # SmuL
# BR NDA ID1 ID2
3.04944553E-02 2 14 1000024 # BR(SmuL -> Fv_2 Cha_1 )
1.61901499E-01 2 14 1000037 # BR(SmuL -> Fv_2 Cha_2 )
3.93562353E-01 2 14 1000047 # BR(SmuL -> Fv_2 Cha_3 )
6.17540619E-02 2 13 1000022 # BR(SmuL -> Fe_2 Chi_1 )
5.70949416E-02 2 13 1000023 # BR(SmuL -> Fe_2 Chi_2 )
2.41706430E-02 2 13 1000025 # BR(SmuL -> Fe_2 Chi_3 )
1.46353251E-01 2 13 1000045 # BR(SmuL -> Fe_2 Chi_5 )
1.24652421E-01 2 13 1000055 # BR(SmuL -> Fe_2 Chi_6 )
DECAY 1000015 1.53851602E+01 # Stau1
# BR NDA ID1 ID2
2.69864654E-02 2 16 1000024 # BR(Stau1 -> Fv_3 Cha_1 )
1.55771013E-01 2 16 1000037 # BR(Stau1 -> Fv_3 Cha_2 )
3.82761175E-01 2 16 1000047 # BR(Stau1 -> Fv_3 Cha_3 )
7.72204176E-02 2 15 1000022 # BR(Stau1 -> Fe_3 Chi_1 )
7.09821078E-02 2 15 1000023 # BR(Stau1 -> Fe_3 Chi_2 )
2.30782257E-02 2 15 1000025 # BR(Stau1 -> Fe_3 Chi_3 )
2.60881783E-04 2 15 1000035 # BR(Stau1 -> Fe_3 Chi_4 )
1.41280788E-01 2 15 1000045 # BR(Stau1 -> Fe_3 Chi_5 )
1.21658925E-01 2 15 1000055 # BR(Stau1 -> Fe_3 Chi_6 )
DECAY 1000016 1.59625578E+01 # Snu_tau
# BR NDA ID1 ID2
5.97252721E-02 2 16 1000022 # BR(Snu_tau -> Fv_3 Chi_1 )
5.65094684E-02 2 16 1000023 # BR(Snu_tau -> Fv_3 Chi_2 )
8.41222881E-03 2 16 1000025 # BR(Snu_tau -> Fv_3 Chi_3 )
4.23915911E-04 2 16 1000035 # BR(Snu_tau -> Fv_3 Chi_4 )
1.48779922E-01 2 16 1000045 # BR(Snu_tau -> Fv_3 Chi_5 )
1.37001990E-01 2 16 1000055 # BR(Snu_tau -> Fv_3 Chi_6 )
2.74888013E-02 2 -1000024 15 # BR(Snu_tau -> Cha_1^* Fe_3 )
4.26496484E-01 2 -1000037 15 # BR(Snu_tau -> Cha_2^* Fe_3 )
1.35161917E-01 2 -1000047 15 # BR(Snu_tau -> Cha_3^* Fe_3 )
DECAY 1000014 1.59495218E+01 # Snu_mu
# BR NDA ID1 ID2
5.97743685E-02 2 14 1000022 # BR(Snu_mu -> Fv_2 Chi_1 )
5.65559220E-02 2 14 1000023 # BR(Snu_mu -> Fv_2 Chi_2 )
8.41915275E-03 2 14 1000025 # BR(Snu_mu -> Fv_2 Chi_3 )
4.24264889E-04 2 14 1000035 # BR(Snu_mu -> Fv_2 Chi_4 )
1.48902561E-01 2 14 1000045 # BR(Snu_mu -> Fv_2 Chi_5 )
1.37114938E-01 2 14 1000055 # BR(Snu_mu -> Fv_2 Chi_6 )
2.67704071E-02 2 -1000024 13 # BR(Snu_mu -> Cha_1^* Fe_2 )
4.26839277E-01 2 -1000037 13 # BR(Snu_mu -> Cha_2^* Fe_2 )
1.35199109E-01 2 -1000047 13 # BR(Snu_mu -> Cha_3^* Fe_2 )
DECAY 1000012 1.59494755E+01 # Snu_e
# BR NDA ID1 ID2
5.97745429E-02 2 12 1000022 # BR(Snu_e -> Fv_1 Chi_1 )
5.65560870E-02 2 12 1000023 # BR(Snu_e -> Fv_1 Chi_2 )
8.41917735E-03 2 12 1000025 # BR(Snu_e -> Fv_1 Chi_3 )
4.24266128E-04 2 12 1000035 # BR(Snu_e -> Fv_1 Chi_4 )
1.48902996E-01 2 12 1000045 # BR(Snu_e -> Fv_1 Chi_5 )
1.37115339E-01 2 12 1000055 # BR(Snu_e -> Fv_1 Chi_6 )
2.67678554E-02 2 -1000024 11 # BR(Snu_e -> Cha_1^* Fe_1 )
4.26840495E-01 2 -1000037 11 # BR(Snu_e -> Cha_2^* Fe_1 )
1.35199241E-01 2 -1000047 11 # BR(Snu_e -> Cha_3^* Fe_1 )
DECAY 25 2.60608337E-03 # hh_1
# BR NDA ID1 ID2
2.86978983E-03 2 22 22 # BR(hh_1 -> VP VP )
9.04531371E-02 2 21 21 # BR(hh_1 -> VG VG )
2.59876756E-03 2 23 23 # BR(hh_1 -> VZ VZ )
6.15902598E-02 2 24 -24 # BR(hh_1 -> VWm^* VWm_virt )
2.71008356E-04 2 -3 3 # BR(hh_1 -> Fd_2^* Fd_2 )
7.25330946E-01 2 -5 5 # BR(hh_1 -> Fd_3^* Fd_3 )
2.85702684E-04 2 -13 13 # BR(hh_1 -> Fe_2^* Fe_2 )
8.24409370E-02 2 -15 15 # BR(hh_1 -> Fe_3^* Fe_3 )
3.41585478E-02 2 -4 4 # BR(hh_1 -> Fu_2^* Fu_2 )
DECAY 35 3.77797217E+01 # hh_2
# BR NDA ID1 ID2
8.45598278E-03 2 -1000024 1000024 # BR(hh_2 -> Cha_1^* Cha_1 )
6.71494568E-02 2 -1000024 1000037 # BR(hh_2 -> Cha_1^* Cha_2 )
7.44077705E-03 2 -1000024 1000047 # BR(hh_2 -> Cha_1^* Cha_3 )
6.71494568E-02 2 -1000037 1000024 # BR(hh_2 -> Cha_2^* Cha_1 )
9.55151129E-02 2 -1000037 1000037 # BR(hh_2 -> Cha_2^* Cha_2 )
3.20762340E-01 2 -1000037 1000047 # BR(hh_2 -> Cha_2^* Cha_3 )
7.44077705E-03 2 -1000047 1000024 # BR(hh_2 -> Cha_3^* Cha_1 )
3.20762340E-01 2 -1000047 1000037 # BR(hh_2 -> Cha_3^* Cha_2 )
8.61817464E-02 2 -1000047 1000047 # BR(hh_2 -> Cha_3^* Cha_3 )
2.31393153E-04 2 1000022 1000035 # BR(hh_2 -> Chi_1 Chi_4 )
1.17886603E-04 2 1000023 1000025 # BR(hh_2 -> Chi_2 Chi_3 )
2.55792751E-03 2 1000025 1000025 # BR(hh_2 -> Chi_3 Chi_3 )
4.57949794E-04 2 1000025 1000055 # BR(hh_2 -> Chi_3 Chi_6 )
2.87808808E-03 2 1000035 1000035 # BR(hh_2 -> Chi_4 Chi_4 )
3.05668847E-03 2 25 25 # BR(hh_2 -> hh_1 hh_1 )
2.19600919E-04 2 -37 24 # BR(hh_2 -> Hpm_2 VWm^* )
2.19600919E-04 2 37 -24 # BR(hh_2 -> Hpm_2^* VWm )
6.58474058E-03 2 -24 24 # BR(hh_2 -> VWm VWm^* )
2.51058832E-03 2 23 23 # BR(hh_2 -> VZ VZ )
DECAY 45 1.64301934E+01 # hh_3
# BR NDA ID1 ID2
1.87765619E-01 2 -1000024 1000024 # BR(hh_3 -> Cha_1^* Cha_1 )
6.68696470E-04 2 -1000024 1000037 # BR(hh_3 -> Cha_1^* Cha_2 )
2.55136087E-02 2 -1000024 1000047 # BR(hh_3 -> Cha_1^* Cha_3 )
6.68696470E-04 2 -1000037 1000024 # BR(hh_3 -> Cha_2^* Cha_1 )
3.85047780E-04 2 -1000037 1000047 # BR(hh_3 -> Cha_2^* Cha_3 )
2.55136087E-02 2 -1000047 1000024 # BR(hh_3 -> Cha_3^* Cha_1 )
3.85047780E-04 2 -1000047 1000037 # BR(hh_3 -> Cha_3^* Cha_2 )
2.57900062E-03 2 -1000047 1000047 # BR(hh_3 -> Cha_3^* Cha_3 )
9.93238205E-02 2 1000022 1000022 # BR(hh_3 -> Chi_1 Chi_1 )
2.23541648E-01 2 1000022 1000023 # BR(hh_3 -> Chi_1 Chi_2 )
1.14728941E-03 2 1000022 1000025 # BR(hh_3 -> Chi_1 Chi_3 )
2.56382899E-02 2 1000022 1000035 # BR(hh_3 -> Chi_1 Chi_4 )
1.19516214E-04 2 1000022 1000055 # BR(hh_3 -> Chi_1 Chi_6 )
1.21944418E-01 2 1000023 1000023 # BR(hh_3 -> Chi_2 Chi_2 )
1.17102101E-03 2 1000023 1000025 # BR(hh_3 -> Chi_2 Chi_3 )
1.89007687E-02 2 1000023 1000035 # BR(hh_3 -> Chi_2 Chi_4 )
1.99492107E-04 2 1000023 1000055 # BR(hh_3 -> Chi_2 Chi_6 )
9.19728358E-02 2 1000025 1000025 # BR(hh_3 -> Chi_3 Chi_3 )
7.12009061E-04 2 1000025 1000045 # BR(hh_3 -> Chi_3 Chi_5 )
2.56553281E-02 2 1000025 1000055 # BR(hh_3 -> Chi_3 Chi_6 )
1.07552795E-01 2 1000035 1000035 # BR(hh_3 -> Chi_4 Chi_4 )
8.21290960E-04 2 1000035 1000045 # BR(hh_3 -> Chi_4 Chi_5 )
1.13746956E-04 2 1000035 1000055 # BR(hh_3 -> Chi_4 Chi_6 )
1.74869938E-03 2 1000055 1000055 # BR(hh_3 -> Chi_6 Chi_6 )
8.11061350E-04 2 -6 6 # BR(hh_3 -> Fu_3^* Fu_3 )
5.63680422E-03 2 25 25 # BR(hh_3 -> hh_1 hh_1 )
3.36216026E-03 2 -47 24 # BR(hh_3 -> Hpm_3 VWm^* )
3.36216026E-03 2 47 -24 # BR(hh_3 -> Hpm_3^* VWm )
1.55969116E-02 2 -24 24 # BR(hh_3 -> VWm VWm^* )
7.02545758E-03 2 23 23 # BR(hh_3 -> VZ VZ )
DECAY 55 7.24470333E+01 # hh_4
# BR NDA ID1 ID2
1.80436469E-04 2 21 21 # BR(hh_4 -> VG VG )
6.72715118E-03 2 -1000024 1000024 # BR(hh_4 -> Cha_1^* Cha_1 )
7.78615271E-02 2 -1000024 1000037 # BR(hh_4 -> Cha_1^* Cha_2 )
5.45990415E-02 2 -1000024 1000047 # BR(hh_4 -> Cha_1^* Cha_3 )
7.78615271E-02 2 -1000037 1000024 # BR(hh_4 -> Cha_2^* Cha_1 )
1.58028595E-03 2 -1000037 1000037 # BR(hh_4 -> Cha_2^* Cha_2 )
1.38950578E-02 2 -1000037 1000047 # BR(hh_4 -> Cha_2^* Cha_3 )
5.45990415E-02 2 -1000047 1000024 # BR(hh_4 -> Cha_3^* Cha_1 )
1.38950578E-02 2 -1000047 1000037 # BR(hh_4 -> Cha_3^* Cha_2 )
3.20750179E-04 2 -1000047 1000047 # BR(hh_4 -> Cha_3^* Cha_3 )
2.65908542E-03 2 1000022 1000022 # BR(hh_4 -> Chi_1 Chi_1 )
2.10728091E-04 2 1000022 1000023 # BR(hh_4 -> Chi_1 Chi_2 )
1.59057665E-02 2 1000022 1000025 # BR(hh_4 -> Chi_1 Chi_3 )
3.65560772E-02 2 1000022 1000035 # BR(hh_4 -> Chi_1 Chi_4 )
2.62285628E-03 2 1000022 1000045 # BR(hh_4 -> Chi_1 Chi_5 )
1.00341483E-03 2 1000022 1000055 # BR(hh_4 -> Chi_1 Chi_6 )
1.06720635E-03 2 1000023 1000023 # BR(hh_4 -> Chi_2 Chi_2 )
5.04556364E-02 2 1000023 1000025 # BR(hh_4 -> Chi_2 Chi_3 )
6.21804350E-03 2 1000023 1000035 # BR(hh_4 -> Chi_2 Chi_4 )
1.26139071E-03 2 1000023 1000045 # BR(hh_4 -> Chi_2 Chi_5 )
2.64462273E-03 2 1000023 1000055 # BR(hh_4 -> Chi_2 Chi_6 )
2.61638644E-03 2 1000025 1000025 # BR(hh_4 -> Chi_3 Chi_3 )
3.25142244E-04 2 1000025 1000035 # BR(hh_4 -> Chi_3 Chi_4 )
1.19802745E-03 2 1000025 1000045 # BR(hh_4 -> Chi_3 Chi_5 )
1.19719364E-02 2 1000025 1000055 # BR(hh_4 -> Chi_3 Chi_6 )
1.49482537E-03 2 1000035 1000035 # BR(hh_4 -> Chi_4 Chi_4 )
6.75899037E-02 2 1000035 1000045 # BR(hh_4 -> Chi_4 Chi_5 )
6.41720594E-02 2 1000035 1000055 # BR(hh_4 -> Chi_4 Chi_6 )
2.62519188E-04 2 1000045 1000045 # BR(hh_4 -> Chi_5 Chi_5 )
2.92211036E-03 2 1000055 1000055 # BR(hh_4 -> Chi_6 Chi_6 )
1.68985080E-03 2 -5 5 # BR(hh_4 -> Fd_3^* Fd_3 )
3.05340952E-04 2 -15 15 # BR(hh_4 -> Fe_3^* Fe_3 )
4.10260950E-01 2 -6 6 # BR(hh_4 -> Fu_3^* Fu_3 )
3.83820617E-03 2 25 35 # BR(hh_4 -> hh_1 hh_2 )
1.09245783E-04 2 25 45 # BR(hh_4 -> hh_1 hh_3 )
4.41289187E-03 2 -47 24 # BR(hh_4 -> Hpm_3 VWm^* )
4.41289187E-03 2 47 -24 # BR(hh_4 -> Hpm_3^* VWm )
DECAY 36 5.29711210E-04 # Ah_2
# BR NDA ID1 ID2
6.99960291E-04 2 22 22 # BR(Ah_2 -> VP VP )
1.35862885E-02 2 1000022 1000022 # BR(Ah_2 -> Chi_1 Chi_1 )
2.61526519E-02 2 1000022 1000023 # BR(Ah_2 -> Chi_1 Chi_2 )
2.90565589E-02 2 1000022 1000025 # BR(Ah_2 -> Chi_1 Chi_3 )
6.40558757E-01 2 1000022 1000035 # BR(Ah_2 -> Chi_1 Chi_4 )
2.82543229E-01 2 1000023 1000025 # BR(Ah_2 -> Chi_2 Chi_3 )
7.30598163E-03 2 1000023 1000035 # BR(Ah_2 -> Chi_2 Chi_4 )
DECAY 46 2.03000616E+01 # Ah_3
# BR NDA ID1 ID2
2.09299143E-01 2 -1000024 1000024 # BR(Ah_3 -> Cha_1^* Cha_1 )
1.02824803E-03 2 -1000024 1000037 # BR(Ah_3 -> Cha_1^* Cha_2 )
2.90959205E-02 2 -1000024 1000047 # BR(Ah_3 -> Cha_1^* Cha_3 )
1.02824803E-03 2 -1000037 1000024 # BR(Ah_3 -> Cha_2^* Cha_1 )
1.72933389E-04 2 -1000037 1000047 # BR(Ah_3 -> Cha_2^* Cha_3 )
2.90959205E-02 2 -1000047 1000024 # BR(Ah_3 -> Cha_3^* Cha_1 )
1.72933389E-04 2 -1000047 1000037 # BR(Ah_3 -> Cha_3^* Cha_2 )
3.81401895E-03 2 -1000047 1000047 # BR(Ah_3 -> Cha_3^* Cha_3 )
9.79675901E-02 2 1000022 1000022 # BR(Ah_3 -> Chi_1 Chi_1 )
2.06916857E-01 2 1000022 1000023 # BR(Ah_3 -> Chi_1 Chi_2 )
1.38371279E-03 2 1000022 1000025 # BR(Ah_3 -> Chi_1 Chi_3 )
2.58857986E-02 2 1000022 1000035 # BR(Ah_3 -> Chi_1 Chi_4 )
1.31039613E-04 2 1000022 1000055 # BR(Ah_3 -> Chi_1 Chi_6 )
1.19323172E-01 2 1000023 1000023 # BR(Ah_3 -> Chi_2 Chi_2 )
1.03066959E-03 2 1000023 1000025 # BR(Ah_3 -> Chi_2 Chi_3 )
1.82818962E-02 2 1000023 1000035 # BR(Ah_3 -> Chi_2 Chi_4 )
1.98748856E-04 2 1000023 1000055 # BR(Ah_3 -> Chi_2 Chi_6 )
1.01278976E-01 2 1000025 1000025 # BR(Ah_3 -> Chi_3 Chi_3 )
7.78913984E-04 2 1000025 1000045 # BR(Ah_3 -> Chi_3 Chi_5 )
2.96937773E-02 2 1000025 1000055 # BR(Ah_3 -> Chi_3 Chi_6 )
1.20144299E-01 2 1000035 1000035 # BR(Ah_3 -> Chi_4 Chi_4 )
7.00544945E-04 2 1000035 1000045 # BR(Ah_3 -> Chi_4 Chi_5 )
2.27273690E-04 2 1000035 1000055 # BR(Ah_3 -> Chi_4 Chi_6 )
2.15026684E-03 2 1000055 1000055 # BR(Ah_3 -> Chi_6 Chi_6 )
DECAY 56 7.26526228E+01 # Ah_4
# BR NDA ID1 ID2
2.12373184E-04 2 21 21 # BR(Ah_4 -> VG VG )
1.93134007E-02 2 -1000024 1000024 # BR(Ah_4 -> Cha_1^* Cha_1 )
8.38046792E-02 2 -1000024 1000037 # BR(Ah_4 -> Cha_1^* Cha_2 )
3.78941216E-02 2 -1000024 1000047 # BR(Ah_4 -> Cha_1^* Cha_3 )
8.38046792E-02 2 -1000037 1000024 # BR(Ah_4 -> Cha_2^* Cha_1 )
1.58761401E-03 2 -1000037 1000037 # BR(Ah_4 -> Cha_2^* Cha_2 )
7.65909750E-03 2 -1000037 1000047 # BR(Ah_4 -> Cha_2^* Cha_3 )
3.78941216E-02 2 -1000047 1000024 # BR(Ah_4 -> Cha_3^* Cha_1 )
7.65909750E-03 2 -1000047 1000037 # BR(Ah_4 -> Cha_3^* Cha_2 )
2.15223170E-02 2 -1000047 1000047 # BR(Ah_4 -> Cha_3^* Cha_3 )
1.96077745E-03 2 1000022 1000022 # BR(Ah_4 -> Chi_1 Chi_1 )
4.07225916E-04 2 1000022 1000023 # BR(Ah_4 -> Chi_1 Chi_2 )
3.38369103E-02 2 1000022 1000025 # BR(Ah_4 -> Chi_1 Chi_3 )
1.52041971E-02 2 1000022 1000035 # BR(Ah_4 -> Chi_1 Chi_4 )
1.15720254E-03 2 1000022 1000045 # BR(Ah_4 -> Chi_1 Chi_5 )
5.73273219E-03 2 1000022 1000055 # BR(Ah_4 -> Chi_1 Chi_6 )
1.23948096E-03 2 1000023 1000023 # BR(Ah_4 -> Chi_2 Chi_2 )
6.76364989E-03 2 1000023 1000025 # BR(Ah_4 -> Chi_2 Chi_3 )
5.27740197E-02 2 1000023 1000035 # BR(Ah_4 -> Chi_2 Chi_4 )
2.63000331E-04 2 1000023 1000045 # BR(Ah_4 -> Chi_2 Chi_5 )
5.09170275E-03 2 1000025 1000025 # BR(Ah_4 -> Chi_3 Chi_3 )
4.06870808E-03 2 1000025 1000035 # BR(Ah_4 -> Chi_3 Chi_4 )
6.20668962E-02 2 1000025 1000045 # BR(Ah_4 -> Chi_3 Chi_5 )
4.25333886E-02 2 1000025 1000055 # BR(Ah_4 -> Chi_3 Chi_6 )
2.88505628E-03 2 1000035 1000035 # BR(Ah_4 -> Chi_4 Chi_4 )
1.58943033E-03 2 1000035 1000045 # BR(Ah_4 -> Chi_4 Chi_5 )
1.36883504E-02 2 1000035 1000055 # BR(Ah_4 -> Chi_4 Chi_6 )
4.74665734E-04 2 1000045 1000045 # BR(Ah_4 -> Chi_5 Chi_5 )
7.23114429E-03 2 1000045 1000055 # BR(Ah_4 -> Chi_5 Chi_6 )
1.33426013E-02 2 1000055 1000055 # BR(Ah_4 -> Chi_6 Chi_6 )
1.68631039E-03 2 -5 5 # BR(Ah_4 -> Fd_3^* Fd_3 )
3.04700093E-04 2 -15 15 # BR(Ah_4 -> Fe_3^* Fe_3 )
4.12536789E-01 2 -6 6 # BR(Ah_4 -> Fu_3^* Fu_3 )
3.84449510E-03 2 35 23 # BR(Ah_4 -> hh_2 VZ )
1.59796816E-04 2 45 23 # BR(Ah_4 -> hh_3 VZ )
3.84427784E-03 2 -47 24 # BR(Ah_4 -> Hpm_3 VWm^* )
3.84427784E-03 2 47 -24 # BR(Ah_4 -> Hpm_3^* VWm )
DECAY 37 1.36693932E-04 # Hpm_2
# BR NDA ID1 ID2
6.69694532E-01 2 1000022 -1000024 # BR(Hpm_2^* -> Chi_1 Cha_1^* )
3.30194817E-01 2 1000023 -1000024 # BR(Hpm_2^* -> Chi_2 Cha_1^* )
DECAY 47 3.38534161E+01 # Hpm_3
# BR NDA ID1 ID2
2.10542545E-04 2 36 24 # BR(Hpm_3^* -> Ah_2 VWm^* )
4.40014697E-04 2 1000022 -1000024 # BR(Hpm_3^* -> Chi_1 Cha_1^* )
1.79361278E-04 2 1000023 -1000024 # BR(Hpm_3^* -> Chi_2 Cha_1^* )
7.34235883E-03 2 1000025 -1000024 # BR(Hpm_3^* -> Chi_3 Cha_1^* )
7.31221364E-02 2 1000025 -1000037 # BR(Hpm_3^* -> Chi_3 Cha_2^* )
5.14655769E-03 2 1000025 -1000047 # BR(Hpm_3^* -> Chi_3 Cha_3^* )
8.32020261E-03 2 1000035 -1000024 # BR(Hpm_3^* -> Chi_4 Cha_1^* )
8.28171807E-04 2 1000035 -1000037 # BR(Hpm_3^* -> Chi_4 Cha_2^* )
7.07121324E-02 2 1000045 -1000024 # BR(Hpm_3^* -> Chi_5 Cha_1^* )
2.53180862E-02 2 1000045 -1000037 # BR(Hpm_3^* -> Chi_5 Cha_2^* )
3.86458168E-01 2 1000045 -1000047 # BR(Hpm_3^* -> Chi_5 Cha_3^* )
3.43771683E-03 2 1000055 -1000024 # BR(Hpm_3^* -> Chi_6 Cha_1^* )
3.84537585E-01 2 1000055 -1000037 # BR(Hpm_3^* -> Chi_6 Cha_2^* )
2.38158813E-02 2 1000055 -1000047 # BR(Hpm_3^* -> Chi_6 Cha_3^* )
2.29535907E-04 2 37 25 # BR(Hpm_3^* -> Hpm_2^* hh_1 )
4.30473908E-03 2 25 24 # BR(Hpm_3^* -> hh_1 VWm^* )
5.33109873E-03 2 24 23 # BR(Hpm_3^* -> VWm^* VZ )
DECAY 57 6.66892839E+01 # Hpm_4
# BR NDA ID1 ID2
5.60665880E-02 2 1000022 -1000024 # BR(Hpm_4^* -> Chi_1 Cha_1^* )
1.44831690E-03 2 1000022 -1000037 # BR(Hpm_4^* -> Chi_1 Cha_2^* )
9.45142752E-03 2 1000022 -1000047 # BR(Hpm_4^* -> Chi_1 Cha_3^* )
6.41265638E-02 2 1000023 -1000024 # BR(Hpm_4^* -> Chi_2 Cha_1^* )
2.04607612E-03 2 1000023 -1000037 # BR(Hpm_4^* -> Chi_2 Cha_2^* )
2.45773434E-03 2 1000023 -1000047 # BR(Hpm_4^* -> Chi_2 Cha_3^* )
6.76686199E-04 2 1000025 -1000024 # BR(Hpm_4^* -> Chi_3 Cha_1^* )
4.01671960E-02 2 1000025 -1000037 # BR(Hpm_4^* -> Chi_3 Cha_2^* )
9.79354482E-02 2 1000025 -1000047 # BR(Hpm_4^* -> Chi_3 Cha_3^* )
5.34224760E-03 2 1000035 -1000024 # BR(Hpm_4^* -> Chi_4 Cha_1^* )
4.96763558E-02 2 1000035 -1000037 # BR(Hpm_4^* -> Chi_4 Cha_2^* )
9.24950745E-02 2 1000035 -1000047 # BR(Hpm_4^* -> Chi_4 Cha_3^* )
5.96269486E-02 2 1000045 -1000024 # BR(Hpm_4^* -> Chi_5 Cha_1^* )
8.21769809E-04 2 1000045 -1000037 # BR(Hpm_4^* -> Chi_5 Cha_2^* )
1.04995653E-02 2 1000045 -1000047 # BR(Hpm_4^* -> Chi_5 Cha_3^* )
7.34050172E-02 2 1000055 -1000024 # BR(Hpm_4^* -> Chi_6 Cha_1^* )
1.12640370E-02 2 1000055 -1000037 # BR(Hpm_4^* -> Chi_6 Cha_2^* )
7.95604403E-04 2 1000055 -1000047 # BR(Hpm_4^* -> Chi_6 Cha_3^* )
7.02009731E-04 2 6 -3 # BR(Hpm_4^* -> Fu_3 Fd_2^* )
4.09256696E-01 2 6 -5 # BR(Hpm_4^* -> Fu_3 Fd_3^* )
3.31854096E-04 2 16 -15 # BR(Hpm_4^* -> Fv_3 Fe_3^* )
3.81863762E-03 2 47 25 # BR(Hpm_4^* -> Hpm_3^* hh_1 )
3.47300847E-03 2 35 24 # BR(Hpm_4^* -> hh_2 VWm^* )
1.51697801E-04 2 45 24 # BR(Hpm_4^* -> hh_3 VWm^* )
3.76083027E-03 2 47 23 # BR(Hpm_4^* -> Hpm_3^* VZ )
DECAY 3000021 0.00000000E+00 # phiO
# BR NDA ID1 ID2
DECAY 3000022 0.00000000E+00 # sigmaO
# BR NDA ID1 ID2
DECAY 1000021 1.92937222E-02 # Glu_1
# BR NDA ID1 ID2
# BR NDA ID1 ID2 ID3
6.30857643E-04 3 1 -1 1000022 # BR(Glu_1 -> Fd_1 Fd_1^* Chi_1 )
1.11409288E-02 3 1 -1 1000023 # BR(Glu_1 -> Fd_1 Fd_1^* Chi_2 )
1.61290540E-03 3 1 -1 1000025 # BR(Glu_1 -> Fd_1 Fd_1^* Chi_3 )
2.43608051E-02 3 1 -1 1000045 # BR(Glu_1 -> Fd_1 Fd_1^* Chi_5 )
2.25006935E-02 3 1 -1 1000055 # BR(Glu_1 -> Fd_1 Fd_1^* Chi_6 )
1.42093236E-04 3 1 -3 1000022 # BR(Glu_1 -> Fd_1 Fd_2^* Chi_1 )
1.37517809E-04 3 1 -3 1000023 # BR(Glu_1 -> Fd_1 Fd_2^* Chi_2 )
2.63733872E-04 3 1 -3 1000025 # BR(Glu_1 -> Fd_1 Fd_2^* Chi_3 )
2.88243995E-03 3 1 -3 1000045 # BR(Glu_1 -> Fd_1 Fd_2^* Chi_5 )
2.57332565E-03 3 1 -3 1000055 # BR(Glu_1 -> Fd_1 Fd_2^* Chi_6 )
1.42093236E-04 3 3 -1 1000022 # BR(Glu_1 -> Fd_2 Fd_1^* Chi_1 )
1.37517809E-04 3 3 -1 1000023 # BR(Glu_1 -> Fd_2 Fd_1^* Chi_2 )
2.63733872E-04 3 3 -1 1000025 # BR(Glu_1 -> Fd_2 Fd_1^* Chi_3 )
2.88243995E-03 3 3 -1 1000045 # BR(Glu_1 -> Fd_2 Fd_1^* Chi_5 )
2.57332565E-03 3 3 -1 1000055 # BR(Glu_1 -> Fd_2 Fd_1^* Chi_6 )
6.30902788E-04 3 3 -3 1000022 # BR(Glu_1 -> Fd_2 Fd_2^* Chi_1 )
1.11408614E-02 3 3 -3 1000023 # BR(Glu_1 -> Fd_2 Fd_2^* Chi_2 )
1.61315629E-03 3 3 -3 1000025 # BR(Glu_1 -> Fd_2 Fd_2^* Chi_3 )
2.43604009E-02 3 3 -3 1000045 # BR(Glu_1 -> Fd_2 Fd_2^* Chi_5 )
2.25003071E-02 3 3 -3 1000055 # BR(Glu_1 -> Fd_2 Fd_2^* Chi_6 )
6.85392504E-04 3 5 -5 1000022 # BR(Glu_1 -> Fd_3 Fd_3^* Chi_1 )
1.44537818E-03 3 5 -5 1000023 # BR(Glu_1 -> Fd_3 Fd_3^* Chi_2 )
6.25693411E-04 3 5 -5 1000025 # BR(Glu_1 -> Fd_3 Fd_3^* Chi_3 )
4.64951484E-03 3 5 -5 1000045 # BR(Glu_1 -> Fd_3 Fd_3^* Chi_5 )
4.09207105E-03 3 5 -5 1000055 # BR(Glu_1 -> Fd_3 Fd_3^* Chi_6 )
5.38011076E-03 3 1 -2 -1000024 # BR(Glu_1 -> Fd_1 Fu_1^* Cha_1^* )
5.38011076E-03 3 -1 2 1000024 # BR(Glu_1 -> Fd_1^* Fu_1 Cha_1 )
5.23748339E-02 3 1 -2 -1000037 # BR(Glu_1 -> Fd_1 Fu_1^* Cha_2^* )
5.23748339E-02 3 -1 2 1000037 # BR(Glu_1 -> Fd_1^* Fu_1 Cha_2 )
4.62721543E-02 3 1 -2 -1000047 # BR(Glu_1 -> Fd_1 Fu_1^* Cha_3^* )
4.62721543E-02 3 -1 2 1000047 # BR(Glu_1 -> Fd_1^* Fu_1 Cha_3 )
2.63827651E-04 3 1 -4 -1000024 # BR(Glu_1 -> Fd_1 Fu_2^* Cha_1^* )
2.63827651E-04 3 -1 4 1000024 # BR(Glu_1 -> Fd_1^* Fu_2 Cha_1 )
2.28610300E-03 3 1 -4 -1000037 # BR(Glu_1 -> Fd_1 Fu_2^* Cha_2^* )
2.28610300E-03 3 -1 4 1000037 # BR(Glu_1 -> Fd_1^* Fu_2 Cha_2 )
2.47250604E-03 3 1 -4 -1000047 # BR(Glu_1 -> Fd_1 Fu_2^* Cha_3^* )
2.47250604E-03 3 -1 4 1000047 # BR(Glu_1 -> Fd_1^* Fu_2 Cha_3 )
2.64058500E-04 3 3 -2 -1000024 # BR(Glu_1 -> Fd_2 Fu_1^* Cha_1^* )
2.64058500E-04 3 -3 2 1000024 # BR(Glu_1 -> Fd_2^* Fu_1 Cha_1 )
2.28973398E-03 3 3 -2 -1000037 # BR(Glu_1 -> Fd_2 Fu_1^* Cha_2^* )
2.28973398E-03 3 -3 2 1000037 # BR(Glu_1 -> Fd_2^* Fu_1 Cha_2 )
2.47672238E-03 3 3 -2 -1000047 # BR(Glu_1 -> Fd_2 Fu_1^* Cha_3^* )
2.47672238E-03 3 -3 2 1000047 # BR(Glu_1 -> Fd_2^* Fu_1 Cha_3 )
5.37689252E-03 3 3 -4 -1000024 # BR(Glu_1 -> Fd_2 Fu_2^* Cha_1^* )
5.37689252E-03 3 -3 4 1000024 # BR(Glu_1 -> Fd_2^* Fu_2 Cha_1 )
5.22824319E-02 3 3 -4 -1000037 # BR(Glu_1 -> Fd_2 Fu_2^* Cha_2^* )
5.22824319E-02 3 -3 4 1000037 # BR(Glu_1 -> Fd_2^* Fu_2 Cha_2 )
4.61919684E-02 3 3 -4 -1000047 # BR(Glu_1 -> Fd_2 Fu_2^* Cha_3^* )
4.61919684E-02 3 -3 4 1000047 # BR(Glu_1 -> Fd_2^* Fu_2 Cha_3 )
2.07598244E-04 3 3 -6 -1000024 # BR(Glu_1 -> Fd_2 Fu_3^* Cha_1^* )
2.07598244E-04 3 -3 6 1000024 # BR(Glu_1 -> Fd_2^* Fu_3 Cha_1 )
8.06455716E-05 3 3 -6 -1000037 # BR(Glu_1 -> Fd_2 Fu_3^* Cha_2^* )
8.06455716E-05 3 -3 6 1000037 # BR(Glu_1 -> Fd_2^* Fu_3 Cha_2 )
1.12970903E-04 3 3 -6 -1000047 # BR(Glu_1 -> Fd_2 Fu_3^* Cha_3^* )
1.12970903E-04 3 -3 6 1000047 # BR(Glu_1 -> Fd_2^* Fu_3 Cha_3 )
4.03782180E-02 3 5 -6 -1000024 # BR(Glu_1 -> Fd_3 Fu_3^* Cha_1^* )
4.03782180E-02 3 -5 6 1000024 # BR(Glu_1 -> Fd_3^* Fu_3 Cha_1 )
9.33173025E-03 3 5 -6 -1000037 # BR(Glu_1 -> Fd_3 Fu_3^* Cha_2^* )
9.33173025E-03 3 -5 6 1000037 # BR(Glu_1 -> Fd_3^* Fu_3 Cha_2 )
8.49248506E-03 3 5 -6 -1000047 # BR(Glu_1 -> Fd_3 Fu_3^* Cha_3^* )
8.49248506E-03 3 -5 6 1000047 # BR(Glu_1 -> Fd_3^* Fu_3 Cha_3 )
3.78057014E-02 3 2 -2 1000022 # BR(Glu_1 -> Fu_1 Fu_1^* Chi_1 )
1.35880286E-02 3 2 -2 1000023 # BR(Glu_1 -> Fu_1 Fu_1^* Chi_2 )
2.17498511E-03 3 2 -2 1000025 # BR(Glu_1 -> Fu_1 Fu_1^* Chi_3 )
2.68200061E-02 3 2 -2 1000045 # BR(Glu_1 -> Fu_1 Fu_1^* Chi_5 )
2.48164883E-02 3 2 -2 1000055 # BR(Glu_1 -> Fu_1 Fu_1^* Chi_6 )
3.77877069E-02 3 4 -4 1000022 # BR(Glu_1 -> Fu_2 Fu_2^* Chi_1 )
1.35941138E-02 3 4 -4 1000023 # BR(Glu_1 -> Fu_2 Fu_2^* Chi_2 )
2.17596081E-03 3 4 -4 1000025 # BR(Glu_1 -> Fu_2 Fu_2^* Chi_3 )
2.67247743E-02 3 4 -4 1000045 # BR(Glu_1 -> Fu_2 Fu_2^* Chi_5 )
2.47327970E-02 3 4 -4 1000055 # BR(Glu_1 -> Fu_2 Fu_2^* Chi_6 )
1.11450085E-04 3 4 -6 1000025 # BR(Glu_1 -> Fu_2 Fu_3^* Chi_3 )
1.21500633E-04 3 4 -6 1000035 # BR(Glu_1 -> Fu_2 Fu_3^* Chi_4 )
1.11450085E-04 3 6 -4 1000025 # BR(Glu_1 -> Fu_3 Fu_2^* Chi_3 )
1.21500633E-04 3 6 -4 1000035 # BR(Glu_1 -> Fu_3 Fu_2^* Chi_4 )
2.60488941E-03 3 6 -6 1000022 # BR(Glu_1 -> Fu_3 Fu_3^* Chi_1 )
2.91909121E-03 3 6 -6 1000023 # BR(Glu_1 -> Fu_3 Fu_3^* Chi_2 )
5.63667795E-02 3 6 -6 1000025 # BR(Glu_1 -> Fu_3 Fu_3^* Chi_3 )
1.00414588E-02 3 6 -6 1000035 # BR(Glu_1 -> Fu_3 Fu_3^* Chi_4 )
5.77988388E-03 3 6 -6 1000045 # BR(Glu_1 -> Fu_3 Fu_3^* Chi_5 )
1.37557830E-02 3 6 -6 1000055 # BR(Glu_1 -> Fu_3 Fu_3^* Chi_6 )
DECAY 2000021 1.95980411E-02 # Glu_2
# BR NDA ID1 ID2
# BR NDA ID1 ID2 ID3
1.16236637E-02 3 1 -1 1000022 # BR(Glu_2 -> Fd_1 Fd_1^* Chi_1 )
5.05154398E-04 3 1 -1 1000023 # BR(Glu_2 -> Fd_1 Fd_1^* Chi_2 )
3.46179371E-03 3 1 -1 1000025 # BR(Glu_2 -> Fd_1 Fd_1^* Chi_3 )
2.43096161E-02 3 1 -1 1000045 # BR(Glu_2 -> Fd_1 Fd_1^* Chi_5 )
2.06056771E-02 3 1 -1 1000055 # BR(Glu_2 -> Fd_1 Fd_1^* Chi_6 )
1.39889588E-04 3 1 -3 1000022 # BR(Glu_2 -> Fd_1 Fd_2^* Chi_1 )
1.35385325E-04 3 1 -3 1000023 # BR(Glu_2 -> Fd_1 Fd_2^* Chi_2 )
2.59643858E-04 3 1 -3 1000025 # BR(Glu_2 -> Fd_1 Fd_2^* Chi_3 )
2.83774779E-03 3 1 -3 1000045 # BR(Glu_2 -> Fd_1 Fd_2^* Chi_5 )
2.53342710E-03 3 1 -3 1000055 # BR(Glu_2 -> Fd_1 Fd_2^* Chi_6 )
1.39889588E-04 3 3 -1 1000022 # BR(Glu_2 -> Fd_2 Fd_1^* Chi_1 )
1.35385325E-04 3 3 -1 1000023 # BR(Glu_2 -> Fd_2 Fd_1^* Chi_2 )
2.59643858E-04 3 3 -1 1000025 # BR(Glu_2 -> Fd_2 Fd_1^* Chi_3 )
2.83774779E-03 3 3 -1 1000045 # BR(Glu_2 -> Fd_2 Fd_1^* Chi_5 )
2.53342710E-03 3 3 -1 1000055 # BR(Glu_2 -> Fd_2 Fd_1^* Chi_6 )
1.16235908E-02 3 3 -3 1000022 # BR(Glu_2 -> Fd_2 Fd_2^* Chi_1 )
5.05201076E-04 3 3 -3 1000023 # BR(Glu_2 -> Fd_2 Fd_2^* Chi_2 )
3.46165769E-03 3 3 -3 1000025 # BR(Glu_2 -> Fd_2 Fd_2^* Chi_3 )
2.43092504E-02 3 3 -3 1000045 # BR(Glu_2 -> Fd_2 Fd_2^* Chi_5 )
2.06053870E-02 3 3 -3 1000055 # BR(Glu_2 -> Fd_2 Fd_2^* Chi_6 )
1.51962485E-03 3 5 -5 1000022 # BR(Glu_2 -> Fd_3 Fd_3^* Chi_1 )
6.36970026E-04 3 5 -5 1000023 # BR(Glu_2 -> Fd_3 Fd_3^* Chi_2 )
4.56937909E-04 3 5 -5 1000025 # BR(Glu_2 -> Fd_3 Fd_3^* Chi_3 )
1.01098746E-04 3 5 -5 1000035 # BR(Glu_2 -> Fd_3 Fd_3^* Chi_4 )
4.66961323E-03 3 5 -5 1000045 # BR(Glu_2 -> Fd_3 Fd_3^* Chi_5 )
4.14685651E-03 3 5 -5 1000055 # BR(Glu_2 -> Fd_3 Fd_3^* Chi_6 )
5.29668239E-03 3 1 -2 -1000024 # BR(Glu_2 -> Fd_1 Fu_1^* Cha_1^* )
5.29668239E-03 3 -1 2 1000024 # BR(Glu_2 -> Fd_1^* Fu_1 Cha_1 )
5.15627350E-02 3 1 -2 -1000037 # BR(Glu_2 -> Fd_1 Fu_1^* Cha_2^* )
5.15627350E-02 3 -1 2 1000037 # BR(Glu_2 -> Fd_1^* Fu_1 Cha_2 )
4.55546867E-02 3 1 -2 -1000047 # BR(Glu_2 -> Fd_1 Fu_1^* Cha_3^* )
4.55546867E-02 3 -1 2 1000047 # BR(Glu_2 -> Fd_1^* Fu_1 Cha_3 )
2.59730044E-04 3 1 -4 -1000024 # BR(Glu_2 -> Fd_1 Fu_2^* Cha_1^* )
2.59730044E-04 3 -1 4 1000024 # BR(Glu_2 -> Fd_1^* Fu_2 Cha_1 )
2.25074134E-03 3 1 -4 -1000037 # BR(Glu_2 -> Fd_1 Fu_2^* Cha_2^* )
2.25074134E-03 3 -1 4 1000037 # BR(Glu_2 -> Fd_1^* Fu_2 Cha_2 )
2.43419771E-03 3 1 -4 -1000047 # BR(Glu_2 -> Fd_1 Fu_2^* Cha_3^* )
2.43419771E-03 3 -1 4 1000047 # BR(Glu_2 -> Fd_1^* Fu_2 Cha_3 )
2.59963529E-04 3 3 -2 -1000024 # BR(Glu_2 -> Fd_2 Fu_1^* Cha_1^* )
2.59963529E-04 3 -3 2 1000024 # BR(Glu_2 -> Fd_2^* Fu_1 Cha_1 )
2.25423135E-03 3 3 -2 -1000037 # BR(Glu_2 -> Fd_2 Fu_1^* Cha_2^* )
2.25423135E-03 3 -3 2 1000037 # BR(Glu_2 -> Fd_2^* Fu_1 Cha_2 )
2.43832202E-03 3 3 -2 -1000047 # BR(Glu_2 -> Fd_2 Fu_1^* Cha_3^* )
2.43832202E-03 3 -3 2 1000047 # BR(Glu_2 -> Fd_2^* Fu_1 Cha_3 )
5.28940577E-03 3 3 -4 -1000024 # BR(Glu_2 -> Fd_2 Fu_2^* Cha_1^* )
5.28940577E-03 3 -3 4 1000024 # BR(Glu_2 -> Fd_2^* Fu_2 Cha_1 )
5.14742876E-02 3 3 -4 -1000037 # BR(Glu_2 -> Fd_2 Fu_2^* Cha_2^* )
5.14742876E-02 3 -3 4 1000037 # BR(Glu_2 -> Fd_2^* Fu_2 Cha_2 )
4.54771666E-02 3 3 -4 -1000047 # BR(Glu_2 -> Fd_2 Fu_2^* Cha_3^* )
4.54771666E-02 3 -3 4 1000047 # BR(Glu_2 -> Fd_2^* Fu_2 Cha_3 )
2.12307021E-04 3 3 -6 -1000024 # BR(Glu_2 -> Fd_2 Fu_3^* Cha_1^* )
2.12307021E-04 3 -3 6 1000024 # BR(Glu_2 -> Fd_2^* Fu_3 Cha_1 )
7.90313833E-05 3 3 -6 -1000037 # BR(Glu_2 -> Fd_2 Fu_3^* Cha_2^* )
7.90313833E-05 3 -3 6 1000037 # BR(Glu_2 -> Fd_2^* Fu_3 Cha_2 )
1.12728592E-04 3 3 -6 -1000047 # BR(Glu_2 -> Fd_2 Fu_3^* Cha_3^* )
1.12728592E-04 3 -3 6 1000047 # BR(Glu_2 -> Fd_2^* Fu_3 Cha_3 )
3.45168262E-02 3 5 -6 -1000024 # BR(Glu_2 -> Fd_3 Fu_3^* Cha_1^* )
3.45168262E-02 3 -5 6 1000024 # BR(Glu_2 -> Fd_3^* Fu_3 Cha_1 )
7.62866868E-03 3 5 -6 -1000037 # BR(Glu_2 -> Fd_3 Fu_3^* Cha_2^* )
7.62866868E-03 3 -5 6 1000037 # BR(Glu_2 -> Fd_3^* Fu_3 Cha_2 )
1.93970003E-02 3 5 -6 -1000047 # BR(Glu_2 -> Fd_3 Fu_3^* Cha_3^* )
1.93970003E-02 3 -5 6 1000047 # BR(Glu_2 -> Fd_3^* Fu_3 Cha_3 )
1.41719142E-02 3 2 -2 1000022 # BR(Glu_2 -> Fu_1 Fu_1^* Chi_1 )
3.45488297E-02 3 2 -2 1000023 # BR(Glu_2 -> Fu_1 Fu_1^* Chi_2 )
6.59158304E-03 3 2 -2 1000025 # BR(Glu_2 -> Fu_1 Fu_1^* Chi_3 )
2.70550307E-02 3 2 -2 1000045 # BR(Glu_2 -> Fu_1 Fu_1^* Chi_5 )
2.13896573E-02 3 2 -2 1000055 # BR(Glu_2 -> Fu_1 Fu_1^* Chi_6 )
1.41765069E-02 3 4 -4 1000022 # BR(Glu_2 -> Fu_2 Fu_2^* Chi_1 )
3.45306128E-02 3 4 -4 1000023 # BR(Glu_2 -> Fu_2 Fu_2^* Chi_2 )
6.57327374E-03 3 4 -4 1000025 # BR(Glu_2 -> Fu_2 Fu_2^* Chi_3 )
2.69638753E-02 3 4 -4 1000045 # BR(Glu_2 -> Fu_2 Fu_2^* Chi_5 )
2.13128326E-02 3 4 -4 1000055 # BR(Glu_2 -> Fu_2 Fu_2^* Chi_6 )
1.08958792E-04 3 4 -6 1000025 # BR(Glu_2 -> Fu_2 Fu_3^* Chi_3 )
1.20056044E-04 3 4 -6 1000035 # BR(Glu_2 -> Fu_2 Fu_3^* Chi_4 )
1.08958792E-04 3 6 -4 1000025 # BR(Glu_2 -> Fu_3 Fu_2^* Chi_3 )
1.20056044E-04 3 6 -4 1000035 # BR(Glu_2 -> Fu_3 Fu_2^* Chi_4 )
8.70542313E-03 3 6 -6 1000022 # BR(Glu_2 -> Fu_3 Fu_3^* Chi_1 )
4.57738861E-03 3 6 -6 1000023 # BR(Glu_2 -> Fu_3 Fu_3^* Chi_2 )
1.22921385E-02 3 6 -6 1000025 # BR(Glu_2 -> Fu_3 Fu_3^* Chi_3 )
6.36396440E-02 3 6 -6 1000035 # BR(Glu_2 -> Fu_3 Fu_3^* Chi_4 )
2.70921504E-03 3 6 -6 1000045 # BR(Glu_2 -> Fu_3 Fu_3^* Chi_5 )
1.92368492E-03 3 6 -6 1000055 # BR(Glu_2 -> Fu_3 Fu_3^* Chi_6 )
DECAY 1000022 0.00000000E+00 # Chi_1
# BR NDA ID1 ID2
DECAY 1000023 1.01824186E-14 # Chi_2
# BR NDA ID1 ID2
# BR NDA ID1 ID2 ID3
# 2.02161507E-01 3 1000022 -1 1 # BR(Chi_2 -> Chi_1 Fd_1^* Fd_1 )
# 2.01119336E-01 3 1000022 -3 3 # BR(Chi_2 -> Chi_1 Fd_2^* Fd_2 )
# 2.40988599E-02 3 1000022 -11 11 # BR(Chi_2 -> Chi_1 Fe_1^* Fe_1 )
# 2.38587878E-02 3 1000022 -13 13 # BR(Chi_2 -> Chi_1 Fe_2^* Fe_2 )
# 2.00865464E-04 3 1000022 -15 15 # BR(Chi_2 -> Chi_1 Fe_3^* Fe_3 )
# 1.89489818E-01 3 1000022 -2 2 # BR(Chi_2 -> Chi_1 Fu_1^* Fu_1 )
# 6.48987546E-02 3 1000022 -4 4 # BR(Chi_2 -> Chi_1 Fu_2^* Fu_2 )
# 9.80567536E-02 3 1000022 -12 12 # BR(Chi_2 -> Chi_1 Fv_1^* Fv_1 )
# 9.80567537E-02 3 1000022 -14 14 # BR(Chi_2 -> Chi_1 Fv_2^* Fv_2 )
# 9.80567907E-02 3 1000022 -16 16 # BR(Chi_2 -> Chi_1 Fv_3^* Fv_3 )
5.00000000E-01 3 1000022 -11 11 # BR(Chi_2 -> Chi_1 Fe_1^* Fe_1 )
5.00000000E-01 3 1000022 -13 13 # BR(Chi_2 -> Chi_1 Fe_2^* Fe_2 )
DECAY 1000025 2.12473527E-01 # Chi_3
# BR NDA ID1 ID2
1.18121873E-01 2 1000022 25 # BR(Chi_3 -> Chi_1 hh_1 )
1.73635904E-01 2 1000023 25 # BR(Chi_3 -> Chi_2 hh_1 )
4.35969887E-01 2 1000022 23 # BR(Chi_3 -> Chi_1 VZ )
2.72272182E-01 2 1000023 23 # BR(Chi_3 -> Chi_2 VZ )
DECAY 1000035 2.86157711E-01 # Chi_4
# BR NDA ID1 ID2
4.90430759E-01 2 1000022 25 # BR(Chi_4 -> Chi_1 hh_1 )
1.41683140E-01 2 1000023 25 # BR(Chi_4 -> Chi_2 hh_1 )
2.02821184E-01 2 1000022 23 # BR(Chi_4 -> Chi_1 VZ )
1.65018975E-01 2 1000023 23 # BR(Chi_4 -> Chi_2 VZ )
DECAY 1000045 7.97556911E-02 # Chi_5
# BR NDA ID1 ID2
2.61092849E-01 2 1000024 24 # BR(Chi_5 -> Cha_1 VWm^* )
2.61092849E-01 2 -1000024 -24 # BR(Chi_5 -> Cha_1^* VWm )
1.11481764E-01 2 1000022 25 # BR(Chi_5 -> Chi_1 hh_1 )
3.23373320E-02 2 1000023 25 # BR(Chi_5 -> Chi_2 hh_1 )
3.22680004E-02 2 1000025 25 # BR(Chi_5 -> Chi_3 hh_1 )
2.65270011E-02 2 1000035 25 # BR(Chi_5 -> Chi_4 hh_1 )
5.51417142E-02 2 1000022 23 # BR(Chi_5 -> Chi_1 VZ )
3.07208896E-04 2 1000023 23 # BR(Chi_5 -> Chi_2 VZ )
4.74029453E-02 2 1000025 23 # BR(Chi_5 -> Chi_3 VZ )
1.72327165E-01 2 1000035 23 # BR(Chi_5 -> Chi_4 VZ )
DECAY 1000055 1.23215836E+00 # Chi_6
# BR NDA ID1 ID2
2.85066724E-01 2 1000024 24 # BR(Chi_6 -> Cha_1 VWm^* )
2.85066724E-01 2 -1000024 -24 # BR(Chi_6 -> Cha_1^* VWm )
2.55272900E-03 2 1000022 25 # BR(Chi_6 -> Chi_1 hh_1 )
7.30954316E-03 2 1000023 25 # BR(Chi_6 -> Chi_2 hh_1 )
2.08059399E-01 2 1000025 25 # BR(Chi_6 -> Chi_3 hh_1 )
3.12669926E-04 2 1000035 25 # BR(Chi_6 -> Chi_4 hh_1 )
6.00386902E-02 2 1000022 23 # BR(Chi_6 -> Chi_1 VZ )
2.04628916E-02 2 1000023 23 # BR(Chi_6 -> Chi_2 VZ )
3.16756468E-03 2 1000025 23 # BR(Chi_6 -> Chi_3 VZ )
1.27961528E-01 2 1000035 23 # BR(Chi_6 -> Chi_4 VZ )
DECAY 1000024 2.42129630E-01 # Cha_1
# BR NDA ID1 ID2
6.22794754E-01 2 1000022 -24 # BR(Cha_1 -> Chi_1 VWm )
3.77194439E-01 2 1000023 -24 # BR(Cha_1 -> Chi_2 VWm )
DECAY 1000037 1.46963935E-01 # Cha_2
# BR NDA ID1 ID2
3.92268114E-02 2 1000024 25 # BR(Cha_2 -> Cha_1 hh_1 )
1.23218064E-01 2 1000024 23 # BR(Cha_2 -> Cha_1 VZ )
1.94062865E-01 2 1000022 -24 # BR(Cha_2 -> Chi_1 VWm )
7.93482232E-03 2 1000023 -24 # BR(Cha_2 -> Chi_2 VWm )
3.71789024E-01 2 1000025 -24 # BR(Cha_2 -> Chi_3 VWm )
2.63411348E-01 2 1000035 -24 # BR(Cha_2 -> Chi_4 VWm )
# BR NDA ID1 ID2 ID3
3.34460855E-04 3 1000022 -6 5 # BR(Cha_2 -> Chi_1 Fu_3^* Fd_3 )
DECAY 1000047 1.19982610E+00 # Cha_3
# BR NDA ID1 ID2
2.08643885E-01 2 1000024 25 # BR(Cha_3 -> Cha_1 hh_1 )
2.59099379E-01 2 1000024 23 # BR(Cha_3 -> Cha_1 VZ )
5.18255122E-02 2 1000022 -24 # BR(Cha_3 -> Chi_1 VWm )
2.84172848E-02 2 1000023 -24 # BR(Cha_3 -> Chi_2 VWm )
2.93148260E-01 2 1000025 -24 # BR(Cha_3 -> Chi_3 VWm )
1.58726930E-01 2 1000035 -24 # BR(Cha_3 -> Chi_4 VWm )
# BR NDA ID1 ID2 ID3
1.03529903E-04 3 1000022 -6 5 # BR(Cha_3 -> Chi_1 Fu_3^* Fd_3 )
DECAY 2 0.00000000E+00 # Fu_1
# BR NDA ID1 ID2
DECAY 4 0.00000000E+00 # Fu_2
# BR NDA ID1 ID2
DECAY 6 1.61201460E+00 # Fu_3
# BR NDA ID1 ID2
1.67594663E-03 2 3 24 # BR(Fu_3 -> Fd_2 VWm^* )
9.98288615E-01 2 5 24 # BR(Fu_3 -> Fd_3 VWm^* )
DECAY 21 0.00000000E+00 # VG
DECAY 22 0.00000000E+00 # VP
DECAY 23 2.49520000E+00 # VZ
DECAY 24 2.14100000E+00 # VWm
DECAY 12 0.00000000E+00 # Fv_1
DECAY 14 0.00000000E+00 # Fv_2
DECAY 16 0.00000000E+00 # Fv_3
DECAY 11 0.00000000E+00 # Fe_1
DECAY 13 0.00000000E+00 # Fe_2
DECAY 15 0.00000000E+00 # Fe_3
DECAY 1 0.00000000E+00 # Fd_1
DECAY 3 0.00000000E+00 # Fd_2
DECAY 5 0.00000000E+00 # Fd_3
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<MGGenerationInfo>
# Number of Events : 100
# Integrated weight (pb) : 2.01629545539e-05
</MGGenerationInfo>
<MGPythiaCard>
<![CDATA[
!
! It is possible to run this card manually with:
! LD_LIBRARY_
!
!
! Pythia8 cmd card automatically generated by MadGraph5_aMC@NLO
! For more information on the use of the MG5aMC / Pythia8 interface, visit
! https:/
!
! ==================
! General parameters
! ==================
!
Main:numberOfEvents = -1
!
! -------
! Specify the HEPMC output of the Pythia8 shower. You can set it to:
! auto : MG5aMC will automatically place it the run_<i> directory
! /dev/null : to turn off the HEPMC output.
! <path> : to select where the HEPMC file must written. It will
! therefore not be placed in the run_<i> directory. The
! specified path, if not absolute, will be relative to
! the Event/run_<i> directory of the process output.
! fifo : to have MG5aMC setup the piping of the PY8 output to
! analysis tools such as MadAnalysis5.
! fifo@<fifo_path> :
! Same as 'fifo', but selecting a custom path to create the
! fifo pipe. (useful to select a mounted drive that supports
! fifo). Note that the fifo file extension *must* be '.hepmc.fifo'.
! -------
!
HEPMCoutput:file = tag_1_pythia8_
!
! -------
! Parameters relevant only when performing MLM merging, which can be
! turned on by setting ickkw to '1' in the run_card and chosing a
! positive value for the parameter xqcut.
! For details, see section 'Jet Matching' on the left-hand menu of
! http://
! -------
! If equal to -1.0, MadGraph5_aMC@NLO will set it automatically based
! on the parameter 'xqcut' of the run_card.dat
! The following parameter was forced to be commented out by MG5aMC.
! JetMatching:qCut = -1.0
! Use default kt-MLM to match parton level jets to those produced by the
! shower. But the other Shower-kt scheme is available too with this option.
! The following parameter was forced to be commented out by MG5aMC.
! JetMatching:
! A value of -1 means that it is automatically guessed by MadGraph.
! It is however always safer to explicitly set it.
! The following parameter was forced to be commented out by MG5aMC.
! JetMatching:nJetMax = -1
!
! -------
! Parameters relevant only when performing CKKW-L merging, which can
! be turned on by setting the parameter 'ptlund' *or* 'ktdurham' to
! a positive value.
! For details, see section 'CKKW-L Merging' on the left-hand menu of
! http://
! -------
! Central merging scale values you want to be used.
! If equal to -1.0, then MadGraph5_aMC@NLO will set this automatically
! based on the parameter 'ktdurham' of the run_card.dat
! The following parameter was forced to be commented out by MG5aMC.
! Merging:TMS = -1.0
! This must be set manually, according to Pythia8 directives.
! An example of possible value is 'pp>LEPTONS,
! Alternatively, from Pythia v8.223 onwards, the value 'guess' can be
! used to instruct Pythia to guess the hard process. The guess would mean
! that all particles apart from light partons will be considered as a part
! of the hard process. This guess is prone to errors if the desired hard
! process is complicated (i.e. contains light partons). The user should
! then be wary of suspicious error messages in the Pythia log file.
! The following parameter was forced to be commented out by MG5aMC.
! Merging:Process = <set_by_user>
! A value of -1 means that it is automatically guessed by MadGraph.
! It is however always safer to explicitly set it.
! The following parameter was forced to be commented out by MG5aMC.
! Merging:nJetMax = -1
!
! For all merging schemes, decide whehter you want the merging scale
! variation computed for only the central weights or all other
! PDF and scale variation weights as well
SysCalc:
!
! =======
! User customized parameters
! =======
!
! By default, Pythia8 generates multi-parton interaction events. This is
! often irrelevant for phenomenology and very slow. You can turn this
! feature off by uncommenting the line below if so desired.
!partonlevel:mpi = off
!
! Additional general parameters.
!
#1000023:
#1000023:
#1000023:tau0=70.
##1000023:
SUSY:all=off
##SUSYResonance
!
! Additional technical parameters set by MG5_aMC.
!
! Tell Pythia8 that an LHEF input is used.
Beams:frameType=4
! Specify one must read inputs from the MadGraph banner.
JetMatching:
JetMatching:
! 1.0 corresponds to HEPMC weight given in [mb]. We choose here the [pb] normalization.
HEPMCoutput:
! Be more forgiving with momentum mismatches.
Check:epTolErr=
!
! =======
! Subrun definitions
! =======
!
LHEFInputs:
Main:subrun=0
!
! Definition of subrun 0
!
Beams:LHEF=
]]>
</MGPythiaCard>
<madspin>
<![CDATA[
#******
#* MadSpin *
#* *
#* P. Artoisenet, R. Frederix, R. Rietkerk, O. Mattelaer *
#* *
#* Part of the MadGraph5_aMC@NLO Framework: *
#* The MadGraph5_aMC@NLO Development Team - Find us at *
#* https:/
#* *
#* Manual: *
#* cp3.irmp.
#* *
#******
#Some options (uncomment to apply)
#
# set seed 1
# set Nevents_
# set BW_cut 15 # cut on how far the particle can be off-shell
set spinmode none # Use one of the madspin special mode
set max_weight_ps_point 400 # number of PS to estimate the maximum for each event
# specify the decay for the final state particles
decay n2 > l+ l- n1
# running the actual code
launch
]]>
</madspin>
</header>
<init>
2212 2212 6.500000e+03 6.500000e+03 0 0 260000 260000 -4 1
+2.7444131e-08 +4.8796094e-10 +2.7454802e-08 1
<generator name='MadGraph5
</init>
</LesHouchesEvents>
|
Revision history for this message
|
#4 |
Hi,
You can try to remove the line:
# in case of problems send email to <email address hidden>
from your original param_card, this is the presence of the "@" in your card which forces the presence of the ]]> symbol since the "@" creates issue for some xml parser.
So removing that line should solves your problem.
By adding such line in my param_card and changing some other formatting choices,
I successfully succeed to reproduce the error. So you will find below a patch:
(be carefull indentation is important and is typically not preserve...)
Cheers,
Olivier
=== modified file 'models/
--- models/
+++ models/
@@ -93,6 +93,9 @@
data, self.comment = text.split('#',1)
else:
data, self.comment = text, ""
+
+ if ']]>' in data:
+ data = data.split(
data = data.split()
On 12 Mar 2019, at 21:17, Jack Y. Araz <<email address hidden>
Question #679135 on MadGraph5_aMC@NLO changed:
https:/
Status: Answered => Open
Jack Y. Araz is still having a problem:
Hi Oliver
Thanks for the quick response
Now the problem seems to be a problem with your param_card format.
Difficult to know more without seeing the file but my guess is that you are missing a return line at the end of the file (or something >like that). Can you copy the banner of the event file here? (or just the part of the param_card?
I'm adding the banner below and as you said there is ']]>' right before
</slha> but I don't see it anywhere in the param card.
Concerning your modification, it is quite dangerous and can lead to
bias in general.
Thanks, I'm changing it back to normal
Best regards
Jack
banner:
<LesHouchesEvents version="3.0">
<header>
<!--
#******
# *
# MadGraph5_aMC@NLO *
# *
# Going Beyond *
# *
# http://
# http://
# http://
# *
# The MadGraph5_aMC@NLO team *
# *
#......
# *
# This file contains all the information necessary to reproduce *
# the events generated: *
# *
# 1. software version *
# 2. proc_card : code generation info including model *
# 3. param_card : model primary parameters in the LH format *
# 4. run_card : running parameters (collider and cuts) *
# 5. pythia_card : present only if pythia has been run *
# 6. pgs_card : present only if pgs has been run *
# 7. delphes_cards : present only if delphes has been run *
# *
# *
#******
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<MGVersion>
3.0.1
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<MG5ProcCard>
<![CDATA[
#******
#* MadGraph5_aMC@NLO *
#* *
#* * * *
#* * * * * *
#* * * * * 5 * * * * *
#* * * * * *
#* * * *
#* *
#* *
#* VERSION 3.0.1 2018-12-20 *
#* *
#* The MadGraph5_aMC@NLO Development Team - Find us at *
#* https:/
#* *
#******
#* *
#* Command File for MadGraph5_aMC@NLO *
#* *
#* run as ./bin/mg5_aMC filename *
#* *
#******
set default_
set group_subprocesses Auto
set ignore_
set loop_optimized_
set include_
set loop_color_flows False
set gauge unitary
set complex_mass_scheme False
set max_npoint_
import model sm
define p = g u c d s u~ c~ d~ s~
define j = g u c d s u~ c~ d~ s~
define l+ = e+ mu+
define l- = e- mu-
define vl = ve vm vt
define vl~ = ve~ vm~ vt~
import model DiracGaugino_UFO --modelname
generate p p > n2 n2
output n2Prod_py8decay
]]>
</MG5ProcCard>
<MGProcCard>
#******
# MadGraph/MadEvent *
# http://
# *
# proc_card.dat *
#******
# *
# This Files is generated by MADGRAPH 5 *
# *
# WARNING: This Files is generated for MADEVENT (compatibility issue)*
# This files is NOT a valid MG4 proc_card.dat *
# Running this in MG4 will NEVER reproduce the result of MG5*
# *
#******
#******
# Process(es) requested : mg2 input *
#******
# Begin PROCESS # This is TAG. Do not modify this line
p p > n2 n2 #Process
# Be carefull the coupling are here in MG5 convention
end_coup # End the couplings input
done # this tells MG there are no more procs
# End PROCESS # This is TAG. Do not modify this line
#******
# Model information *
#******
# Begin MODEL # This is TAG. Do not modify this line
DiracGaugino_UFO
# End MODEL # This is TAG. Do not modify this line
#******
# Start multiparticle definitions *
#******
# Begin MULTIPARTICLES # This is TAG. Do not modify this line
# End MULTIPARTICLES # This is TAG. Do not modify this line
</MGProcCard>
<MGRunCard>
<![CDATA[
#******
# MadGraph5_aMC@NLO *
# *
# run_card.dat MadEvent *
# *
# This file is used to set the parameters of the run. *
# *
# Some notation/
# *
# Lines starting with a '# ' are info or comments *
# *
# mind the format: value = variable ! comment *
# *
# To display more options, you can type the command: *
# update full_run_card *
#******
#
#******
# Running parameters
#******
#
#******
# Tag name for the run (one word) *
#******
tag_1 = run_tag ! name of the run
#******
# Number of events and rnd seed *
# Warning: Do not generate more than 1M events in a single run *
# If you want to run Pythia, avoid more than 50k events in a run. *
#******
100 = nevents ! Number of unweighted events requested
123 = iseed ! rnd seed (0=assigned automatically=
#******
# Collider type and energy *
# lpp: 0=No PDF, 1=proton, -1=antiproton, 2=photon from proton, *
# 3=photon from electron *
#******
1 = lpp1 ! beam 1 type
1 = lpp2 ! beam 2 type
6500.0 = ebeam1 ! beam 1 total energy in GeV
6500.0 = ebeam2 ! beam 2 total energy in GeV
# To see polarised beam options: type "update beam_pol"
#******
# PDF CHOICE: this automatically fixes also alpha_s and its evol. *
#******
lhapdf = pdlabel ! PDF set
260000 = lhaid ! if pdlabel=lhapdf, this is the lhapdf number
# To see heavy ion options: type "update ion_pdf"
#******
# Renormalization and factorization scales *
#******
False = fixed_ren_scale ! if .true. use fixed ren scale
False = fixed_fac_scale ! if .true. use fixed fac scale
91.188 = scale ! fixed ren scale
91.188 = dsqrt_q2fact1 ! fixed fact scale for pdf1
91.188 = dsqrt_q2fact2 ! fixed fact scale for pdf2
-1 = dynamical_
1.0 = scalefact ! scale factor for event-by-event scales
#******
# Type and output format
#******
False = gridpack !True = setting up the grid pack
0.0 = time_of_flight ! threshold (in mm) below which the invariant livetime is not written (-1 means not written)
3.0 = lhe_version ! Change the way clustering information pass to shower.
True = clusinfo ! include clustering tag in output
average = event_norm ! average/sum. Normalization of the weight in the LHEF
#******
# Matching parameter (MLM only)
#******
0 = ickkw ! 0 no matching, 1 MLM
1.0 = alpsfact ! scale factor for QCD emission vx
False = chcluster ! cluster only according to channel diag
4 = asrwgtflavor ! highest quark flavor for a_s reweight
False = auto_ptj_mjj ! Automatic setting of ptj and mjj if xqcut >0
0.0 = xqcut ! minimum kt jet measure between partons
#******
#
#******
# handling of the helicities:
# 0: sum over all helicities
# 1: importance sampling over helicities
#******
0 = nhel ! using helicities importance sampling or not.
#******
# Generation bias, check the wiki page below for more information: *
# 'cp3.irmp.
#******
None = bias_module ! Bias type of bias, [None, ptj_bias, -custom_folder-]
{} = bias_parameters ! Specifies the parameters of the module.
#
#******
# Parton level cuts definition *
#******
#
#
#******
# BW cutoff (M+/-bwcutoff*
#******
15.0 = bwcutoff ! (M+/-bwcutoff*
#******
# Apply pt/E/eta/
# (note that etmiss/
#******
False = cut_decays ! Cut decay products
#******
# Standard Cuts *
#******
# Minimum and maximum pt's (for max, -1 means no cut) *
#******
20.0 = ptj ! minimum pt for the jets
0.0 = ptb ! minimum pt for the b
10.0 = pta ! minimum pt for the photons
10.0 = ptl ! minimum pt for the charged leptons
0.0 = misset ! minimum missing Et (sum of neutrino's momenta)
-1.0 = ptjmax ! maximum pt for the jets
-1.0 = ptbmax ! maximum pt for the b
-1.0 = ptamax ! maximum pt for the photons
-1.0 = ptlmax ! maximum pt for the charged leptons
-1.0 = missetmax ! maximum missing Et (sum of neutrino's momenta)
{} = pt_min_pdg ! pt cut for other particles (use pdg code). Applied on particle and anti-particle
{} = pt_max_pdg ! pt cut for other particles (syntax e.g. {6: 100, 25: 50})
#******
# Minimum and maximum E's (in the center of mass frame) *
#******
0.0 = ej ! minimum E for the jets
0.0 = eb ! minimum E for the b
0.0 = ea ! minimum E for the photons
0.0 = el ! minimum E for the charged leptons
-1.0 = ejmax ! maximum E for the jets
-1.0 = ebmax ! maximum E for the b
-1.0 = eamax ! maximum E for the photons
-1.0 = elmax ! maximum E for the charged leptons
{} = e_min_pdg ! E cut for other particles (use pdg code). Applied on particle and anti-particle
{} = e_max_pdg ! E cut for other particles (syntax e.g. {6: 100, 25: 50})
#******
# Maximum and minimum absolute rapidity (for max, -1 means no cut) *
#******
5.0 = etaj ! max rap for the jets
-1.0 = etab ! max rap for the b
2.5 = etaa ! max rap for the photons
2.5 = etal ! max rap for the charged leptons
0.0 = etajmin ! min rap for the jets
0.0 = etabmin ! min rap for the b
0.0 = etaamin ! min rap for the photons
0.0 = etalmin ! main rap for the charged leptons
{} = eta_min_pdg ! rap cut for other particles (use pdg code). Applied on particle and anti-particle
{} = eta_max_pdg ! rap cut for other particles (syntax e.g. {6: 2.5, 23: 5})
#******
# Minimum and maximum DeltaR distance *
#******
0.4 = drjj ! min distance between jets
0.0 = drbb ! min distance between b's
0.4 = drll ! min distance between leptons
0.4 = draa ! min distance between gammas
0.0 = drbj ! min distance between b and jet
0.4 = draj ! min distance between gamma and jet
0.4 = drjl ! min distance between jet and lepton
0.0 = drab ! min distance between gamma and b
0.0 = drbl ! min distance between b and lepton
0.4 = dral ! min distance between gamma and lepton
-1.0 = drjjmax ! max distance between jets
-1.0 = drbbmax ! max distance between b's
-1.0 = drllmax ! max distance between leptons
-1.0 = draamax ! max distance between gammas
-1.0 = drbjmax ! max distance between b and jet
-1.0 = drajmax ! max distance between gamma and jet
-1.0 = drjlmax ! max distance between jet and lepton
-1.0 = drabmax ! max distance between gamma and b
-1.0 = drblmax ! max distance between b and lepton
-1.0 = dralmax ! maxdistance between gamma and lepton
#******
# Minimum and maximum invariant mass for pairs *
# WARNING: for four lepton final state mmll cut require to have *
# different lepton masses for each flavor! *
#******
0.0 = mmjj ! min invariant mass of a jet pair
0.0 = mmbb ! min invariant mass of a b pair
0.0 = mmaa ! min invariant mass of gamma gamma pair
0.0 = mmll ! min invariant mass of l+l- (same flavour) lepton pair
-1.0 = mmjjmax ! max invariant mass of a jet pair
-1.0 = mmbbmax ! max invariant mass of a b pair
-1.0 = mmaamax ! max invariant mass of gamma gamma pair
-1.0 = mmllmax ! max invariant mass of l+l- (same flavour) lepton pair
{} = mxx_min_pdg ! min invariant mass of a pair of particles X/X~ (e.g. {6:250})
{'default': False} = mxx_only_
#******
# Minimum and maximum invariant mass for all letpons *
#******
0.0 = mmnl ! min invariant mass for all letpons (l+- and vl)
-1.0 = mmnlmax ! max invariant mass for all letpons (l+- and vl)
#******
# Minimum and maximum pt for 4-momenta sum of leptons *
#******
0.0 = ptllmin ! Minimum pt for 4-momenta sum of leptons(l and vl)
-1.0 = ptllmax ! Maximum pt for 4-momenta sum of leptons(l and vl)
#******
# Inclusive cuts *
#******
0.0 = ptheavy ! minimum pt for at least one heavy final state
0.0 = xptj ! minimum pt for at least one jet
0.0 = xptb ! minimum pt for at least one b
0.0 = xpta ! minimum pt for at least one photon
0.0 = xptl ! minimum pt for at least one charged lepton
#******
# Control the pt's of the jets sorted by pt *
#******
0.0 = ptj1min ! minimum pt for the leading jet in pt
0.0 = ptj2min ! minimum pt for the second jet in pt
0.0 = ptj3min ! minimum pt for the third jet in pt
0.0 = ptj4min ! minimum pt for the fourth jet in pt
-1.0 = ptj1max ! maximum pt for the leading jet in pt
-1.0 = ptj2max ! maximum pt for the second jet in pt
-1.0 = ptj3max ! maximum pt for the third jet in pt
-1.0 = ptj4max ! maximum pt for the fourth jet in pt
0 = cutuse ! reject event if fails any (0) / all (1) jet pt cuts
#******
# Control the pt's of leptons sorted by pt *
#******
0.0 = ptl1min ! minimum pt for the leading lepton in pt
0.0 = ptl2min ! minimum pt for the second lepton in pt
0.0 = ptl3min ! minimum pt for the third lepton in pt
0.0 = ptl4min ! minimum pt for the fourth lepton in pt
-1.0 = ptl1max ! maximum pt for the leading lepton in pt
-1.0 = ptl2max ! maximum pt for the second lepton in pt
-1.0 = ptl3max ! maximum pt for the third lepton in pt
-1.0 = ptl4max ! maximum pt for the fourth lepton in pt
#******
# Control the Ht(k)=Sum of k leading jets *
#******
0.0 = htjmin ! minimum jet HT=Sum(jet pt)
-1.0 = htjmax ! maximum jet HT=Sum(jet pt)
0.0 = ihtmin !inclusive Ht for all partons (including b)
-1.0 = ihtmax !inclusive Ht for all partons (including b)
0.0 = ht2min ! minimum Ht for the two leading jets
0.0 = ht3min ! minimum Ht for the three leading jets
0.0 = ht4min ! minimum Ht for the four leading jets
-1.0 = ht2max ! maximum Ht for the two leading jets
-1.0 = ht3max ! maximum Ht for the three leading jets
-1.0 = ht4max ! maximum Ht for the four leading jets
#******
# Photon-isolation cuts, according to hep-ph/9801442 *
# When ptgmin=0, all the other parameters are ignored *
# When ptgmin>0, pta and draj are not going to be used *
#******
0.0 = ptgmin ! Min photon transverse momentum
0.4 = R0gamma ! Radius of isolation code
1.0 = xn ! n parameter of eq.(3.4) in hep-ph/9801442
1.0 = epsgamma ! epsilon_gamma parameter of eq.(3.4) in hep-ph/9801442
True = isoEM ! isolate photons from EM energy (photons and leptons)
#******
# WBF cuts *
#******
0.0 = xetamin ! minimum rapidity for two jets in the WBF case
0.0 = deltaeta ! minimum rapidity for two jets in the WBF case
#******
# Turn on either the ktdurham or ptlund cut to activate *
# CKKW(L) merging with Pythia8 [arXiv:1410.3012, arXiv:1109.4829] *
#******
-1.0 = ktdurham
0.4 = dparameter
-1.0 = ptlund
1, 2, 3, 4, 5, 6, 21, 1000001, 1000002, 1000003, 1000004, 1000005, 1000006, 1000021, 2000001, 2000002, 2000003, 2000004, 2000005, 2000006, 2000021, 3000021, 3000022 = pdgs_for_
#******
# maximal pdg code for quark to be considered as a light jet *
# (otherwise b cuts are applied) *
#******
4 = maxjetflavor ! Maximum jet pdg code
#******
#
#******
# Store info for systematics studies *
# WARNING: Do not use for interference type of computation *
#******
True = use_syst ! Enable systematics studies
#
systematics = systematics_program ! none, systematics [python], SysCalc [depreceted, C++]
['--mur=0.5,1,2', '--muf=0.5,1,2', '--pdf=errorset'] = systematics_
# Syscalc is deprecated but to see the associate options type'update syscalc'
]]>
</MGRunCard>
<slha>
<![CDATA[
# SUSY Les Houches Accord 2 - DiracGauginos Spectrum + Decays + Flavor Observables
# SPheno module generated by SARAH
# -------
# SPheno v4.0.3
# W. Porod, Comput. Phys. Commun. 153 (2003) 275-315, hep-ph/0301101
# W. Porod, F.Staub, Comput.
# SARAH: SARAHVER
# F. Staub; arXiv:0806.0538 (online manual)
# F. Staub; Comput. Phys. Commun. 181 (2010) 1077-1086; arXiv:0909.2863
# F. Staub; Comput. Phys. Commun. 182 (2011) 808-833; arXiv:1002.0840
# F. Staub; Comput. Phys. Commun. 184 (2013) 1792-1809; arXiv:1207.0906
# F. Staub; Comput. Phys. Commun. 185 (2014) 1773-1790; arXiv:1309.7223
# Including the calculation of flavor observables based on the FlavorKit
# W. Porod, F. Staub, A. Vicente; Eur.Phys.J. C74 (2014) 8, 2992; arXiv:1405.1434
# Two-loop masss corrections to Higgs fields based on
# M. D. Goodsell, K. Nickel, F. Staub; Eur.Phys.J. C75 (2015) no.6, 290; arXiv:1411.0675
# M. D. Goodsell, K. Nickel, F. Staub; Eur.Phys.J. C75 (2015) no.1, 32; arXiv:1503.03098
# M. D. Goodsell, F. Staub; arXiv:1511.01904
#
# in case of problems send email to <email address hidden> and <email address hidden>
# -------
# Created: 01.03.2019, 11:22
Block SPINFO # Program information
1 SPhenoSARAH # spectrum calculator
2 v4.0.3 # version number of SPheno
9 SARAHVER # version number of SARAH
BLOCK QNUMBERS 1000055 # N6
1 0 # 3 times electric charge
2 2 # (2S + 1)
3 1 # colour rep
4 0 # particle/
BLOCK QNUMBERS 1000047 # C3 C3bar
1 -3 #
2 2 #
3 1 #
4 1 #
BLOCK QNUMBERS 2000021 # go2
1 0 # 3 times electric charge
2 2 # (2S + 1)
3 8 # colour rep
4 0 # particle/
BLOCK QNUMBERS 3000022 # SOc
1 0 # 3 times electric charge
2 1 # (2S + 1)
3 8 # colour rep
4 0 # particle/
BLOCK QNUMBERS 3000021 # POc
1 0 # 3 times electric charge
2 1 # (2S + 1)
3 8 # colour rep
4 0 # particle/
BLOCK QNUMBERS 55 # h4
1 0 # 3 times electric charge
2 1 # (2S + 1)
3 1 # colour rep
4 0 # particle/
BLOCK QNUMBERS 56 # Ah4
1 0 # 3 times electric charge
2 1 # (2S + 1)
3 1 # colour rep
4 0 # particle/
BLOCK QNUMBERS 47 # Hm3c Hm3
1 3 # 3 times electric charge
2 1 # (2S + 1)
3 1 # colour rep
4 1 # particle/
BLOCK QNUMBERS 57 # Hm4c Hm4
1 3 # 3 times electric charge
2 1 # (2S + 1)
3 1 # colour rep
4 1 # particle/
Block MODSEL # Input parameters
1 0 # SUSY Scale input
2 1 # Boundary conditions
6 1 # switching on flavour violation
Block MINPAR # Input parameters
1 0.00000000E+00 # mSUSY
3 2.00000000E+00 # TanBeta
Block gaugeGUT Q= 1.50000000E+03 # (GUT scale)
1 4.68331188E-01 # g1(Q)^DRbar
2 6.41764836E-01 # g2(Q)^DRbar
3 1.02353455E+00 # g3(Q)^DRbar
Block SMINPUTS # SM parameters
1 1.27932000E+02 # alpha_em^
2 1.16637000E-05 # G_mu [GeV^-2]
3 1.18700000E-01 # alpha_s(MZ)^MSbar
4 9.11887000E+01 # m_Z(pole)
5 4.18000000E+00 # m_b(m_b), MSbar
6 1.73500000E+02 # m_t(pole)
7 1.77669000E+00 # m_tau(pole)
Block GAUGE Q= 1.50000000E+03 # (SUSY Scale)
1 3.62767778E-01 # g1
2 6.41764836E-01 # g2
3 1.02353455E+00 # g3
Block HMIX Q= 1.50000000E+03 # (SUSY Scale)
350 1.40000000E-01 # LT
34 0.00000000E+00 # LS
1 4.00000000E+02 # Mu
45 0.00000000E+00 # MO
31 0.00000000E+00 # MS
35 0.00000000E+00 # MTR
351 0.00000000E+00 # TLT
36 0.00000000E+00 # TLS
101 2.90000000E+06 # Bmu
46 0.00000000E+00 # BO
33 -1.00000000E+06 # BMS
37 1.00000000E+06 # BMT
32 -2.08528779E+06 # LL1
30 0.00000000E+00 # L1
310 1.16800000E+00 # vT
102 1.08450676E+02 # vd
103 2.16901353E+02 # vu
310 1.16800000E+00 # vT
3 2.42503084E+02 # v
10 1.10705747E+00 # betaH
Block IMHMIX Q= 1.50000000E+03 # (SUSY Scale)
350 0.00000000E+00 # LT
34 0.00000000E+00 # LS
1 0.00000000E+00 # Mu
45 0.00000000E+00 # MO
31 0.00000000E+00 # MS
35 0.00000000E+00 # MTR
351 0.00000000E+00 # TLT
36 0.00000000E+00 # TLS
101 0.00000000E+00 # Bmu
46 0.00000000E+00 # BO
33 0.00000000E+00 # BMS
37 0.00000000E+00 # BMT
32 0.00000000E+00 # LL1
30 0.00000000E+00 # L1
Block NMSSMRUN Q= 1.50000000E+03 # (SUSY Scale)
1 3.35000000E-01 # lam
2 -3.00000000E-01 # kap
3 0.00000000E+00 # Tlam
4 0.00000000E+00 # Tk
10 8.71031466E+06 # ms2
5 9.20100000E-01 # vS
5 9.20100000E-01 # vS
Block IMNMSSMRUN Q= 1.50000000E+03 # (SUSY Scale)
1 0.00000000E+00 # lam
2 0.00000000E+00 # kap
3 0.00000000E+00 # Tlam
4 0.00000000E+00 # Tk
Block MSOFT Q= 1.50000000E+03 # (SUSY Scale)
21 5.63932757E+06 # mHd2
22 1.28730240E+06 # mHu2
110 1.43754732E+06 # mt2
111 2.25004601E+06 # mo2
1 0.00000000E+00 # M1
2 0.00000000E+00 # M2
3 0.00000000E+00 # M3
300 2.00000000E+02 # MDB
301 5.00000000E+02 # MDW
302 1.75000000E+03 # MDO
Block IMMSOFT Q= 1.50000000E+03 # (SUSY Scale)
1 0.00000000E+00 # M1
2 0.00000000E+00 # M2
3 0.00000000E+00 # M3
300 0.00000000E+00 # MDB
301 0.00000000E+00 # MDW
302 0.00000000E+00 # MDO
Block Yd Q= 1.50000000E+03 # (SUSY Scale)
1 1 3.04917106E-05 # Real(Yd(1,1),dp)
1 2 1.93632489E-11 # Real(Yd(1,2),dp)
1 3 -4.63469474E-10 # Real(Yd(1,3),dp)
2 1 3.67888991E-10 # Real(Yd(2,1),dp)
2 2 5.79320003E-04 # Real(Yd(2,2),dp)
2 3 6.07218576E-08 # Real(Yd(2,3),dp)
3 1 -4.53070301E-07 # Real(Yd(3,1),dp)
3 2 3.12428739E-06 # Real(Yd(3,2),dp)
3 3 2.95022192E-02 # Real(Yd(3,3),dp)
Block IMYd Q= 1.50000000E+03 # (SUSY Scale)
1 1 0.00000000E+00 # Aimag(Yd(1,1))
1 2 0.00000000E+00 # Aimag(Yd(1,2))
1 3 0.00000000E+00 # Aimag(Yd(1,3))
2 1 0.00000000E+00 # Aimag(Yd(2,1))
2 2 0.00000000E+00 # Aimag(Yd(2,2))
2 3 0.00000000E+00 # Aimag(Yd(2,3))
3 1 0.00000000E+00 # Aimag(Yd(3,1))
3 2 0.00000000E+00 # Aimag(Yd(3,2))
3 3 0.00000000E+00 # Aimag(Yd(3,3))
Block Ye Q= 1.50000000E+03 # (SUSY Scale)
1 1 6.54148017E-06 # Real(Ye(1,1),dp)
1 2 0.00000000E+00 # Real(Ye(1,2),dp)
1 3 0.00000000E+00 # Real(Ye(1,3),dp)
2 1 0.00000000E+00 # Real(Ye(2,1),dp)
2 2 1.35257062E-03 # Real(Ye(2,2),dp)
2 3 0.00000000E+00 # Real(Ye(2,3),dp)
3 1 0.00000000E+00 # Real(Ye(3,1),dp)
3 2 0.00000000E+00 # Real(Ye(3,2),dp)
3 3 2.27440507E-02 # Real(Ye(3,3),dp)
Block IMYe Q= 1.50000000E+03 # (SUSY Scale)
1 1 0.00000000E+00 # Aimag(Ye(1,1))
1 2 0.00000000E+00 # Aimag(Ye(1,2))
1 3 0.00000000E+00 # Aimag(Ye(1,3))
2 1 0.00000000E+00 # Aimag(Ye(2,1))
2 2 0.00000000E+00 # Aimag(Ye(2,2))
2 3 0.00000000E+00 # Aimag(Ye(2,3))
3 1 0.00000000E+00 # Aimag(Ye(3,1))
3 2 0.00000000E+00 # Aimag(Ye(3,2))
3 3 0.00000000E+00 # Aimag(Ye(3,3))
Block Yu Q= 1.50000000E+03 # (SUSY Scale)
1 1 7.38619768E-06 # Real(Yu(1,1),dp)
1 2 1.71231698E-06 # Real(Yu(1,2),dp)
1 3 2.64500086E-08 # Real(Yu(1,3),dp)
2 1 -8.55906333E-04 # Real(Yu(2,1),dp)
2 2 3.68957704E-03 # Real(Yu(2,2),dp)
2 3 1.57318790E-04 # Real(Yu(2,3),dp)
3 1 5.54601646E-03 # Real(Yu(3,1),dp)
3 2 -3.82440564E-02 # Real(Yu(3,2),dp)
3 3 9.23906555E-01 # Real(Yu(3,3),dp)
Block IMYu Q= 1.50000000E+03 # (SUSY Scale)
1 1 0.00000000E+00 # Aimag(Yu(1,1))
1 2 0.00000000E+00 # Aimag(Yu(1,2))
1 3 0.00000000E+00 # Aimag(Yu(1,3))
2 1 0.00000000E+00 # Aimag(Yu(2,1))
2 2 0.00000000E+00 # Aimag(Yu(2,2))
2 3 0.00000000E+00 # Aimag(Yu(2,3))
3 1 0.00000000E+00 # Aimag(Yu(3,1))
3 2 0.00000000E+00 # Aimag(Yu(3,2))
3 3 0.00000000E+00 # Aimag(Yu(3,3))
Block Td Q= 1.50000000E+03 # (SUSY Scale)
1 1 0.00000000E+00 # Real(Td(1,1),dp)
1 2 0.00000000E+00 # Real(Td(1,2),dp)
1 3 0.00000000E+00 # Real(Td(1,3),dp)
2 1 0.00000000E+00 # Real(Td(2,1),dp)
2 2 0.00000000E+00 # Real(Td(2,2),dp)
2 3 0.00000000E+00 # Real(Td(2,3),dp)
3 1 0.00000000E+00 # Real(Td(3,1),dp)
3 2 0.00000000E+00 # Real(Td(3,2),dp)
3 3 0.00000000E+00 # Real(Td(3,3),dp)
Block IMTd Q= 1.50000000E+03 # (SUSY Scale)
1 1 0.00000000E+00 # Aimag(Td(1,1))
1 2 0.00000000E+00 # Aimag(Td(1,2))
1 3 0.00000000E+00 # Aimag(Td(1,3))
2 1 0.00000000E+00 # Aimag(Td(2,1))
2 2 0.00000000E+00 # Aimag(Td(2,2))
2 3 0.00000000E+00 # Aimag(Td(2,3))
3 1 0.00000000E+00 # Aimag(Td(3,1))
3 2 0.00000000E+00 # Aimag(Td(3,2))
3 3 0.00000000E+00 # Aimag(Td(3,3))
Block Te Q= 1.50000000E+03 # (SUSY Scale)
1 1 0.00000000E+00 # Real(Te(1,1),dp)
1 2 0.00000000E+00 # Real(Te(1,2),dp)
1 3 0.00000000E+00 # Real(Te(1,3),dp)
2 1 0.00000000E+00 # Real(Te(2,1),dp)
2 2 0.00000000E+00 # Real(Te(2,2),dp)
2 3 0.00000000E+00 # Real(Te(2,3),dp)
3 1 0.00000000E+00 # Real(Te(3,1),dp)
3 2 0.00000000E+00 # Real(Te(3,2),dp)
3 3 0.00000000E+00 # Real(Te(3,3),dp)
Block IMTe Q= 1.50000000E+03 # (SUSY Scale)
1 1 0.00000000E+00 # Aimag(Te(1,1))
1 2 0.00000000E+00 # Aimag(Te(1,2))
1 3 0.00000000E+00 # Aimag(Te(1,3))
2 1 0.00000000E+00 # Aimag(Te(2,1))
2 2 0.00000000E+00 # Aimag(Te(2,2))
2 3 0.00000000E+00 # Aimag(Te(2,3))
3 1 0.00000000E+00 # Aimag(Te(3,1))
3 2 0.00000000E+00 # Aimag(Te(3,2))
3 3 0.00000000E+00 # Aimag(Te(3,3))
Block Tu Q= 1.50000000E+03 # (SUSY Scale)
1 1 0.00000000E+00 # Real(Tu(1,1),dp)
1 2 0.00000000E+00 # Real(Tu(1,2),dp)
1 3 0.00000000E+00 # Real(Tu(1,3),dp)
2 1 0.00000000E+00 # Real(Tu(2,1),dp)
2 2 0.00000000E+00 # Real(Tu(2,2),dp)
2 3 0.00000000E+00 # Real(Tu(2,3),dp)
3 1 0.00000000E+00 # Real(Tu(3,1),dp)
3 2 0.00000000E+00 # Real(Tu(3,2),dp)
3 3 0.00000000E+00 # Real(Tu(3,3),dp)
Block IMTu Q= 1.50000000E+03 # (SUSY Scale)
1 1 0.00000000E+00 # Aimag(Tu(1,1))
1 2 0.00000000E+00 # Aimag(Tu(1,2))
1 3 0.00000000E+00 # Aimag(Tu(1,3))
2 1 0.00000000E+00 # Aimag(Tu(2,1))
2 2 0.00000000E+00 # Aimag(Tu(2,2))
2 3 0.00000000E+00 # Aimag(Tu(2,3))
3 1 0.00000000E+00 # Aimag(Tu(3,1))
3 2 0.00000000E+00 # Aimag(Tu(3,2))
3 3 0.00000000E+00 # Aimag(Tu(3,3))
Block MSQ2 Q= 1.50000000E+03 # (SUSY Scale)
1 1 6.25000000E+06 # Real(mq2(1,1),dp)
1 2 -3.40483057E+00 # Real(mq2(1,2),dp)
1 3 8.11192123E+01 # Real(mq2(1,3),dp)
2 1 -3.40483057E+00 # Real(mq2(2,1),dp)
2 2 6.25000000E+06 # Real(mq2(2,2),dp)
2 3 -5.59387671E+02 # Real(mq2(2,3),dp)
3 1 8.11192123E+01 # Real(mq2(3,1),dp)
3 2 -5.59387671E+02 # Real(mq2(3,2),dp)
3 3 1.25000000E+07 # Real(mq2(3,3),dp)
Block IMMSQ2 Q= 1.50000000E+03 # (SUSY Scale)
1 1 0.00000000E+00 # Aimag(mq2(1,1))
1 2 0.00000000E+00 # Aimag(mq2(1,2))
1 3 0.00000000E+00 # Aimag(mq2(1,3))
2 1 0.00000000E+00 # Aimag(mq2(2,1))
2 2 0.00000000E+00 # Aimag(mq2(2,2))
2 3 0.00000000E+00 # Aimag(mq2(2,3))
3 1 0.00000000E+00 # Aimag(mq2(3,1))
3 2 0.00000000E+00 # Aimag(mq2(3,2))
3 3 0.00000000E+00 # Aimag(mq2(3,3))
Block MSL2 Q= 1.50000000E+03 # (SUSY Scale)
1 1 2.24973148E+06 # Real(ml2(1,1),dp)
1 2 0.00000000E+00 # Real(ml2(1,2),dp)
1 3 0.00000000E+00 # Real(ml2(1,3),dp)
2 1 0.00000000E+00 # Real(ml2(2,1),dp)
2 2 2.24973148E+06 # Real(ml2(2,2),dp)
2 3 0.00000000E+00 # Real(ml2(2,3),dp)
3 1 0.00000000E+00 # Real(ml2(3,1),dp)
3 2 0.00000000E+00 # Real(ml2(3,2),dp)
3 3 2.24973047E+06 # Real(ml2(3,3),dp)
Block IMMSL2 Q= 1.50000000E+03 # (SUSY Scale)
1 1 0.00000000E+00 # Aimag(ml2(1,1))
1 2 0.00000000E+00 # Aimag(ml2(1,2))
1 3 0.00000000E+00 # Aimag(ml2(1,3))
2 1 0.00000000E+00 # Aimag(ml2(2,1))
2 2 0.00000000E+00 # Aimag(ml2(2,2))
2 3 0.00000000E+00 # Aimag(ml2(2,3))
3 1 0.00000000E+00 # Aimag(ml2(3,1))
3 2 0.00000000E+00 # Aimag(ml2(3,2))
3 3 0.00000000E+00 # Aimag(ml2(3,3))
Block MSD2 Q= 1.50000000E+03 # (SUSY Scale)
1 1 6.25000000E+06 # Real(md2(1,1),dp)
1 2 -1.63419771E-09 # Real(md2(1,2),dp)
1 3 1.99342952E-06 # Real(md2(1,3),dp)
2 1 -1.63419771E-09 # Real(md2(2,1),dp)
2 2 6.25000000E+06 # Real(md2(2,2),dp)
2 3 -2.61173380E-04 # Real(md2(2,3),dp)
3 1 1.99342952E-06 # Real(md2(3,1),dp)
3 2 -2.61173380E-04 # Real(md2(3,2),dp)
3 3 1.25000000E+07 # Real(md2(3,3),dp)
Block IMMSD2 Q= 1.50000000E+03 # (SUSY Scale)
1 1 0.00000000E+00 # Aimag(md2(1,1))
1 2 0.00000000E+00 # Aimag(md2(1,2))
1 3 0.00000000E+00 # Aimag(md2(1,3))
2 1 0.00000000E+00 # Aimag(md2(2,1))
2 2 0.00000000E+00 # Aimag(md2(2,2))
2 3 0.00000000E+00 # Aimag(md2(2,3))
3 1 0.00000000E+00 # Aimag(md2(3,1))
3 2 0.00000000E+00 # Aimag(md2(3,2))
3 3 0.00000000E+00 # Aimag(md2(3,3))
Block MSU2 Q= 1.50000000E+03 # (SUSY Scale)
1 1 6.25000000E+06 # Real(mu2(1,1),dp)
1 2 0.00000000E+00 # Real(mu2(1,2),dp)
1 3 1.39643313E-08 # Real(mu2(1,3),dp)
2 1 0.00000000E+00 # Real(mu2(2,1),dp)
2 2 6.25000000E+06 # Real(mu2(2,2),dp)
2 3 8.29722515E-05 # Real(mu2(2,3),dp)
3 1 1.39643313E-08 # Real(mu2(3,1),dp)
3 2 8.29722515E-05 # Real(mu2(3,2),dp)
3 3 1.25000000E+07 # Real(mu2(3,3),dp)
Block IMMSU2 Q= 1.50000000E+03 # (SUSY Scale)
1 1 0.00000000E+00 # Aimag(mu2(1,1))
1 2 0.00000000E+00 # Aimag(mu2(1,2))
1 3 0.00000000E+00 # Aimag(mu2(1,3))
2 1 0.00000000E+00 # Aimag(mu2(2,1))
2 2 0.00000000E+00 # Aimag(mu2(2,2))
2 3 0.00000000E+00 # Aimag(mu2(2,3))
3 1 0.00000000E+00 # Aimag(mu2(3,1))
3 2 0.00000000E+00 # Aimag(mu2(3,2))
3 3 0.00000000E+00 # Aimag(mu2(3,3))
Block MSE2 Q= 1.50000000E+03 # (SUSY Scale)
1 1 2.25210023E+06 # Real(me2(1,1),dp)
1 2 0.00000000E+00 # Real(me2(1,2),dp)
1 3 0.00000000E+00 # Real(me2(1,3),dp)
2 1 0.00000000E+00 # Real(me2(2,1),dp)
2 2 2.25210022E+06 # Real(me2(2,2),dp)
2 3 0.00000000E+00 # Real(me2(2,3),dp)
3 1 0.00000000E+00 # Real(me2(3,1),dp)
3 2 0.00000000E+00 # Real(me2(3,2),dp)
3 3 2.25209819E+06 # Real(me2(3,3),dp)
Block IMMSE2 Q= 1.50000000E+03 # (SUSY Scale)
1 1 0.00000000E+00 # Aimag(me2(1,1))
1 2 0.00000000E+00 # Aimag(me2(1,2))
1 3 0.00000000E+00 # Aimag(me2(1,3))
2 1 0.00000000E+00 # Aimag(me2(2,1))
2 2 0.00000000E+00 # Aimag(me2(2,2))
2 3 0.00000000E+00 # Aimag(me2(2,3))
3 1 0.00000000E+00 # Aimag(me2(3,1))
3 2 0.00000000E+00 # Aimag(me2(3,2))
3 3 0.00000000E+00 # Aimag(me2(3,3))
Block MASS # Mass spectrum
# PDG code mass particle
2000003 2.56854968E+03 # SsR
2000001 2.56854970E+03 # SdR
1000001 2.57560535E+03 # SdL
1000003 2.57561205E+03 # SsL
2000005 3.59318809E+03 # Sb2
1000005 3.60691618E+03 # Sb1
2000004 2.56940276E+03 # ScR
2000002 2.56940301E+03 # SuR
1000002 2.57505076E+03 # SuL
1000004 2.57506551E+03 # ScL
1000006 3.60399143E+03 # St1
2000006 3.61257196E+03 # St2
2000015 1.50200195E+03 # Stau2
2000013 1.50214205E+03 # SmuR
2000011 1.50214259E+03 # SeR
1000011 1.50374555E+03 # SeL
1000013 1.50374603E+03 # SmuL
1000015 1.50386823E+03 # Stau1
1000016 1.50239101E+03 # Snu_tau
1000014 1.50239761E+03 # Snu_mu
1000012 1.50239763E+03 # Snu_e
25 1.10694718E+02 # hh_1
35 1.85637001E+03 # hh_2
45 2.25202843E+03 # hh_3
55 2.68990385E+03 # hh_4
36 6.35466142E+02 # Ah_2
46 2.63244944E+03 # Ah_3
56 2.68885973E+03 # Ah_4
37 6.05990017E+02 # Hpm_2
47 1.84692168E+03 # Hpm_3
57 2.68927708E+03 # Hpm_4
22 0.00000000E+00 # VP
23 9.11887000E+01 # VZ
21 0.00000000E+00 # VG
24 7.92402623E+01 # VWm
1 5.00000000E-03 # Fd_1
3 9.50000000E-02 # Fd_2
5 4.18000000E+00 # Fd_3
2 2.50000000E-03 # Fu_1
4 1.27000000E+00 # Fu_2
6 1.73500000E+02 # Fu_3
11 5.10998930E-04 # Fe_1
13 1.05658372E-01 # Fe_2
15 1.77669000E+00 # Fe_3
12 0.00000000E+00 # Fv_1
14 0.00000000E+00 # Fv_2
16 0.00000000E+00 # Fv_3
1000021 2.00866180E+03 # Glu_1
2000021 2.00866696E+03 # Glu_2
3000021 3.94150134E+03 # phiO
3000022 1.64728179E+03 # sigmaO
1000022 1.99873694E+02 # Chi_1
1000023 2.03646245E+02 # Chi_2
1000025 4.02591269E+02 # Chi_3
1000035 4.21716191E+02 # Chi_4
1000045 5.37139248E+02 # Chi_5
1000055 5.48667802E+02 # Chi_6
1000024 3.99673292E+02 # Cha_1
1000037 5.36418776E+02 # Cha_2
1000047 5.49341767E+02 # Cha_3
Block LSP # LSP and NLSP
1 1000022 # LSP
2 1000023 # NLSP
Block DSQMIX Q= 1.50000000E+03 # ()
1 1 -9.71812783E-01 # Real(ZD(1,1),dp)
1 2 -2.35753800E-01 # Real(ZD(1,2),dp)
1 3 -1.97667271E-05 # Real(ZD(1,3),dp)
1 4 5.23078054E-05 # Real(ZD(1,4),dp)
1 5 2.41087923E-04 # Real(ZD(1,5),dp)
1 6 -3.41727910E-08 # Real(ZD(1,6),dp)
2 1 -2.35753921E-01 # Real(ZD(2,1),dp)
2 2 9.71812255E-01 # Real(ZD(2,2),dp)
2 3 2.09708000E-04 # Real(ZD(2,3),dp)
2 4 1.26769005E-05 # Real(ZD(2,4),dp)
2 5 -9.92817422E-04 # Real(ZD(2,5),dp)
2 6 3.62538744E-07 # Real(ZD(2,6),dp)
3 1 2.74682393E-05 # Real(ZD(3,1),dp)
3 2 -1.89413290E-04 # Real(ZD(3,2),dp)
3 3 9.09363098E-01 # Real(ZD(3,3),dp)
3 4 2.11589465E-11 # Real(ZD(3,4),dp)
3 5 -2.77214882E-09 # Real(ZD(3,5),dp)
3 6 -4.16003268E-01 # Real(ZD(3,6),dp)
4 1 5.38220212E-05 # Real(ZD(4,1),dp)
4 2 4.37358094E-09 # Real(ZD(4,2),dp)
4 3 -1.64982017E-09 # Real(ZD(4,3),dp)
4 4 9.99999999E-01 # Real(ZD(4,4),dp)
4 5 -7.65712983E-06 # Real(ZD(4,5),dp)
4 6 -3.69628624E-12 # Real(ZD(4,6),dp)
5 1 2.32137608E-07 # Real(ZD(5,1),dp)
5 2 1.02167006E-03 # Real(ZD(5,2),dp)
5 3 2.16068822E-07 # Real(ZD(5,3),dp)
5 4 7.65710889E-06 # Real(ZD(5,4),dp)
5 5 9.99999478E-01 # Real(ZD(5,5),dp)
5 6 4.84020844E-10 # Real(ZD(5,6),dp)
6 1 -1.26232717E-05 # Real(ZD(6,1),dp)
6 2 8.70465523E-05 # Real(ZD(6,2),dp)
6 3 -4.16003259E-01 # Real(ZD(6,3),dp)
6 4 -1.06518583E-11 # Real(ZD(6,4),dp)
6 5 1.39555930E-09 # Real(ZD(6,5),dp)
6 6 -9.09363118E-01 # Real(ZD(6,6),dp)
Block IMDSQMIX Q= 1.50000000E+03 # ()
1 1 0.00000000E+00 # Aimag(ZD(1,1))
1 2 0.00000000E+00 # Aimag(ZD(1,2))
1 3 0.00000000E+00 # Aimag(ZD(1,3))
1 4 0.00000000E+00 # Aimag(ZD(1,4))
1 5 0.00000000E+00 # Aimag(ZD(1,5))
1 6 0.00000000E+00 # Aimag(ZD(1,6))
2 1 0.00000000E+00 # Aimag(ZD(2,1))
2 2 0.00000000E+00 # Aimag(ZD(2,2))
2 3 0.00000000E+00 # Aimag(ZD(2,3))
2 4 0.00000000E+00 # Aimag(ZD(2,4))
2 5 0.00000000E+00 # Aimag(ZD(2,5))
2 6 0.00000000E+00 # Aimag(ZD(2,6))
3 1 0.00000000E+00 # Aimag(ZD(3,1))
3 2 0.00000000E+00 # Aimag(ZD(3,2))
3 3 0.00000000E+00 # Aimag(ZD(3,3))
3 4 0.00000000E+00 # Aimag(ZD(3,4))
3 5 0.00000000E+00 # Aimag(ZD(3,5))
3 6 0.00000000E+00 # Aimag(ZD(3,6))
4 1 0.00000000E+00 # Aimag(ZD(4,1))
4 2 0.00000000E+00 # Aimag(ZD(4,2))
4 3 0.00000000E+00 # Aimag(ZD(4,3))
4 4 0.00000000E+00 # Aimag(ZD(4,4))
4 5 0.00000000E+00 # Aimag(ZD(4,5))
4 6 0.00000000E+00 # Aimag(ZD(4,6))
5 1 0.00000000E+00 # Aimag(ZD(5,1))
5 2 0.00000000E+00 # Aimag(ZD(5,2))
5 3 0.00000000E+00 # Aimag(ZD(5,3))
5 4 0.00000000E+00 # Aimag(ZD(5,4))
5 5 0.00000000E+00 # Aimag(ZD(5,5))
5 6 0.00000000E+00 # Aimag(ZD(5,6))
6 1 0.00000000E+00 # Aimag(ZD(6,1))
6 2 0.00000000E+00 # Aimag(ZD(6,2))
6 3 0.00000000E+00 # Aimag(ZD(6,3))
6 4 0.00000000E+00 # Aimag(ZD(6,4))
6 5 0.00000000E+00 # Aimag(ZD(6,5))
6 6 0.00000000E+00 # Aimag(ZD(6,6))
Block SNUMIX Q= 1.50000000E+03 # ()
1 1 1.00000000E+00 # Real(ZV(1,1),dp)
1 2 0.00000000E+00 # Real(ZV(1,2),dp)
1 3 0.00000000E+00 # Real(ZV(1,3),dp)
2 1 0.00000000E+00 # Real(ZV(2,1),dp)
2 2 1.00000000E+00 # Real(ZV(2,2),dp)
2 3 0.00000000E+00 # Real(ZV(2,3),dp)
3 1 0.00000000E+00 # Real(ZV(3,1),dp)
3 2 0.00000000E+00 # Real(ZV(3,2),dp)
3 3 1.00000000E+00 # Real(ZV(3,3),dp)
Block IMSNUMIX Q= 1.50000000E+03 # ()
1 1 0.00000000E+00 # Aimag(ZV(1,1))
1 2 0.00000000E+00 # Aimag(ZV(1,2))
1 3 0.00000000E+00 # Aimag(ZV(1,3))
2 1 0.00000000E+00 # Aimag(ZV(2,1))
2 2 0.00000000E+00 # Aimag(ZV(2,2))
2 3 0.00000000E+00 # Aimag(ZV(2,3))
3 1 0.00000000E+00 # Aimag(ZV(3,1))
3 2 0.00000000E+00 # Aimag(ZV(3,2))
3 3 0.00000000E+00 # Aimag(ZV(3,3))
Block USQMIX Q= 1.50000000E+03 # ()
1 1 9.82210353E-01 # Real(ZU(1,1),dp)
1 2 1.87783903E-01 # Real(ZU(1,2),dp)
1 3 1.56385066E-05 # Real(ZU(1,3),dp)
1 4 -8.63356262E-06 # Real(ZU(1,4),dp)
1 5 1.68456268E-04 # Real(ZU(1,5),dp)
1 6 -8.29861840E-06 # Real(ZU(1,6),dp)
2 1 1.87781448E-01 # Real(ZU(2,1),dp)
2 2 -9.82201338E-01 # Real(ZU(2,2),dp)
2 3 -3.48109878E-04 # Real(ZU(2,3),dp)
2 4 3.35148517E-07 # Real(ZU(2,4),dp)
2 5 4.30164817E-03 # Real(ZU(2,5),dp)
2 6 1.84708001E-04 # Real(ZU(2,6),dp)
3 1 -2.99253764E-05 # Real(ZU(3,1),dp)
3 2 2.06358294E-04 # Real(ZU(3,2),dp)
3 3 -8.64810940E-01 # Real(ZU(3,3),dp)
3 4 -1.15863827E-10 # Real(ZU(3,4),dp)
3 5 -6.89126463E-07 # Real(ZU(3,5),dp)
3 6 -5.02097595E-01 # Real(ZU(3,6),dp)
4 1 8.41647266E-06 # Real(ZU(4,1),dp)
4 2 1.95287155E-06 # Real(ZU(4,2),dp)
4 3 3.80584862E-10 # Real(ZU(4,3),dp)
4 4 1.00000000E+00 # Real(ZU(4,4),dp)
4 5 5.82879932E-07 # Real(ZU(4,5),dp)
4 6 -5.86089897E-10 # Real(ZU(4,6),dp)
5 1 -9.73238127E-04 # Real(ZU(5,1),dp)
5 2 4.19348931E-03 # Real(ZU(5,2),dp)
5 3 2.25368958E-06 # Real(ZU(5,3),dp)
5 4 -5.82872648E-07 # Real(ZU(5,4),dp)
5 5 9.99990734E-01 # Real(ZU(5,5),dp)
5 6 -3.47273055E-06 # Real(ZU(5,6),dp)
6 1 -4.80597367E-05 # Real(ZU(6,1),dp)
6 2 3.31408108E-04 # Real(ZU(6,2),dp)
6 3 -5.02097517E-01 # Real(ZU(6,3),dp)
6 4 4.53670871E-10 # Real(ZU(6,4),dp)
6 5 2.69832241E-06 # Real(ZU(6,5),dp)
6 6 8.64810945E-01 # Real(ZU(6,6),dp)
Block IMUSQMIX Q= 1.50000000E+03 # ()
1 1 0.00000000E+00 # Aimag(ZU(1,1))
1 2 0.00000000E+00 # Aimag(ZU(1,2))
1 3 0.00000000E+00 # Aimag(ZU(1,3))
1 4 0.00000000E+00 # Aimag(ZU(1,4))
1 5 0.00000000E+00 # Aimag(ZU(1,5))
1 6 0.00000000E+00 # Aimag(ZU(1,6))
2 1 0.00000000E+00 # Aimag(ZU(2,1))
2 2 0.00000000E+00 # Aimag(ZU(2,2))
2 3 0.00000000E+00 # Aimag(ZU(2,3))
2 4 0.00000000E+00 # Aimag(ZU(2,4))
2 5 0.00000000E+00 # Aimag(ZU(2,5))
2 6 0.00000000E+00 # Aimag(ZU(2,6))
3 1 0.00000000E+00 # Aimag(ZU(3,1))
3 2 0.00000000E+00 # Aimag(ZU(3,2))
3 3 0.00000000E+00 # Aimag(ZU(3,3))
3 4 0.00000000E+00 # Aimag(ZU(3,4))
3 5 0.00000000E+00 # Aimag(ZU(3,5))
3 6 0.00000000E+00 # Aimag(ZU(3,6))
4 1 0.00000000E+00 # Aimag(ZU(4,1))
4 2 0.00000000E+00 # Aimag(ZU(4,2))
4 3 0.00000000E+00 # Aimag(ZU(4,3))
4 4 0.00000000E+00 # Aimag(ZU(4,4))
4 5 0.00000000E+00 # Aimag(ZU(4,5))
4 6 0.00000000E+00 # Aimag(ZU(4,6))
5 1 0.00000000E+00 # Aimag(ZU(5,1))
5 2 0.00000000E+00 # Aimag(ZU(5,2))
5 3 0.00000000E+00 # Aimag(ZU(5,3))
5 4 0.00000000E+00 # Aimag(ZU(5,4))
5 5 0.00000000E+00 # Aimag(ZU(5,5))
5 6 0.00000000E+00 # Aimag(ZU(5,6))
6 1 0.00000000E+00 # Aimag(ZU(6,1))
6 2 0.00000000E+00 # Aimag(ZU(6,2))
6 3 0.00000000E+00 # Aimag(ZU(6,3))
6 4 0.00000000E+00 # Aimag(ZU(6,4))
6 5 0.00000000E+00 # Aimag(ZU(6,5))
6 6 0.00000000E+00 # Aimag(ZU(6,6))
Block SELMIX Q= 1.50000000E+03 # ()
1 1 -9.99999996E-01 # Real(ZE(1,1),dp)
1 2 -5.87461830E-12 # Real(ZE(1,2),dp)
1 3 -0.00000000E+00 # Real(ZE(1,3),dp)
1 4 8.51889732E-05 # Real(ZE(1,4),dp)
1 5 4.03098572E-15 # Real(ZE(1,5),dp)
1 6 -0.00000000E+00 # Real(ZE(1,6),dp)
2 1 5.87377870E-12 # Real(ZE(2,1),dp)
2 2 -9.99845004E-01 # Real(ZE(2,2),dp)
2 3 0.00000000E+00 # Real(ZE(2,3),dp)
2 4 -5.00232070E-16 # Real(ZE(2,4),dp)
2 5 1.76058995E-02 # Real(ZE(2,5),dp)
2 6 0.00000000E+00 # Real(ZE(2,6),dp)
3 1 0.00000000E+00 # Real(ZE(3,1),dp)
3 2 0.00000000E+00 # Real(ZE(3,2),dp)
3 3 -9.64705547E-01 # Real(ZE(3,3),dp)
3 4 0.00000000E+00 # Real(ZE(3,4),dp)
3 5 0.00000000E+00 # Real(ZE(3,5),dp)
3 6 2.63330983E-01 # Real(ZE(3,6),dp)
4 1 8.51889732E-05 # Real(ZE(4,1),dp)
4 2 4.40903382E-16 # Real(ZE(4,2),dp)
4 3 0.00000000E+00 # Real(ZE(4,3),dp)
4 4 9.99999996E-01 # Real(ZE(4,4),dp)
4 5 2.50305834E-14 # Real(ZE(4,5),dp)
4 6 0.00000000E+00 # Real(ZE(4,6),dp)
5 1 -9.93997107E-14 # Real(ZE(5,1),dp)
5 2 1.76058995E-02 # Real(ZE(5,2),dp)
5 3 -0.00000000E+00 # Real(ZE(5,3),dp)
5 4 -2.50259986E-14 # Real(ZE(5,4),dp)
5 5 9.99845004E-01 # Real(ZE(5,5),dp)
5 6 -0.00000000E+00 # Real(ZE(5,6),dp)
6 1 -0.00000000E+00 # Real(ZE(6,1),dp)
6 2 -0.00000000E+00 # Real(ZE(6,2),dp)
6 3 -2.63330983E-01 # Real(ZE(6,3),dp)
6 4 -0.00000000E+00 # Real(ZE(6,4),dp)
6 5 -0.00000000E+00 # Real(ZE(6,5),dp)
6 6 -9.64705547E-01 # Real(ZE(6,6),dp)
Block IMSELMIX Q= 1.50000000E+03 # ()
1 1 0.00000000E+00 # Aimag(ZE(1,1))
1 2 0.00000000E+00 # Aimag(ZE(1,2))
1 3 0.00000000E+00 # Aimag(ZE(1,3))
1 4 0.00000000E+00 # Aimag(ZE(1,4))
1 5 0.00000000E+00 # Aimag(ZE(1,5))
1 6 0.00000000E+00 # Aimag(ZE(1,6))
2 1 0.00000000E+00 # Aimag(ZE(2,1))
2 2 0.00000000E+00 # Aimag(ZE(2,2))
2 3 0.00000000E+00 # Aimag(ZE(2,3))
2 4 0.00000000E+00 # Aimag(ZE(2,4))
2 5 0.00000000E+00 # Aimag(ZE(2,5))
2 6 0.00000000E+00 # Aimag(ZE(2,6))
3 1 0.00000000E+00 # Aimag(ZE(3,1))
3 2 0.00000000E+00 # Aimag(ZE(3,2))
3 3 0.00000000E+00 # Aimag(ZE(3,3))
3 4 0.00000000E+00 # Aimag(ZE(3,4))
3 5 0.00000000E+00 # Aimag(ZE(3,5))
3 6 0.00000000E+00 # Aimag(ZE(3,6))
4 1 0.00000000E+00 # Aimag(ZE(4,1))
4 2 0.00000000E+00 # Aimag(ZE(4,2))
4 3 0.00000000E+00 # Aimag(ZE(4,3))
4 4 0.00000000E+00 # Aimag(ZE(4,4))
4 5 0.00000000E+00 # Aimag(ZE(4,5))
4 6 0.00000000E+00 # Aimag(ZE(4,6))
5 1 0.00000000E+00 # Aimag(ZE(5,1))
5 2 0.00000000E+00 # Aimag(ZE(5,2))
5 3 0.00000000E+00 # Aimag(ZE(5,3))
5 4 0.00000000E+00 # Aimag(ZE(5,4))
5 5 0.00000000E+00 # Aimag(ZE(5,5))
5 6 0.00000000E+00 # Aimag(ZE(5,6))
6 1 0.00000000E+00 # Aimag(ZE(6,1))
6 2 0.00000000E+00 # Aimag(ZE(6,2))
6 3 0.00000000E+00 # Aimag(ZE(6,3))
6 4 0.00000000E+00 # Aimag(ZE(6,4))
6 5 0.00000000E+00 # Aimag(ZE(6,5))
6 6 0.00000000E+00 # Aimag(ZE(6,6))
Block SCALARMIX Q= 1.50000000E+03 # ()
1 1 4.47777587E-01 # ZH(1,1)
1 2 8.94067128E-01 # ZH(1,2)
1 3 7.57359142E-03 # ZH(1,3)
1 4 9.04676079E-03 # ZH(1,4)
2 1 -1.93164619E-02 # ZH(2,1)
2 2 -5.27642287E-04 # ZH(2,2)
2 3 1.01164393E-02 # ZH(2,3)
2 4 9.99762098E-01 # ZH(2,4)
3 1 -4.04217320E-03 # ZH(3,1)
3 2 1.03927961E-02 # ZH(3,2)
3 3 -9.99887367E-01 # ZH(3,3)
3 4 1.00450928E-02 # ZH(3,4)
4 1 8.93927160E-01 # ZH(4,1)
4 2 -4.47812106E-01 # ZH(4,2)
4 3 -8.09639635E-03 # ZH(4,3)
4 4 1.71172043E-02 # ZH(4,4)
Block PSEUDOSCALARMIX Q= 1.50000000E+03 # ()
1 1 4.47212381E-01 # ZA(1,1)
1 2 -8.94427798E-01 # ZA(1,2)
1 3 6.19643347E-09 # ZA(1,3)
1 4 2.95224978E-07 # ZA(1,4)
2 1 -5.00869061E-06 # ZA(2,1)
2 2 -2.83440918E-06 # ZA(2,2)
2 3 -1.50193834E-04 # ZA(2,3)
2 4 -9.99999989E-01 # ZA(2,4)
3 1 -6.57580231E-04 # ZA(3,1)
3 2 -3.28782121E-04 # ZA(3,2)
3 3 9.99999718E-01 # ZA(3,3)
3 4 -1.50189568E-04 # ZA(3,4)
4 1 -8.94427557E-01 # ZA(4,1)
4 2 -4.47212260E-01 # ZA(4,2)
4 3 -7.35192602E-04 # ZA(4,3)
4 4 5.85791490E-06 # ZA(4,4)
Block CHARGEMIX Q= 1.50000000E+03 # ()
1 1 4.47192363E-01 # ZP(1,1)
1 2 -8.94386379E-01 # ZP(1,2)
1 3 6.78218310E-03 # ZP(1,3)
1 4 6.78213038E-03 # ZP(1,4)
2 1 -1.32005490E-05 # ZP(2,1)
2 2 5.46869773E-06 # ZP(2,2)
2 3 -7.06307794E-01 # ZP(2,3)
2 4 7.07904866E-01 # ZP(2,4)
3 1 1.90962272E-02 # ZP(3,1)
3 2 -1.17395504E-03 # ZP(3,2)
3 3 -7.07775475E-01 # ZP(3,3)
3 4 -7.06178329E-01 # ZP(3,4)
4 1 -8.94233931E-01 # ZP(4,1)
4 2 -4.47293670E-01 # ZP(4,2)
4 3 -1.17123459E-02 # ZP(4,3)
4 4 -1.16991419E-02 # ZP(4,4)
Block NMIX Q= 1.50000000E+03 # ()
1 1 0.00000000E+00 # Real(ZN(1,1),dp)
1 2 0.00000000E+00 # Real(ZN(1,2),dp)
1 3 -0.00000000E+00 # Real(ZN(1,3),dp)
1 4 -0.00000000E+00 # Real(ZN(1,4),dp)
1 5 -0.00000000E+00 # Real(ZN(1,5),dp)
1 6 -0.00000000E+00 # Real(ZN(1,6),dp)
2 1 -6.91298735E-01 # Real(ZN(2,1),dp)
2 2 -7.82511750E-04 # Real(ZN(2,2),dp)
2 3 -1.08708978E-01 # Real(ZN(2,3),dp)
2 4 -2.63797660E-03 # Real(ZN(2,4),dp)
2 5 -7.14308850E-01 # Real(ZN(2,5),dp)
2 6 6.61157702E-03 # Real(ZN(2,6),dp)
3 1 9.76862231E-02 # Real(ZN(3,1),dp)
3 2 2.14348191E-01 # Real(ZN(3,2),dp)
3 3 -6.61982911E-01 # Real(ZN(3,3),dp)
3 4 6.47190072E-01 # Real(ZN(3,4),dp)
3 5 6.31755956E-03 # Real(ZN(3,5),dp)
3 6 2.95628110E-01 # Real(ZN(3,6),dp)
4 1 0.00000000E+00 # Real(ZN(4,1),dp)
4 2 -0.00000000E+00 # Real(ZN(4,2),dp)
4 3 0.00000000E+00 # Real(ZN(4,3),dp)
4 4 0.00000000E+00 # Real(ZN(4,4),dp)
4 5 -0.00000000E+00 # Real(ZN(4,5),dp)
4 6 0.00000000E+00 # Real(ZN(4,6),dp)
5 1 0.00000000E+00 # Real(ZN(5,1),dp)
5 2 -0.00000000E+00 # Real(ZN(5,2),dp)
5 3 0.00000000E+00 # Real(ZN(5,3),dp)
5 4 -0.00000000E+00 # Real(ZN(5,4),dp)
5 5 0.00000000E+00 # Real(ZN(5,5),dp)
5 6 0.00000000E+00 # Real(ZN(5,6),dp)
6 1 2.85379829E-02 # Real(ZN(6,1),dp)
6 2 -6.71669268E-01 # Real(ZN(6,2),dp)
6 3 -2.33469244E-01 # Real(ZN(6,3),dp)
6 4 2.74682607E-01 # Real(ZN(6,4),dp)
6 5 1.64901062E-03 # Real(ZN(6,5),dp)
6 6 -6.46594800E-01 # Real(ZN(6,6),dp)
Block IMNMIX Q= 1.50000000E+03 # ()
1 1 7.14337054E-01 # Aimag(ZN(1,1))
1 2 3.13757864E-03 # Aimag(ZN(1,2))
1 3 -4.27194086E-02 # Aimag(ZN(1,3))
1 4 -1.38215436E-01 # Aimag(ZN(1,4))
1 5 -6.84472869E-01 # Aimag(ZN(1,5))
1 6 -1.67679785E-02 # Aimag(ZN(1,6))
2 1 0.00000000E+00 # Aimag(ZN(2,1))
2 2 0.00000000E+00 # Aimag(ZN(2,2))
2 3 0.00000000E+00 # Aimag(ZN(2,3))
2 4 0.00000000E+00 # Aimag(ZN(2,4))
2 5 0.00000000E+00 # Aimag(ZN(2,5))
2 6 0.00000000E+00 # Aimag(ZN(2,6))
3 1 0.00000000E+00 # Aimag(ZN(3,1))
3 2 0.00000000E+00 # Aimag(ZN(3,2))
3 3 0.00000000E+00 # Aimag(ZN(3,3))
3 4 0.00000000E+00 # Aimag(ZN(3,4))
3 5 0.00000000E+00 # Aimag(ZN(3,5))
3 6 0.00000000E+00 # Aimag(ZN(3,6))
4 1 3.79443006E-02 # Aimag(ZN(4,1))
4 2 -1.45441511E-02 # Aimag(ZN(4,2))
4 3 7.02556114E-01 # Aimag(ZN(4,3))
4 4 6.93024117E-01 # Aimag(ZN(4,4))
4 5 -1.45656887E-01 # Aimag(ZN(4,5))
4 6 5.71423546E-02 # Aimag(ZN(4,6))
5 1 5.64330160E-03 # Aimag(ZN(5,1))
5 2 -7.09008644E-01 # Aimag(ZN(5,2))
5 3 6.56159148E-03 # Aimag(ZN(5,3))
5 4 -7.93825147E-02 # Aimag(ZN(5,4))
5 5 1.09503756E-03 # Aimag(ZN(5,5))
5 6 7.00663299E-01 # Aimag(ZN(5,6))
6 1 0.00000000E+00 # Aimag(ZN(6,1))
6 2 0.00000000E+00 # Aimag(ZN(6,2))
6 3 0.00000000E+00 # Aimag(ZN(6,3))
6 4 0.00000000E+00 # Aimag(ZN(6,4))
6 5 0.00000000E+00 # Aimag(ZN(6,5))
6 6 0.00000000E+00 # Aimag(ZN(6,6))
Block UMIX Q= 1.50000000E+03 # ()
1 1 -2.13892119E-01 # Real(UM(1,1),dp)
1 2 9.46452464E-01 # Real(UM(1,2),dp)
1 3 -2.41822031E-01 # Real(UM(1,3),dp)
2 1 5.24728839E-01 # Real(UM(2,1),dp)
2 2 -9.74861808E-02 # Real(UM(2,2),dp)
2 3 -8.45669019E-01 # Real(UM(2,3),dp)
3 1 -8.23959833E-01 # Real(UM(3,1),dp)
3 2 -3.07772932E-01 # Real(UM(3,2),dp)
3 3 -4.75779377E-01 # Real(UM(3,3),dp)
Block IMUMIX Q= 1.50000000E+03 # ()
1 1 -0.00000000E+00 # Aimag(UM(1,1))
1 2 -0.00000000E+00 # Aimag(UM(1,2))
1 3 -0.00000000E+00 # Aimag(UM(1,3))
2 1 -0.00000000E+00 # Aimag(UM(2,1))
2 2 -0.00000000E+00 # Aimag(UM(2,2))
2 3 -0.00000000E+00 # Aimag(UM(2,3))
3 1 -0.00000000E+00 # Aimag(UM(3,1))
3 2 -0.00000000E+00 # Aimag(UM(3,2))
3 3 -0.00000000E+00 # Aimag(UM(3,3))
Block VMIX Q= 1.50000000E+03 # ()
1 1 -2.00411515E-01 # Real(UP(1,1),dp)
1 2 9.19982137E-01 # Real(UP(1,2),dp)
1 3 -3.36850252E-01 # Real(UP(1,3),dp)
2 1 -8.52308103E-01 # Real(UP(2,1),dp)
2 2 5.82932296E-03 # Real(UP(2,2),dp)
2 3 5.23007568E-01 # Real(UP(2,3),dp)
3 1 -4.83121229E-01 # Real(UP(3,1),dp)
3 2 -3.91916939E-01 # Real(UP(3,2),dp)
3 3 -7.82939967E-01 # Real(UP(3,3),dp)
Block IMVMIX Q= 1.50000000E+03 # ()
1 1 0.00000000E+00 # Aimag(UP(1,1))
1 2 0.00000000E+00 # Aimag(UP(1,2))
1 3 0.00000000E+00 # Aimag(UP(1,3))
2 1 0.00000000E+00 # Aimag(UP(2,1))
2 2 0.00000000E+00 # Aimag(UP(2,2))
2 3 0.00000000E+00 # Aimag(UP(2,3))
3 1 0.00000000E+00 # Aimag(UP(3,1))
3 2 0.00000000E+00 # Aimag(UP(3,2))
3 3 0.00000000E+00 # Aimag(UP(3,3))
Block UELMIX Q= 1.50000000E+03 # ()
1 1 1.00000000E+00 # Real(ZEL(1,1),dp)
1 2 0.00000000E+00 # Real(ZEL(1,2),dp)
1 3 0.00000000E+00 # Real(ZEL(1,3),dp)
2 1 0.00000000E+00 # Real(ZEL(2,1),dp)
2 2 1.00000000E+00 # Real(ZEL(2,2),dp)
2 3 0.00000000E+00 # Real(ZEL(2,3),dp)
3 1 0.00000000E+00 # Real(ZEL(3,1),dp)
3 2 0.00000000E+00 # Real(ZEL(3,2),dp)
3 3 1.00000000E+00 # Real(ZEL(3,3),dp)
Block IMUELMIX Q= 1.50000000E+03 # ()
1 1 0.00000000E+00 # Aimag(ZEL(1,1))
1 2 0.00000000E+00 # Aimag(ZEL(1,2))
1 3 0.00000000E+00 # Aimag(ZEL(1,3))
2 1 0.00000000E+00 # Aimag(ZEL(2,1))
2 2 0.00000000E+00 # Aimag(ZEL(2,2))
2 3 0.00000000E+00 # Aimag(ZEL(2,3))
3 1 0.00000000E+00 # Aimag(ZEL(3,1))
3 2 0.00000000E+00 # Aimag(ZEL(3,2))
3 3 0.00000000E+00 # Aimag(ZEL(3,3))
Block UERMIX Q= 1.50000000E+03 # ()
1 1 1.00000000E+00 # Real(ZER(1,1),dp)
1 2 0.00000000E+00 # Real(ZER(1,2),dp)
1 3 0.00000000E+00 # Real(ZER(1,3),dp)
2 1 0.00000000E+00 # Real(ZER(2,1),dp)
2 2 1.00000000E+00 # Real(ZER(2,2),dp)
2 3 0.00000000E+00 # Real(ZER(2,3),dp)
3 1 0.00000000E+00 # Real(ZER(3,1),dp)
3 2 0.00000000E+00 # Real(ZER(3,2),dp)
3 3 1.00000000E+00 # Real(ZER(3,3),dp)
Block IMUERMIX Q= 1.50000000E+03 # ()
1 1 0.00000000E+00 # Aimag(ZER(1,1))
1 2 0.00000000E+00 # Aimag(ZER(1,2))
1 3 0.00000000E+00 # Aimag(ZER(1,3))
2 1 0.00000000E+00 # Aimag(ZER(2,1))
2 2 0.00000000E+00 # Aimag(ZER(2,2))
2 3 0.00000000E+00 # Aimag(ZER(2,3))
3 1 0.00000000E+00 # Aimag(ZER(3,1))
3 2 0.00000000E+00 # Aimag(ZER(3,2))
3 3 0.00000000E+00 # Aimag(ZER(3,3))
Block UDLMIX Q= 1.50000000E+03 # ()
1 1 1.00000000E+00 # Real(ZDL(1,1),dp)
1 2 -6.40187274E-07 # Real(ZDL(1,2),dp)
1 3 1.53572605E-05 # Real(ZDL(1,3),dp)
2 1 6.41814853E-07 # Real(ZDL(2,1),dp)
2 2 9.99999994E-01 # Real(ZDL(2,2),dp)
2 3 -1.05981352E-04 # Real(ZDL(2,3),dp)
3 1 -1.53571925E-05 # Real(ZDL(3,1),dp)
3 2 1.05981362E-04 # Real(ZDL(3,2),dp)
3 3 9.99999994E-01 # Real(ZDL(3,3),dp)
Block IMUDLMIX Q= 1.50000000E+03 # ()
1 1 0.00000000E+00 # Aimag(ZDL(1,1))
1 2 0.00000000E+00 # Aimag(ZDL(1,2))
1 3 0.00000000E+00 # Aimag(ZDL(1,3))
2 1 0.00000000E+00 # Aimag(ZDL(2,1))
2 2 0.00000000E+00 # Aimag(ZDL(2,2))
2 3 -0.00000000E+00 # Aimag(ZDL(2,3))
3 1 -0.00000000E+00 # Aimag(ZDL(3,1))
3 2 0.00000000E+00 # Aimag(ZDL(3,2))
3 3 0.00000000E+00 # Aimag(ZDL(3,3))
Block UDRMIX Q= 1.50000000E+03 # ()
1 1 1.00000000E+00 # Real(ZDR(1,1),dp)
1 2 -6.72897973E-08 # Real(ZDR(1,2),dp)
1 3 3.15821226E-08 # Real(ZDR(1,3),dp)
2 1 6.72899280E-08 # Real(ZDR(2,1),dp)
2 2 1.00000000E+00 # Real(ZDR(2,2),dp)
2 3 -4.13931484E-06 # Real(ZDR(2,3),dp)
3 1 -3.15818440E-08 # Real(ZDR(3,1),dp)
3 2 4.13931484E-06 # Real(ZDR(3,2),dp)
3 3 1.00000000E+00 # Real(ZDR(3,3),dp)
Block IMUDRMIX Q= 1.50000000E+03 # ()
1 1 0.00000000E+00 # Aimag(ZDR(1,1))
1 2 -0.00000000E+00 # Aimag(ZDR(1,2))
1 3 0.00000000E+00 # Aimag(ZDR(1,3))
2 1 0.00000000E+00 # Aimag(ZDR(2,1))
2 2 0.00000000E+00 # Aimag(ZDR(2,2))
2 3 0.00000000E+00 # Aimag(ZDR(2,3))
3 1 0.00000000E+00 # Aimag(ZDR(3,1))
3 2 0.00000000E+00 # Aimag(ZDR(3,2))
3 3 0.00000000E+00 # Aimag(ZDR(3,3))
Block UULMIX Q= 1.50000000E+03 # ()
1 1 9.74159113E-01 # Real(ZUL(1,1),dp)
1 2 2.25835711E-01 # Real(ZUL(1,2),dp)
1 3 3.50053929E-03 # Real(ZUL(1,3),dp)
2 1 -2.25783196E-01 # Real(ZUL(2,1),dp)
2 2 9.73287097E-01 # Real(ZUL(2,2),dp)
2 3 4.16434389E-02 # Real(ZUL(2,3),dp)
3 1 5.99754591E-03 # Real(ZUL(3,1),dp)
3 2 -4.13576984E-02 # Real(ZUL(3,2),dp)
3 3 9.99126404E-01 # Real(ZUL(3,3),dp)
Block IMUULMIX Q= 1.50000000E+03 # ()
1 1 0.00000000E+00 # Aimag(ZUL(1,1))
1 2 0.00000000E+00 # Aimag(ZUL(1,2))
1 3 0.00000000E+00 # Aimag(ZUL(1,3))
2 1 0.00000000E+00 # Aimag(ZUL(2,1))
2 2 0.00000000E+00 # Aimag(ZUL(2,2))
2 3 0.00000000E+00 # Aimag(ZUL(2,3))
3 1 0.00000000E+00 # Aimag(ZUL(3,1))
3 2 -0.00000000E+00 # Aimag(ZUL(3,2))
3 3 0.00000000E+00 # Aimag(ZUL(3,3))
Block UURMIX Q= 1.50000000E+03 # ()
1 1 1.00000000E+00 # Real(ZUR(1,1),dp)
1 2 4.82796470E-10 # Real(ZUR(1,2),dp)
1 3 9.89795381E-11 # Real(ZUR(1,3),dp)
2 1 -4.82796529E-10 # Real(ZUR(2,1),dp)
2 2 1.00000000E+00 # Real(ZUR(2,2),dp)
2 3 5.88717512E-07 # Real(ZUR(2,3),dp)
3 1 -9.89792539E-11 # Real(ZUR(3,1),dp)
3 2 -5.88717512E-07 # Real(ZUR(3,2),dp)
3 3 1.00000000E+00 # Real(ZUR(3,3),dp)
Block IMUURMIX Q= 1.50000000E+03 # ()
1 1 0.00000000E+00 # Aimag(ZUR(1,1))
1 2 0.00000000E+00 # Aimag(ZUR(1,2))
1 3 0.00000000E+00 # Aimag(ZUR(1,3))
2 1 -0.00000000E+00 # Aimag(ZUR(2,1))
2 2 0.00000000E+00 # Aimag(ZUR(2,2))
2 3 0.00000000E+00 # Aimag(ZUR(2,3))
3 1 0.00000000E+00 # Aimag(ZUR(3,1))
3 2 0.00000000E+00 # Aimag(ZUR(3,2))
3 3 0.00000000E+00 # Aimag(ZUR(3,3))
Block ZG Q= 1.50000000E+03 # ()
1 1 0.00000000E+00 # Real(ZG(1,1),dp)
1 2 -0.00000000E+00 # Real(ZG(1,2),dp)
2 1 -7.07107229E-01 # Real(ZG(2,1),dp)
2 2 -7.07106334E-01 # Real(ZG(2,2),dp)
Block IMZG Q= 1.50000000E+03 # ()
1 1 7.07106334E-01 # Aimag(ZG(1,1))
1 2 -7.07107229E-01 # Aimag(ZG(1,2))
2 1 0.00000000E+00 # Aimag(ZG(2,1))
2 2 0.00000000E+00 # Aimag(ZG(2,2))
Block SPheno # SPheno internal parameters
1 -1.00000000E+00 # ErrorLevel
2 0.00000000E+00 # SPA_conventions
11 1.00000000E+00 # Branching ratios
13 1.00000000E+00 # 3 Body decays
31 1.50000000E+03 # GUT scale
33 1.50000000E+03 # Renormalization scale
34 1.00000000E-04 # Precision
35 4.00000000E+01 # Iterations
38 2.00000000E+00 # RGE level
40 7.29735257E-03 # Alpha
41 2.49520000E+00 # Gamma_Z
42 2.06000000E+00 # Gamma_W
50 1.00000000E+00 # Rotate negative fermion masses
51 0.00000000E+00 # Switch to SCKM matrix
52 0.00000000E+00 # Ignore negative masses
53 0.00000000E+00 # Ignore negative masses at MZ
55 1.00000000E+00 # Calculate one loop masses
56 1.00000000E+00 # Calculate two-loop Higgs masses
57 1.00000000E+00 # Calculate low energy
60 1.00000000E+00 # Include kinetic mixing
65 1.00000000E+00 # Solution of tadpole equation
8 3.00000000E+00 # Two-Loop Method: diagrammatic
9 1.00000000E+00 # Gauge-less limit
Block HiggsLHC7 # Higgs production cross section at LHC7 [pb] (rescaled SM values from HXSWG)
1 25 1.99229160E+01 # Gluon fusion
2 25 1.38821686E+00 # Vector boson fusion
3 25 8.36470724E-01 # W-H production
4 25 4.63431529E-01 # Z-H production
5 25 1.23359170E-01 # t-t-H production
1 36 8.55466763E-07 # Gluon fusion
Block HiggsLHC8 # Higgs production cross section at LHC8 [pb] (rescaled SM values from HXSWG)
1 25 2.51511637E+01 # Gluon fusion
2 25 1.77804684E+00 # Vector boson fusion
3 25 1.03643434E+00 # W-H production
4 25 5.76048115E-01 # Z-H production
5 25 1.85452971E-01 # t-t-H production
1 36 1.31822273E-06 # Gluon fusion
Block HiggsLHC13 # Higgs production cross section at LHC13 [pb] (rescaled SM values from SusHI 1.5.0)
1 25 5.75566868E+01 # Gluon fusion
1 36 5.13569985E-06 # Gluon fusion
Block HiggsLHC14 # Higgs production cross section at LHC14 [pb] (rescaled SM values from SusHI 1.5.0)
1 25 6.46183382E+01 # Gluon fusion
1 36 6.13863681E-06 # Gluon fusion
Block HiggsFCC100 # Higgs production cross section at FCC-pp [pb] (rescaled SM values from SusHI 1.5.0)
1 25 8.95954842E+02 # Gluon fusion
1 36 3.08512062E-04 # Gluon fusion
Block HPPloops # Loop contributions to H-Photon-Photon coupling
25 24 8.74758683E+00 # h( 1)-VWm( 1)-loop
25 2000003 -8.16538062E-06 # h( 1)-Sd( 1)-loop
25 2000001 -8.16611466E-06 # h( 1)-Sd( 2)-loop
25 1000001 -3.52392170E-05 # h( 1)-Sd( 3)-loop
25 1000003 -3.52397783E-05 # h( 1)-Sd( 4)-loop
25 2000005 1.37075219E-06 # h( 1)-Sd( 5)-loop
25 1000005 -2.36153647E-05 # h( 1)-Sd( 6)-loop
25 2000004 6.52976672E-05 # h( 1)-Su( 1)-loop
25 2000002 6.52855378E-05 # h( 1)-Su( 2)-loop
25 1000002 1.08510406E-04 # h( 1)-Su( 3)-loop
25 1000004 1.04818338E-04 # h( 1)-Su( 4)-loop
25 1000006 -4.98923776E-04 # h( 1)-Su( 5)-loop
25 2000006 -1.62675474E-03 # h( 1)-Su( 6)-loop
25 2000015 -1.40453106E-04 # h( 1)-Se( 1)-loop
25 2000013 -1.95086476E-04 # h( 1)-Se( 2)-loop
25 2000011 -1.95311500E-04 # h( 1)-Se( 3)-loop
25 1000011 -1.51955562E-04 # h( 1)-Se( 4)-loop
25 1000013 -1.52183262E-04 # h( 1)-Se( 5)-loop
25 1000015 -2.07588885E-04 # h( 1)-Se( 6)-loop
25 37 -2.72076419E-04 # h( 1)-Hpm( 2)-loop
25 47 4.31159682E-05 # h( 1)-Hpm( 3)-loop
25 57 -2.43465801E-04 # h( 1)-Hpm( 4)-loop
25 1000024 8.91650482E-02 # h( 1)-Cha( 1)-loop
25 1000037 -1.60331334E-02 # h( 1)-Cha( 2)-loop
25 1000047 -9.18639817E-02 # h( 1)-Cha( 3)-loop
25 11 2.39258884E-08 # h( 1)-Fe( 1)-loop
25 13 3.18306968E-04 # h( 1)-Fe( 2)-loop
25 15 2.75418936E-02 # h( 1)-Fe( 3)-loop
25 1 3.59041197E-07 # h( 1)-Fd( 1)-loop
25 3 6.94067652E-05 # h( 1)-Fd( 2)-loop
25 5 2.56175170E-02 # h( 1)-Fd( 3)-loop
25 2 3.44386405E-07 # h( 1)-Fu( 1)-loop
25 4 1.51456267E-02 # h( 1)-Fu( 2)-loop
25 6 -1.73559241E+00 # h( 1)-Fu( 3)-loop
35 24 1.82892697E-02 # h( 2)-VWm( 1)-loop
35 2000003 -1.26033491E-06 # h( 2)-Sd( 1)-loop
35 2000001 -1.26119380E-06 # h( 2)-Sd( 2)-loop
35 1000001 7.90216197E-04 # h( 2)-Sd( 3)-loop
35 1000003 7.90211015E-04 # h( 2)-Sd( 4)-loop
35 2000005 6.75073119E-05 # h( 2)-Sd( 5)-loop
35 1000005 3.20831992E-04 # h( 2)-Sd( 6)-loop
35 2000004 1.00231188E-05 # h( 2)-Su( 1)-loop
35 2000002 1.00823510E-05 # h( 2)-Su( 2)-loop
35 1000002 -3.16734866E-03 # h( 2)-Su( 3)-loop
35 1000004 -3.16724914E-03 # h( 2)-Su( 4)-loop
35 1000006 -1.16513379E-03 # h( 2)-Su( 5)-loop
35 2000006 -3.85877827E-04 # h( 2)-Su( 6)-loop
35 2000015 5.02067619E-04 # h( 2)-Se( 1)-loop
35 2000013 -3.40769572E-05 # h( 2)-Se( 2)-loop
35 2000011 -3.64827121E-05 # h( 2)-Se( 3)-loop
35 1000011 7.66791448E-03 # h( 2)-Se( 4)-loop
35 1000013 7.66550926E-03 # h( 2)-Se( 5)-loop
35 1000015 7.12951414E-03 # h( 2)-Se( 6)-loop
35 37 5.34440849E-05 # h( 2)-Hpm( 2)-loop
35 47 -1.72662012E-06 # h( 2)-Hpm( 3)-loop
35 57 1.55836311E-03 # h( 2)-Hpm( 4)-loop
35 1000024 2.09117445E-02 # h( 2)-Cha( 1)-loop
35 1000037 -1.60271634E-01 # h( 2)-Cha( 2)-loop
35 1000047 1.61007578E-01 # h( 2)-Cha( 3)-loop
35 11 -5.77601047E-12 # h( 2)-Fe( 1)-loop
35 13 -1.01170971E-07 # h( 2)-Fe( 2)-loop
35 15 -1.39388092E-05 # h( 2)-Fe( 3)-loop
35 1 -5.96730695E-11 # h( 2)-Fd( 1)-loop
35 3 -1.53240267E-08 # h( 2)-Fd( 2)-loop
35 5 -1.34988479E-05 # h( 2)-Fd( 3)-loop
35 2 -8.41763560E-13 # h( 2)-Fu( 1)-loop
35 4 -8.35628734E-08 # h( 2)-Fu( 2)-loop
35 6 -1.18431043E-04 # h( 2)-Fu( 3)-loop
45 24 1.43560001E-02 # h( 3)-VWm( 1)-loop
45 2000003 1.18714543E-04 # h( 3)-Sd( 1)-loop
45 2000001 1.18714482E-04 # h( 3)-Sd( 2)-loop
45 1000001 6.64982179E-05 # h( 3)-Sd( 3)-loop
45 1000003 6.64977781E-05 # h( 3)-Sd( 4)-loop
45 2000005 5.40471333E-05 # h( 3)-Sd( 5)-loop
45 1000005 3.53192774E-05 # h( 3)-Sd( 6)-loop
45 2000004 -9.48983048E-04 # h( 3)-Su( 1)-loop
45 2000002 -9.49009408E-04 # h( 3)-Su( 2)-loop
45 1000002 2.06055890E-04 # h( 3)-Su( 3)-loop
45 1000004 2.05996428E-04 # h( 3)-Su( 4)-loop
45 1000006 1.48888410E-05 # h( 3)-Su( 5)-loop
45 2000006 -3.87403905E-04 # h( 3)-Su( 6)-loop
45 2000015 3.48119206E-03 # h( 3)-Se( 1)-loop
45 2000013 3.86262628E-03 # h( 3)-Se( 2)-loop
45 2000011 3.86434342E-03 # h( 3)-Se( 3)-loop
45 1000011 -1.84415557E-03 # h( 3)-Se( 4)-loop
45 1000013 -1.84243800E-03 # h( 3)-Se( 5)-loop
45 1000015 -1.46088035E-03 # h( 3)-Se( 6)-loop
45 37 1.87952676E-06 # h( 3)-Hpm( 2)-loop
45 47 -4.00782054E-07 # h( 3)-Hpm( 3)-loop
45 57 -1.42371550E-03 # h( 3)-Hpm( 4)-loop
45 1000024 -2.01794990E-02 # h( 3)-Cha( 1)-loop
45 1000037 -8.33297326E-04 # h( 3)-Cha( 2)-loop
45 1000047 -8.41178463E-03 # h( 3)-Cha( 3)-loop
45 11 -8.42730295E-13 # h( 3)-Fe( 1)-loop
45 13 -1.49814792E-08 # h( 3)-Fe( 2)-loop
45 15 -2.10229572E-06 # h( 3)-Fe( 3)-loop
45 1 -8.60158506E-12 # h( 3)-Fd( 1)-loop
45 3 -2.24256439E-09 # h( 3)-Fd( 2)-loop
45 5 -2.04390938E-06 # h( 3)-Fd( 3)-loop
45 2 1.13831393E-11 # h( 3)-Fu( 1)-loop
45 4 1.17398263E-06 # h( 3)-Fu( 2)-loop
45 6 2.20116525E-03 # h( 3)-Fu( 3)-loop
55 24 -8.25236183E-04 # h( 4)-VWm( 1)-loop
55 2000003 1.12676698E-05 # h( 4)-Sd( 1)-loop
55 2000001 1.12680421E-05 # h( 4)-Sd( 2)-loop
55 1000001 7.22233531E-05 # h( 4)-Sd( 3)-loop
55 1000003 7.22230992E-05 # h( 4)-Sd( 4)-loop
55 2000005 7.51453267E-06 # h( 4)-Sd( 5)-loop
55 1000005 3.42848815E-05 # h( 4)-Sd( 6)-loop
55 2000004 -8.99834809E-05 # h( 4)-Su( 1)-loop
55 2000002 -9.00733843E-05 # h( 4)-Su( 2)-loop
55 1000002 -2.44235051E-04 # h( 4)-Su( 3)-loop
55 1000004 -2.42900780E-04 # h( 4)-Su( 4)-loop
55 1000006 1.27394404E-03 # h( 4)-Su( 5)-loop
55 2000006 -6.39305283E-04 # h( 4)-Su( 6)-loop
55 2000015 4.66644325E-04 # h( 4)-Se( 1)-loop
55 2000013 5.03453719E-04 # h( 4)-Se( 2)-loop
55 2000011 5.03599052E-04 # h( 4)-Se( 3)-loop
55 1000011 7.43536714E-04 # h( 4)-Se( 4)-loop
55 1000013 7.43668422E-04 # h( 4)-Se( 5)-loop
55 1000015 7.76639176E-04 # h( 4)-Se( 6)-loop
55 37 6.88068124E-06 # h( 4)-Hpm( 2)-loop
55 47 2.36034748E-04 # h( 4)-Hpm( 3)-loop
55 57 -1.03588405E-04 # h( 4)-Hpm( 4)-loop
55 1000024 1.10820679E-04 # h( 4)-Cha( 1)-loop
55 1000037 -5.36864056E-03 # h( 4)-Cha( 2)-loop
55 1000047 -2.66219107E-03 # h( 4)-Cha( 3)-loop
55 11 1.33736177E-10 # h( 4)-Fe( 1)-loop
55 13 2.40884146E-06 # h( 4)-Fe( 2)-loop
55 15 3.43483280E-04 # h( 4)-Fe( 3)-loop
55 1 1.34948776E-09 # h( 4)-Fd( 1)-loop
55 3 3.56666817E-07 # h( 4)-Fd( 2)-loop
55 5 3.34926319E-04 # h( 4)-Fd( 3)-loop
55 2 -3.46909093E-10 # h( 4)-Fu( 1)-loop
55 4 -3.70192175E-05 # h( 4)-Fu( 2)-loop
55 6 -8.47633751E-02 # h( 4)-Fu( 3)-loop
Block EFFHIGGSCOUPLINGS # values of loop-induced couplings
25 22 22 0.33296131E-04 # H-Photon-Photon
25 21 21 0.66089970E-04 # H-Gluon-Gluon
25 22 23 0.00000000E+00 # H-Photon-Z (not yet calculated by SPheno)
35 22 22 0.38760438E-06 # H-Photon-Photon
35 21 21 0.94320257E-08 # H-Gluon-Gluon
35 22 23 0.00000000E+00 # H-Photon-Z (not yet calculated by SPheno)
45 22 22 0.79367212E-06 # H-Photon-Photon
45 21 21 0.12538099E-06 # H-Gluon-Gluon
45 22 23 0.00000000E+00 # H-Photon-Z (not yet calculated by SPheno)
55 22 22 0.83185658E-06 # H-Photon-Photon
55 21 21 0.41085375E-05 # H-Gluon-Gluon
55 22 23 0.00000000E+00 # H-Photon-Z (not yet calculated by SPheno)
36 22 22 0.53899233E-06 # A-Photon-Photon
36 21 21 0.25226520E-09 # A-Gluon-Gluon
36 22 23 0.00000000E+00 # A-Photon-Z (not yet calculated by SPheno)
46 22 22 0.73173111E-06 # A-Photon-Photon
46 21 21 0.33936254E-08 # A-Gluon-Gluon
46 22 23 0.00000000E+00 # A-Photon-Z (not yet calculated by SPheno)
56 22 22 0.73202854E-06 # A-Photon-Photon
56 21 21 0.44662517E-05 # A-Gluon-Gluon
56 22 23 0.00000000E+00 # A-Photon-Z (not yet calculated by SPheno)
Block SPhenoLowEnergy # low energy observables
1 2.25414564E-02 # T-parameter (1-loop BSM)
2 2.57220633E-01 # S-parameter (1-loop BSM)
3 1.32722169E-02 # U-parameter (1-loop BSM)
20 -2.73830648E-16 # (g-2)_e
21 -1.17071094E-11 # (g-2)_mu
22 -3.30980495E-09 # (g-2)_tau
23 0.00000000E+00 # EDM(e)
24 0.00000000E+00 # EDM(mu)
25 0.00000000E+00 # EDM(tau)
39 -2.88898771E-05 # delta(rho)
Block FlavorKitQFV # quark flavor violating observables
Block FlavorKitLFV # lepton flavor violating observables
Block FWCOEF Q= 1.60000000E+02 # Wilson coefficients at scale Q
Block IMFWCOEF Q= 1.60000000E+02 # Im(Wilson coefficients) at scale Q
DECAY 2000003 2.30151175E+01 # SsR
# BR NDA ID1 ID2
3.27325641E-02 2 3 1000022 # BR(SsR -> Fd_2 Chi_1 )
3.06411181E-02 2 3 1000023 # BR(SsR -> Fd_2 Chi_2 )
5.89984777E-04 2 3 1000025 # BR(SsR -> Fd_2 Chi_3 )
4.67950808E-01 2 1000021 3 # BR(SsR -> Glu_1 Fd_2 )
4.67944696E-01 2 2000021 3 # BR(SsR -> Glu_2 Fd_2 )
DECAY 2000001 2.30150567E+01 # SdR
# BR NDA ID1 ID2
3.27326954E-02 2 1 1000022 # BR(SdR -> Fd_1 Chi_1 )
3.06411652E-02 2 1 1000023 # BR(SdR -> Fd_1 Chi_2 )
5.89540130E-04 2 1 1000025 # BR(SdR -> Fd_1 Chi_3 )
4.67952210E-01 2 1000021 1 # BR(SdR -> Glu_1 Fd_1 )
4.67945814E-01 2 2000021 1 # BR(SdR -> Glu_2 Fd_1 )
DECAY 1000001 5.12846480E+01 # SdL
# BR NDA ID1 ID2
1.79284013E-02 2 2 1000024 # BR(SdL -> Fu_1 Cha_1 )
1.03675453E-01 2 2 1000037 # BR(SdL -> Fu_1 Cha_2 )
2.54504558E-01 2 2 1000047 # BR(SdL -> Fu_1 Cha_3 )
3.31775626E-03 2 1 1000022 # BR(SdL -> Fd_1 Chi_1 )
3.21678962E-03 2 1 1000023 # BR(SdL -> Fd_1 Chi_2 )
7.10032876E-03 2 1 1000025 # BR(SdL -> Fd_1 Chi_3 )
8.96376428E-02 2 1 1000045 # BR(SdL -> Fd_1 Chi_5 )
8.11722141E-02 2 1 1000055 # BR(SdL -> Fd_1 Chi_6 )
1.95255000E-04 2 3 1000022 # BR(SdL -> Fd_2 Chi_1 )
1.89311389E-04 2 3 1000023 # BR(SdL -> Fd_2 Chi_2 )
4.17866915E-04 2 3 1000025 # BR(SdL -> Fd_2 Chi_3 )
5.27527401E-03 2 3 1000045 # BR(SdL -> Fd_2 Chi_5 )
4.77707967E-03 2 3 1000055 # BR(SdL -> Fd_2 Chi_6 )
2.02317095E-01 2 1000021 1 # BR(SdL -> Glu_1 Fd_1 )
1.19066000E-02 2 1000021 3 # BR(SdL -> Glu_1 Fd_2 )
2.02314375E-01 2 2000021 1 # BR(SdL -> Glu_2 Fd_1 )
1.19064328E-02 2 2000021 3 # BR(SdL -> Glu_2 Fd_2 )
DECAY 1000003 5.13557434E+01 # SsL
# BR NDA ID1 ID2
1.78844045E-02 2 4 1000024 # BR(SsL -> Fu_2 Cha_1 )
1.03355883E-01 2 4 1000037 # BR(SsL -> Fu_2 Cha_2 )
2.53722619E-01 2 4 1000047 # BR(SsL -> Fu_2 Cha_3 )
1.18963040E-03 2 6 1000024 # BR(SsL -> Fu_3 Cha_1 )
1.75894312E-04 2 6 1000037 # BR(SsL -> Fu_3 Cha_2 )
6.51701605E-04 2 6 1000047 # BR(SsL -> Fu_3 Cha_3 )
1.94984030E-04 2 1 1000022 # BR(SsL -> Fd_1 Chi_1 )
1.89050237E-04 2 1 1000023 # BR(SsL -> Fd_1 Chi_2 )
4.17285323E-04 2 1 1000025 # BR(SsL -> Fd_1 Chi_3 )
5.26799279E-03 2 1 1000045 # BR(SsL -> Fd_1 Chi_5 )
4.77048073E-03 2 1 1000055 # BR(SsL -> Fd_1 Chi_6 )
3.31319174E-03 2 3 1000022 # BR(SsL -> Fd_2 Chi_1 )
3.21233739E-03 2 3 1000023 # BR(SsL -> Fd_2 Chi_2 )
7.09059185E-03 2 3 1000025 # BR(SsL -> Fd_2 Chi_3 )
8.95137213E-02 2 3 1000045 # BR(SsL -> Fd_2 Chi_5 )
8.10600902E-02 2 3 1000055 # BR(SsL -> Fd_2 Chi_6 )
1.18903361E-02 2 1000021 1 # BR(SsL -> Glu_1 Fd_1 )
2.02040837E-01 2 1000021 3 # BR(SsL -> Glu_1 Fd_2 )
1.18901763E-02 2 2000021 1 # BR(SsL -> Glu_2 Fd_1 )
2.02038000E-01 2 2000021 3 # BR(SsL -> Glu_2 Fd_2 )
DECAY 2000005 1.13831001E+02 # Sb2
# BR NDA ID1 ID2
7.99749533E-02 2 6 1000024 # BR(Sb2 -> Fu_3 Cha_1 )
1.21531837E-02 2 6 1000037 # BR(Sb2 -> Fu_3 Cha_2 )
4.07723126E-02 2 6 1000047 # BR(Sb2 -> Fu_3 Cha_3 )
7.97921628E-03 2 5 1000022 # BR(Sb2 -> Fd_3 Chi_1 )
7.85778951E-03 2 5 1000023 # BR(Sb2 -> Fd_3 Chi_2 )
1.86615058E-03 2 5 1000025 # BR(Sb2 -> Fd_3 Chi_3 )
4.50479710E-04 2 5 1000035 # BR(Sb2 -> Fd_3 Chi_4 )
1.08143965E-02 2 5 1000045 # BR(Sb2 -> Fd_3 Chi_5 )
8.85182785E-03 2 5 1000055 # BR(Sb2 -> Fd_3 Chi_6 )
4.14009401E-01 2 1000021 5 # BR(Sb2 -> Glu_1 Fd_3 )
4.15195400E-01 2 2000021 5 # BR(Sb2 -> Glu_2 Fd_3 )
DECAY 1000005 1.80400858E+02 # Sb1
# BR NDA ID1 ID2
1.53053755E-04 2 4 1000047 # BR(Sb1 -> Fu_2 Cha_3 )
2.34955486E-01 2 6 1000024 # BR(Sb1 -> Fu_3 Cha_1 )
3.51850378E-02 2 6 1000037 # BR(Sb1 -> Fu_3 Cha_2 )
1.31317209E-01 2 6 1000047 # BR(Sb1 -> Fu_3 Cha_3 )
2.25322701E-03 2 5 1000022 # BR(Sb1 -> Fd_3 Chi_1 )
1.91877689E-03 2 5 1000023 # BR(Sb1 -> Fd_3 Chi_2 )
2.28864012E-03 2 5 1000025 # BR(Sb1 -> Fd_3 Chi_3 )
1.00959023E-04 2 5 1000035 # BR(Sb1 -> Fd_3 Chi_4 )
3.26369375E-02 2 5 1000045 # BR(Sb1 -> Fd_3 Chi_5 )
3.02671700E-02 2 5 1000055 # BR(Sb1 -> Fd_3 Chi_6 )
2.64800737E-01 2 1000021 5 # BR(Sb1 -> Glu_1 Fd_3 )
2.64051544E-01 2 2000021 5 # BR(Sb1 -> Glu_2 Fd_3 )
DECAY 2000004 2.74969876E+01 # ScR
# BR NDA ID1 ID2
1.09626794E-01 2 4 1000022 # BR(ScR -> Fu_2 Chi_1 )
1.02620060E-01 2 4 1000023 # BR(ScR -> Fu_2 Chi_2 )
1.98822904E-03 2 4 1000025 # BR(ScR -> Fu_2 Chi_3 )
3.07926370E-04 2 4 1000035 # BR(ScR -> Fu_2 Chi_4 )
1.61281699E-04 2 4 1000055 # BR(ScR -> Fu_2 Chi_6 )
3.92618924E-01 2 1000021 4 # BR(ScR -> Glu_1 Fu_2 )
3.92626993E-01 2 2000021 4 # BR(ScR -> Glu_2 Fu_2 )
DECAY 2000002 2.74952355E+01 # SuR
# BR NDA ID1 ID2
1.09633717E-01 2 2 1000022 # BR(SuR -> Fu_1 Chi_1 )
1.02628452E-01 2 2 1000023 # BR(SuR -> Fu_1 Chi_2 )
1.97463055E-03 2 2 1000025 # BR(SuR -> Fu_1 Chi_3 )
2.96471820E-04 2 2 1000035 # BR(SuR -> Fu_1 Chi_4 )
1.61331144E-04 2 2 1000055 # BR(SuR -> Fu_1 Chi_6 )
3.92652210E-01 2 1000021 2 # BR(SuR -> Glu_1 Fu_1 )
3.92646854E-01 2 2000021 2 # BR(SuR -> Glu_2 Fu_1 )
DECAY 1000002 5.12843742E+01 # SuL
# BR NDA ID1 ID2
3.84969206E-03 2 2 1000022 # BR(SuL -> Fu_1 Chi_1 )
3.48287360E-03 2 2 1000023 # BR(SuL -> Fu_1 Chi_2 )
1.05898850E-02 2 2 1000025 # BR(SuL -> Fu_1 Chi_3 )
9.41779651E-02 2 2 1000045 # BR(SuL -> Fu_1 Chi_5 )
8.30927573E-02 2 2 1000055 # BR(SuL -> Fu_1 Chi_6 )
1.43449748E-04 2 4 1000045 # BR(SuL -> Fu_2 Chi_5 )
1.26571470E-04 2 4 1000055 # BR(SuL -> Fu_2 Chi_6 )
1.51829173E-02 2 -1000024 1 # BR(SuL -> Cha_1^* Fd_1 )
5.55016712E-04 2 -1000024 3 # BR(SuL -> Cha_1^* Fd_2 )
2.63845961E-01 2 -1000037 1 # BR(SuL -> Cha_2^* Fd_1 )
9.64408921E-03 2 -1000037 3 # BR(SuL -> Cha_2^* Fd_2 )
8.44007281E-02 2 -1000047 1 # BR(SuL -> Cha_3^* Fd_1 )
3.08497289E-03 2 -1000047 3 # BR(SuL -> Cha_3^* Fd_2 )
2.13566287E-01 2 1000021 2 # BR(SuL -> Glu_1 Fu_1 )
3.25312310E-04 2 1000021 4 # BR(SuL -> Glu_1 Fu_2 )
2.13563412E-01 2 2000021 2 # BR(SuL -> Glu_2 Fu_1 )
3.25296885E-04 2 2000021 4 # BR(SuL -> Glu_2 Fu_2 )
DECAY 1000004 5.13537661E+01 # ScL
# BR NDA ID1 ID2
1.42451325E-04 2 2 1000045 # BR(ScL -> Fu_1 Chi_5 )
1.25684113E-04 2 2 1000055 # BR(ScL -> Fu_1 Chi_6 )
3.83844330E-03 2 4 1000022 # BR(ScL -> Fu_2 Chi_1 )
3.47321759E-03 2 4 1000023 # BR(ScL -> Fu_2 Chi_2 )
1.05616029E-02 2 4 1000025 # BR(ScL -> Fu_2 Chi_3 )
9.38885928E-02 2 4 1000045 # BR(ScL -> Fu_2 Chi_5 )
8.28416691E-02 2 4 1000055 # BR(ScL -> Fu_2 Chi_6 )
5.91350946E-04 2 6 1000025 # BR(ScL -> Fu_3 Chi_3 )
6.58532850E-04 2 6 1000035 # BR(ScL -> Fu_3 Chi_4 )
1.70680680E-04 2 6 1000045 # BR(ScL -> Fu_3 Chi_5 )
2.46595222E-04 2 6 1000055 # BR(ScL -> Fu_3 Chi_6 )
5.54093975E-04 2 -1000024 1 # BR(ScL -> Cha_1^* Fd_1 )
1.51605914E-02 2 -1000024 3 # BR(ScL -> Cha_1^* Fd_2 )
9.63086655E-03 2 -1000037 1 # BR(ScL -> Cha_2^* Fd_1 )
2.63486315E-01 2 -1000037 3 # BR(ScL -> Cha_2^* Fd_2 )
3.08089267E-03 2 -1000047 1 # BR(ScL -> Cha_3^* Fd_1 )
8.42875960E-02 2 -1000047 3 # BR(ScL -> Cha_3^* Fd_2 )
3.23046393E-04 2 1000021 2 # BR(ScL -> Glu_1 Fu_1 )
2.12925892E-01 2 1000021 4 # BR(ScL -> Glu_1 Fu_2 )
3.43407669E-04 2 1000021 6 # BR(ScL -> Glu_1 Fu_3 )
3.23042045E-04 2 2000021 2 # BR(ScL -> Glu_2 Fu_1 )
2.12915815E-01 2 2000021 4 # BR(ScL -> Glu_2 Fu_2 )
3.45071270E-04 2 2000021 6 # BR(ScL -> Glu_2 Fu_3 )
DECAY 1000006 2.03058234E+02 # St1
# BR NDA ID1 ID2
1.90252367E-02 2 6 1000022 # BR(St1 -> Fu_3 Chi_1 )
5.73816164E-03 2 6 1000023 # BR(St1 -> Fu_3 Chi_2 )
1.36920289E-01 2 6 1000025 # BR(St1 -> Fu_3 Chi_3 )
1.38494385E-01 2 6 1000035 # BR(St1 -> Fu_3 Chi_4 )
3.48113256E-02 2 6 1000045 # BR(St1 -> Fu_3 Chi_5 )
2.17222458E-02 2 6 1000055 # BR(St1 -> Fu_3 Chi_6 )
1.08519174E-04 2 -1000024 3 # BR(St1 -> Cha_1^* Fd_2 )
9.99012489E-02 2 -1000024 5 # BR(St1 -> Cha_1^* Fd_3 )
7.64162349E-02 2 -1000037 5 # BR(St1 -> Cha_2^* Fd_3 )
2.53157900E-03 2 -1000047 5 # BR(St1 -> Cha_3^* Fd_3 )
3.00505589E-04 2 1000021 4 # BR(St1 -> Glu_1 Fu_2 )
2.16075585E-01 2 1000021 6 # BR(St1 -> Glu_1 Fu_3 )
3.00504975E-04 2 2000021 4 # BR(St1 -> Glu_2 Fu_2 )
2.47535172E-01 2 2000021 6 # BR(St1 -> Glu_2 Fu_3 )
DECAY 2000006 2.15936137E+02 # St2
# BR NDA ID1 ID2
1.38336698E-02 2 6 1000022 # BR(St2 -> Fu_3 Chi_1 )
1.41609015E-02 2 6 1000023 # BR(St2 -> Fu_3 Chi_2 )
1.05800432E-01 2 6 1000025 # BR(St2 -> Fu_3 Chi_3 )
1.33912866E-01 2 6 1000035 # BR(St2 -> Fu_3 Chi_4 )
3.44589720E-03 2 6 1000045 # BR(St2 -> Fu_3 Chi_5 )
4.99061203E-02 2 6 1000055 # BR(St2 -> Fu_3 Chi_6 )
3.01206490E-04 2 -1000024 3 # BR(St2 -> Cha_1^* Fd_2 )
1.46049481E-01 2 -1000024 5 # BR(St2 -> Cha_1^* Fd_3 )
2.32024176E-02 2 -1000037 5 # BR(St2 -> Cha_2^* Fd_3 )
6.98153781E-02 2 -1000047 5 # BR(St2 -> Cha_3^* Fd_3 )
2.34434579E-01 2 1000021 6 # BR(St2 -> Glu_1 Fu_3 )
2.04854943E-01 2 2000021 6 # BR(St2 -> Glu_2 Fu_3 )
DECAY 2000015 8.18637837E+00 # Stau2
# BR NDA ID1 ID2
1.02082535E-02 2 16 1000024 # BR(Stau2 -> Fv_3 Cha_1 )
2.29151087E-02 2 16 1000037 # BR(Stau2 -> Fv_3 Cha_2 )
4.80804462E-02 2 16 1000047 # BR(Stau2 -> Fv_3 Cha_3 )
4.48198185E-01 2 15 1000022 # BR(Stau2 -> Fe_3 Chi_1 )
4.20256915E-01 2 15 1000023 # BR(Stau2 -> Fe_3 Chi_2 )
1.30717819E-02 2 15 1000025 # BR(Stau2 -> Fe_3 Chi_3 )
2.29748327E-03 2 15 1000035 # BR(Stau2 -> Fe_3 Chi_4 )
1.98408505E-02 2 15 1000045 # BR(Stau2 -> Fe_3 Chi_5 )
1.51309759E-02 2 15 1000055 # BR(Stau2 -> Fe_3 Chi_6 )
DECAY 2000013 7.57672843E+00 # SmuR
# BR NDA ID1 ID2
1.10283127E-04 2 14 1000037 # BR(SmuR -> Fv_2 Cha_2 )
2.34103666E-04 2 14 1000047 # BR(SmuR -> Fv_2 Cha_3 )
5.11017189E-01 2 13 1000022 # BR(SmuR -> Fe_2 Chi_1 )
4.77934346E-01 2 13 1000023 # BR(SmuR -> Fe_2 Chi_2 )
8.55792644E-03 2 13 1000025 # BR(SmuR -> Fe_2 Chi_3 )
1.27280242E-03 2 13 1000035 # BR(SmuR -> Fe_2 Chi_4 )
1.20848406E-04 2 13 1000045 # BR(SmuR -> Fe_2 Chi_5 )
7.05962644E-04 2 13 1000055 # BR(SmuR -> Fe_2 Chi_6 )
DECAY 2000011 7.57401359E+00 # SeR
# BR NDA ID1 ID2
5.11320380E-01 2 11 1000022 # BR(SeR -> Fe_1 Chi_1 )
4.78213147E-01 2 11 1000023 # BR(SeR -> Fe_1 Chi_2 )
8.53737326E-03 2 11 1000025 # BR(SeR -> Fe_1 Chi_3 )
1.26878456E-03 2 11 1000035 # BR(SeR -> Fe_1 Chi_4 )
6.35148272E-04 2 11 1000055 # BR(SeR -> Fe_1 Chi_6 )
DECAY 1000011 1.59582153E+01 # SeL
# BR NDA ID1 ID2
3.05089932E-02 2 12 1000024 # BR(SeL -> Fv_1 Cha_1 )
1.61927710E-01 2 12 1000037 # BR(SeL -> Fv_1 Cha_2 )
3.93609722E-01 2 12 1000047 # BR(SeL -> Fv_1 Cha_3 )
6.16871294E-02 2 11 1000022 # BR(SeL -> Fe_1 Chi_1 )
5.70346458E-02 2 11 1000023 # BR(SeL -> Fe_1 Chi_2 )
2.41753784E-02 2 11 1000025 # BR(SeL -> Fe_1 Chi_3 )
1.46375070E-01 2 11 1000045 # BR(SeL -> Fe_1 Chi_5 )
1.24665730E-01 2 11 1000055 # BR(SeL -> Fe_1 Chi_6 )
DECAY 1000013 1.59556395E+01 # SmuL
# BR NDA ID1 ID2
3.04944553E-02 2 14 1000024 # BR(SmuL -> Fv_2 Cha_1 )
1.61901499E-01 2 14 1000037 # BR(SmuL -> Fv_2 Cha_2 )
3.93562353E-01 2 14 1000047 # BR(SmuL -> Fv_2 Cha_3 )
6.17540619E-02 2 13 1000022 # BR(SmuL -> Fe_2 Chi_1 )
5.70949416E-02 2 13 1000023 # BR(SmuL -> Fe_2 Chi_2 )
2.41706430E-02 2 13 1000025 # BR(SmuL -> Fe_2 Chi_3 )
1.46353251E-01 2 13 1000045 # BR(SmuL -> Fe_2 Chi_5 )
1.24652421E-01 2 13 1000055 # BR(SmuL -> Fe_2 Chi_6 )
DECAY 1000015 1.53851602E+01 # Stau1
# BR NDA ID1 ID2
2.69864654E-02 2 16 1000024 # BR(Stau1 -> Fv_3 Cha_1 )
1.55771013E-01 2 16 1000037 # BR(Stau1 -> Fv_3 Cha_2 )
3.82761175E-01 2 16 1000047 # BR(Stau1 -> Fv_3 Cha_3 )
7.72204176E-02 2 15 1000022 # BR(Stau1 -> Fe_3 Chi_1 )
7.09821078E-02 2 15 1000023 # BR(Stau1 -> Fe_3 Chi_2 )
2.30782257E-02 2 15 1000025 # BR(Stau1 -> Fe_3 Chi_3 )
2.60881783E-04 2 15 1000035 # BR(Stau1 -> Fe_3 Chi_4 )
1.41280788E-01 2 15 1000045 # BR(Stau1 -> Fe_3 Chi_5 )
1.21658925E-01 2 15 1000055 # BR(Stau1 -> Fe_3 Chi_6 )
DECAY 1000016 1.59625578E+01 # Snu_tau
# BR NDA ID1 ID2
5.97252721E-02 2 16 1000022 # BR(Snu_tau -> Fv_3 Chi_1 )
5.65094684E-02 2 16 1000023 # BR(Snu_tau -> Fv_3 Chi_2 )
8.41222881E-03 2 16 1000025 # BR(Snu_tau -> Fv_3 Chi_3 )
4.23915911E-04 2 16 1000035 # BR(Snu_tau -> Fv_3 Chi_4 )
1.48779922E-01 2 16 1000045 # BR(Snu_tau -> Fv_3 Chi_5 )
1.37001990E-01 2 16 1000055 # BR(Snu_tau -> Fv_3 Chi_6 )
2.74888013E-02 2 -1000024 15 # BR(Snu_tau -> Cha_1^* Fe_3 )
4.26496484E-01 2 -1000037 15 # BR(Snu_tau -> Cha_2^* Fe_3 )
1.35161917E-01 2 -1000047 15 # BR(Snu_tau -> Cha_3^* Fe_3 )
DECAY 1000014 1.59495218E+01 # Snu_mu
# BR NDA ID1 ID2
5.97743685E-02 2 14 1000022 # BR(Snu_mu -> Fv_2 Chi_1 )
5.65559220E-02 2 14 1000023 # BR(Snu_mu -> Fv_2 Chi_2 )
8.41915275E-03 2 14 1000025 # BR(Snu_mu -> Fv_2 Chi_3 )
4.24264889E-04 2 14 1000035 # BR(Snu_mu -> Fv_2 Chi_4 )
1.48902561E-01 2 14 1000045 # BR(Snu_mu -> Fv_2 Chi_5 )
1.37114938E-01 2 14 1000055 # BR(Snu_mu -> Fv_2 Chi_6 )
2.67704071E-02 2 -1000024 13 # BR(Snu_mu -> Cha_1^* Fe_2 )
4.26839277E-01 2 -1000037 13 # BR(Snu_mu -> Cha_2^* Fe_2 )
1.35199109E-01 2 -1000047 13 # BR(Snu_mu -> Cha_3^* Fe_2 )
DECAY 1000012 1.59494755E+01 # Snu_e
# BR NDA ID1 ID2
5.97745429E-02 2 12 1000022 # BR(Snu_e -> Fv_1 Chi_1 )
5.65560870E-02 2 12 1000023 # BR(Snu_e -> Fv_1 Chi_2 )
8.41917735E-03 2 12 1000025 # BR(Snu_e -> Fv_1 Chi_3 )
4.24266128E-04 2 12 1000035 # BR(Snu_e -> Fv_1 Chi_4 )
1.48902996E-01 2 12 1000045 # BR(Snu_e -> Fv_1 Chi_5 )
1.37115339E-01 2 12 1000055 # BR(Snu_e -> Fv_1 Chi_6 )
2.67678554E-02 2 -1000024 11 # BR(Snu_e -> Cha_1^* Fe_1 )
4.26840495E-01 2 -1000037 11 # BR(Snu_e -> Cha_2^* Fe_1 )
1.35199241E-01 2 -1000047 11 # BR(Snu_e -> Cha_3^* Fe_1 )
DECAY 25 2.60608337E-03 # hh_1
# BR NDA ID1 ID2
2.86978983E-03 2 22 22 # BR(hh_1 -> VP VP )
9.04531371E-02 2 21 21 # BR(hh_1 -> VG VG )
2.59876756E-03 2 23 23 # BR(hh_1 -> VZ VZ )
6.15902598E-02 2 24 -24 # BR(hh_1 -> VWm^* VWm_virt )
2.71008356E-04 2 -3 3 # BR(hh_1 -> Fd_2^* Fd_2 )
7.25330946E-01 2 -5 5 # BR(hh_1 -> Fd_3^* Fd_3 )
2.85702684E-04 2 -13 13 # BR(hh_1 -> Fe_2^* Fe_2 )
8.24409370E-02 2 -15 15 # BR(hh_1 -> Fe_3^* Fe_3 )
3.41585478E-02 2 -4 4 # BR(hh_1 -> Fu_2^* Fu_2 )
DECAY 35 3.77797217E+01 # hh_2
# BR NDA ID1 ID2
8.45598278E-03 2 -1000024 1000024 # BR(hh_2 -> Cha_1^* Cha_1 )
6.71494568E-02 2 -1000024 1000037 # BR(hh_2 -> Cha_1^* Cha_2 )
7.44077705E-03 2 -1000024 1000047 # BR(hh_2 -> Cha_1^* Cha_3 )
6.71494568E-02 2 -1000037 1000024 # BR(hh_2 -> Cha_2^* Cha_1 )
9.55151129E-02 2 -1000037 1000037 # BR(hh_2 -> Cha_2^* Cha_2 )
3.20762340E-01 2 -1000037 1000047 # BR(hh_2 -> Cha_2^* Cha_3 )
7.44077705E-03 2 -1000047 1000024 # BR(hh_2 -> Cha_3^* Cha_1 )
3.20762340E-01 2 -1000047 1000037 # BR(hh_2 -> Cha_3^* Cha_2 )
8.61817464E-02 2 -1000047 1000047 # BR(hh_2 -> Cha_3^* Cha_3 )
2.31393153E-04 2 1000022 1000035 # BR(hh_2 -> Chi_1 Chi_4 )
1.17886603E-04 2 1000023 1000025 # BR(hh_2 -> Chi_2 Chi_3 )
2.55792751E-03 2 1000025 1000025 # BR(hh_2 -> Chi_3 Chi_3 )
4.57949794E-04 2 1000025 1000055 # BR(hh_2 -> Chi_3 Chi_6 )
2.87808808E-03 2 1000035 1000035 # BR(hh_2 -> Chi_4 Chi_4 )
3.05668847E-03 2 25 25 # BR(hh_2 -> hh_1 hh_1 )
2.19600919E-04 2 -37 24 # BR(hh_2 -> Hpm_2 VWm^* )
2.19600919E-04 2 37 -24 # BR(hh_2 -> Hpm_2^* VWm )
6.58474058E-03 2 -24 24 # BR(hh_2 -> VWm VWm^* )
2.51058832E-03 2 23 23 # BR(hh_2 -> VZ VZ )
DECAY 45 1.64301934E+01 # hh_3
# BR NDA ID1 ID2
1.87765619E-01 2 -1000024 1000024 # BR(hh_3 -> Cha_1^* Cha_1 )
6.68696470E-04 2 -1000024 1000037 # BR(hh_3 -> Cha_1^* Cha_2 )
2.55136087E-02 2 -1000024 1000047 # BR(hh_3 -> Cha_1^* Cha_3 )
6.68696470E-04 2 -1000037 1000024 # BR(hh_3 -> Cha_2^* Cha_1 )
3.85047780E-04 2 -1000037 1000047 # BR(hh_3 -> Cha_2^* Cha_3 )
2.55136087E-02 2 -1000047 1000024 # BR(hh_3 -> Cha_3^* Cha_1 )
3.85047780E-04 2 -1000047 1000037 # BR(hh_3 -> Cha_3^* Cha_2 )
2.57900062E-03 2 -1000047 1000047 # BR(hh_3 -> Cha_3^* Cha_3 )
9.93238205E-02 2 1000022 1000022 # BR(hh_3 -> Chi_1 Chi_1 )
2.23541648E-01 2 1000022 1000023 # BR(hh_3 -> Chi_1 Chi_2 )
1.14728941E-03 2 1000022 1000025 # BR(hh_3 -> Chi_1 Chi_3 )
2.56382899E-02 2 1000022 1000035 # BR(hh_3 -> Chi_1 Chi_4 )
1.19516214E-04 2 1000022 1000055 # BR(hh_3 -> Chi_1 Chi_6 )
1.21944418E-01 2 1000023 1000023 # BR(hh_3 -> Chi_2 Chi_2 )
1.17102101E-03 2 1000023 1000025 # BR(hh_3 -> Chi_2 Chi_3 )
1.89007687E-02 2 1000023 1000035 # BR(hh_3 -> Chi_2 Chi_4 )
1.99492107E-04 2 1000023 1000055 # BR(hh_3 -> Chi_2 Chi_6 )
9.19728358E-02 2 1000025 1000025 # BR(hh_3 -> Chi_3 Chi_3 )
7.12009061E-04 2 1000025 1000045 # BR(hh_3 -> Chi_3 Chi_5 )
2.56553281E-02 2 1000025 1000055 # BR(hh_3 -> Chi_3 Chi_6 )
1.07552795E-01 2 1000035 1000035 # BR(hh_3 -> Chi_4 Chi_4 )
8.21290960E-04 2 1000035 1000045 # BR(hh_3 -> Chi_4 Chi_5 )
1.13746956E-04 2 1000035 1000055 # BR(hh_3 -> Chi_4 Chi_6 )
1.74869938E-03 2 1000055 1000055 # BR(hh_3 -> Chi_6 Chi_6 )
8.11061350E-04 2 -6 6 # BR(hh_3 -> Fu_3^* Fu_3 )
5.63680422E-03 2 25 25 # BR(hh_3 -> hh_1 hh_1 )
3.36216026E-03 2 -47 24 # BR(hh_3 -> Hpm_3 VWm^* )
3.36216026E-03 2 47 -24 # BR(hh_3 -> Hpm_3^* VWm )
1.55969116E-02 2 -24 24 # BR(hh_3 -> VWm VWm^* )
7.02545758E-03 2 23 23 # BR(hh_3 -> VZ VZ )
DECAY 55 7.24470333E+01 # hh_4
# BR NDA ID1 ID2
1.80436469E-04 2 21 21 # BR(hh_4 -> VG VG )
6.72715118E-03 2 -1000024 1000024 # BR(hh_4 -> Cha_1^* Cha_1 )
7.78615271E-02 2 -1000024 1000037 # BR(hh_4 -> Cha_1^* Cha_2 )
5.45990415E-02 2 -1000024 1000047 # BR(hh_4 -> Cha_1^* Cha_3 )
7.78615271E-02 2 -1000037 1000024 # BR(hh_4 -> Cha_2^* Cha_1 )
1.58028595E-03 2 -1000037 1000037 # BR(hh_4 -> Cha_2^* Cha_2 )
1.38950578E-02 2 -1000037 1000047 # BR(hh_4 -> Cha_2^* Cha_3 )
5.45990415E-02 2 -1000047 1000024 # BR(hh_4 -> Cha_3^* Cha_1 )
1.38950578E-02 2 -1000047 1000037 # BR(hh_4 -> Cha_3^* Cha_2 )
3.20750179E-04 2 -1000047 1000047 # BR(hh_4 -> Cha_3^* Cha_3 )
2.65908542E-03 2 1000022 1000022 # BR(hh_4 -> Chi_1 Chi_1 )
2.10728091E-04 2 1000022 1000023 # BR(hh_4 -> Chi_1 Chi_2 )
1.59057665E-02 2 1000022 1000025 # BR(hh_4 -> Chi_1 Chi_3 )
3.65560772E-02 2 1000022 1000035 # BR(hh_4 -> Chi_1 Chi_4 )
2.62285628E-03 2 1000022 1000045 # BR(hh_4 -> Chi_1 Chi_5 )
1.00341483E-03 2 1000022 1000055 # BR(hh_4 -> Chi_1 Chi_6 )
1.06720635E-03 2 1000023 1000023 # BR(hh_4 -> Chi_2 Chi_2 )
5.04556364E-02 2 1000023 1000025 # BR(hh_4 -> Chi_2 Chi_3 )
6.21804350E-03 2 1000023 1000035 # BR(hh_4 -> Chi_2 Chi_4 )
1.26139071E-03 2 1000023 1000045 # BR(hh_4 -> Chi_2 Chi_5 )
2.64462273E-03 2 1000023 1000055 # BR(hh_4 -> Chi_2 Chi_6 )
2.61638644E-03 2 1000025 1000025 # BR(hh_4 -> Chi_3 Chi_3 )
3.25142244E-04 2 1000025 1000035 # BR(hh_4 -> Chi_3 Chi_4 )
1.19802745E-03 2 1000025 1000045 # BR(hh_4 -> Chi_3 Chi_5 )
1.19719364E-02 2 1000025 1000055 # BR(hh_4 -> Chi_3 Chi_6 )
1.49482537E-03 2 1000035 1000035 # BR(hh_4 -> Chi_4 Chi_4 )
6.75899037E-02 2 1000035 1000045 # BR(hh_4 -> Chi_4 Chi_5 )
6.41720594E-02 2 1000035 1000055 # BR(hh_4 -> Chi_4 Chi_6 )
2.62519188E-04 2 1000045 1000045 # BR(hh_4 -> Chi_5 Chi_5 )
2.92211036E-03 2 1000055 1000055 # BR(hh_4 -> Chi_6 Chi_6 )
1.68985080E-03 2 -5 5 # BR(hh_4 -> Fd_3^* Fd_3 )
3.05340952E-04 2 -15 15 # BR(hh_4 -> Fe_3^* Fe_3 )
4.10260950E-01 2 -6 6 # BR(hh_4 -> Fu_3^* Fu_3 )
3.83820617E-03 2 25 35 # BR(hh_4 -> hh_1 hh_2 )
1.09245783E-04 2 25 45 # BR(hh_4 -> hh_1 hh_3 )
4.41289187E-03 2 -47 24 # BR(hh_4 -> Hpm_3 VWm^* )
4.41289187E-03 2 47 -24 # BR(hh_4 -> Hpm_3^* VWm )
DECAY 36 5.29711210E-04 # Ah_2
# BR NDA ID1 ID2
6.99960291E-04 2 22 22 # BR(Ah_2 -> VP VP )
1.35862885E-02 2 1000022 1000022 # BR(Ah_2 -> Chi_1 Chi_1 )
2.61526519E-02 2 1000022 1000023 # BR(Ah_2 -> Chi_1 Chi_2 )
2.90565589E-02 2 1000022 1000025 # BR(Ah_2 -> Chi_1 Chi_3 )
6.40558757E-01 2 1000022 1000035 # BR(Ah_2 -> Chi_1 Chi_4 )
2.82543229E-01 2 1000023 1000025 # BR(Ah_2 -> Chi_2 Chi_3 )
7.30598163E-03 2 1000023 1000035 # BR(Ah_2 -> Chi_2 Chi_4 )
DECAY 46 2.03000616E+01 # Ah_3
# BR NDA ID1 ID2
2.09299143E-01 2 -1000024 1000024 # BR(Ah_3 -> Cha_1^* Cha_1 )
1.02824803E-03 2 -1000024 1000037 # BR(Ah_3 -> Cha_1^* Cha_2 )
2.90959205E-02 2 -1000024 1000047 # BR(Ah_3 -> Cha_1^* Cha_3 )
1.02824803E-03 2 -1000037 1000024 # BR(Ah_3 -> Cha_2^* Cha_1 )
1.72933389E-04 2 -1000037 1000047 # BR(Ah_3 -> Cha_2^* Cha_3 )
2.90959205E-02 2 -1000047 1000024 # BR(Ah_3 -> Cha_3^* Cha_1 )
1.72933389E-04 2 -1000047 1000037 # BR(Ah_3 -> Cha_3^* Cha_2 )
3.81401895E-03 2 -1000047 1000047 # BR(Ah_3 -> Cha_3^* Cha_3 )
9.79675901E-02 2 1000022 1000022 # BR(Ah_3 -> Chi_1 Chi_1 )
2.06916857E-01 2 1000022 1000023 # BR(Ah_3 -> Chi_1 Chi_2 )
1.38371279E-03 2 1000022 1000025 # BR(Ah_3 -> Chi_1 Chi_3 )
2.58857986E-02 2 1000022 1000035 # BR(Ah_3 -> Chi_1 Chi_4 )
1.31039613E-04 2 1000022 1000055 # BR(Ah_3 -> Chi_1 Chi_6 )
1.19323172E-01 2 1000023 1000023 # BR(Ah_3 -> Chi_2 Chi_2 )
1.03066959E-03 2 1000023 1000025 # BR(Ah_3 -> Chi_2 Chi_3 )
1.82818962E-02 2 1000023 1000035 # BR(Ah_3 -> Chi_2 Chi_4 )
1.98748856E-04 2 1000023 1000055 # BR(Ah_3 -> Chi_2 Chi_6 )
1.01278976E-01 2 1000025 1000025 # BR(Ah_3 -> Chi_3 Chi_3 )
7.78913984E-04 2 1000025 1000045 # BR(Ah_3 -> Chi_3 Chi_5 )
2.96937773E-02 2 1000025 1000055 # BR(Ah_3 -> Chi_3 Chi_6 )
1.20144299E-01 2 1000035 1000035 # BR(Ah_3 -> Chi_4 Chi_4 )
7.00544945E-04 2 1000035 1000045 # BR(Ah_3 -> Chi_4 Chi_5 )
2.27273690E-04 2 1000035 1000055 # BR(Ah_3 -> Chi_4 Chi_6 )
2.15026684E-03 2 1000055 1000055 # BR(Ah_3 -> Chi_6 Chi_6 )
DECAY 56 7.26526228E+01 # Ah_4
# BR NDA ID1 ID2
2.12373184E-04 2 21 21 # BR(Ah_4 -> VG VG )
1.93134007E-02 2 -1000024 1000024 # BR(Ah_4 -> Cha_1^* Cha_1 )
8.38046792E-02 2 -1000024 1000037 # BR(Ah_4 -> Cha_1^* Cha_2 )
3.78941216E-02 2 -1000024 1000047 # BR(Ah_4 -> Cha_1^* Cha_3 )
8.38046792E-02 2 -1000037 1000024 # BR(Ah_4 -> Cha_2^* Cha_1 )
1.58761401E-03 2 -1000037 1000037 # BR(Ah_4 -> Cha_2^* Cha_2 )
7.65909750E-03 2 -1000037 1000047 # BR(Ah_4 -> Cha_2^* Cha_3 )
3.78941216E-02 2 -1000047 1000024 # BR(Ah_4 -> Cha_3^* Cha_1 )
7.65909750E-03 2 -1000047 1000037 # BR(Ah_4 -> Cha_3^* Cha_2 )
2.15223170E-02 2 -1000047 1000047 # BR(Ah_4 -> Cha_3^* Cha_3 )
1.96077745E-03 2 1000022 1000022 # BR(Ah_4 -> Chi_1 Chi_1 )
4.07225916E-04 2 1000022 1000023 # BR(Ah_4 -> Chi_1 Chi_2 )
3.38369103E-02 2 1000022 1000025 # BR(Ah_4 -> Chi_1 Chi_3 )
1.52041971E-02 2 1000022 1000035 # BR(Ah_4 -> Chi_1 Chi_4 )
1.15720254E-03 2 1000022 1000045 # BR(Ah_4 -> Chi_1 Chi_5 )
5.73273219E-03 2 1000022 1000055 # BR(Ah_4 -> Chi_1 Chi_6 )
1.23948096E-03 2 1000023 1000023 # BR(Ah_4 -> Chi_2 Chi_2 )
6.76364989E-03 2 1000023 1000025 # BR(Ah_4 -> Chi_2 Chi_3 )
5.27740197E-02 2 1000023 1000035 # BR(Ah_4 -> Chi_2 Chi_4 )
2.63000331E-04 2 1000023 1000045 # BR(Ah_4 -> Chi_2 Chi_5 )
5.09170275E-03 2 1000025 1000025 # BR(Ah_4 -> Chi_3 Chi_3 )
4.06870808E-03 2 1000025 1000035 # BR(Ah_4 -> Chi_3 Chi_4 )
6.20668962E-02 2 1000025 1000045 # BR(Ah_4 -> Chi_3 Chi_5 )
4.25333886E-02 2 1000025 1000055 # BR(Ah_4 -> Chi_3 Chi_6 )
2.88505628E-03 2 1000035 1000035 # BR(Ah_4 -> Chi_4 Chi_4 )
1.58943033E-03 2 1000035 1000045 # BR(Ah_4 -> Chi_4 Chi_5 )
1.36883504E-02 2 1000035 1000055 # BR(Ah_4 -> Chi_4 Chi_6 )
4.74665734E-04 2 1000045 1000045 # BR(Ah_4 -> Chi_5 Chi_5 )
7.23114429E-03 2 1000045 1000055 # BR(Ah_4 -> Chi_5 Chi_6 )
1.33426013E-02 2 1000055 1000055 # BR(Ah_4 -> Chi_6 Chi_6 )
1.68631039E-03 2 -5 5 # BR(Ah_4 -> Fd_3^* Fd_3 )
3.04700093E-04 2 -15 15 # BR(Ah_4 -> Fe_3^* Fe_3 )
4.12536789E-01 2 -6 6 # BR(Ah_4 -> Fu_3^* Fu_3 )
3.84449510E-03 2 35 23 # BR(Ah_4 -> hh_2 VZ )
1.59796816E-04 2 45 23 # BR(Ah_4 -> hh_3 VZ )
3.84427784E-03 2 -47 24 # BR(Ah_4 -> Hpm_3 VWm^* )
3.84427784E-03 2 47 -24 # BR(Ah_4 -> Hpm_3^* VWm )
DECAY 37 1.36693932E-04 # Hpm_2
# BR NDA ID1 ID2
6.69694532E-01 2 1000022 -1000024 # BR(Hpm_2^* -> Chi_1 Cha_1^* )
3.30194817E-01 2 1000023 -1000024 # BR(Hpm_2^* -> Chi_2 Cha_1^* )
DECAY 47 3.38534161E+01 # Hpm_3
# BR NDA ID1 ID2
2.10542545E-04 2 36 24 # BR(Hpm_3^* -> Ah_2 VWm^* )
4.40014697E-04 2 1000022 -1000024 # BR(Hpm_3^* -> Chi_1 Cha_1^* )
1.79361278E-04 2 1000023 -1000024 # BR(Hpm_3^* -> Chi_2 Cha_1^* )
7.34235883E-03 2 1000025 -1000024 # BR(Hpm_3^* -> Chi_3 Cha_1^* )
7.31221364E-02 2 1000025 -1000037 # BR(Hpm_3^* -> Chi_3 Cha_2^* )
5.14655769E-03 2 1000025 -1000047 # BR(Hpm_3^* -> Chi_3 Cha_3^* )
8.32020261E-03 2 1000035 -1000024 # BR(Hpm_3^* -> Chi_4 Cha_1^* )
8.28171807E-04 2 1000035 -1000037 # BR(Hpm_3^* -> Chi_4 Cha_2^* )
7.07121324E-02 2 1000045 -1000024 # BR(Hpm_3^* -> Chi_5 Cha_1^* )
2.53180862E-02 2 1000045 -1000037 # BR(Hpm_3^* -> Chi_5 Cha_2^* )
3.86458168E-01 2 1000045 -1000047 # BR(Hpm_3^* -> Chi_5 Cha_3^* )
3.43771683E-03 2 1000055 -1000024 # BR(Hpm_3^* -> Chi_6 Cha_1^* )
3.84537585E-01 2 1000055 -1000037 # BR(Hpm_3^* -> Chi_6 Cha_2^* )
2.38158813E-02 2 1000055 -1000047 # BR(Hpm_3^* -> Chi_6 Cha_3^* )
2.29535907E-04 2 37 25 # BR(Hpm_3^* -> Hpm_2^* hh_1 )
4.30473908E-03 2 25 24 # BR(Hpm_3^* -> hh_1 VWm^* )
5.33109873E-03 2 24 23 # BR(Hpm_3^* -> VWm^* VZ )
DECAY 57 6.66892839E+01 # Hpm_4
# BR NDA ID1 ID2
5.60665880E-02 2 1000022 -1000024 # BR(Hpm_4^* -> Chi_1 Cha_1^* )
1.44831690E-03 2 1000022 -1000037 # BR(Hpm_4^* -> Chi_1 Cha_2^* )
9.45142752E-03 2 1000022 -1000047 # BR(Hpm_4^* -> Chi_1 Cha_3^* )
6.41265638E-02 2 1000023 -1000024 # BR(Hpm_4^* -> Chi_2 Cha_1^* )
2.04607612E-03 2 1000023 -1000037 # BR(Hpm_4^* -> Chi_2 Cha_2^* )
2.45773434E-03 2 1000023 -1000047 # BR(Hpm_4^* -> Chi_2 Cha_3^* )
6.76686199E-04 2 1000025 -1000024 # BR(Hpm_4^* -> Chi_3 Cha_1^* )
4.01671960E-02 2 1000025 -1000037 # BR(Hpm_4^* -> Chi_3 Cha_2^* )
9.79354482E-02 2 1000025 -1000047 # BR(Hpm_4^* -> Chi_3 Cha_3^* )
5.34224760E-03 2 1000035 -1000024 # BR(Hpm_4^* -> Chi_4 Cha_1^* )
4.96763558E-02 2 1000035 -1000037 # BR(Hpm_4^* -> Chi_4 Cha_2^* )
9.24950745E-02 2 1000035 -1000047 # BR(Hpm_4^* -> Chi_4 Cha_3^* )
5.96269486E-02 2 1000045 -1000024 # BR(Hpm_4^* -> Chi_5 Cha_1^* )
8.21769809E-04 2 1000045 -1000037 # BR(Hpm_4^* -> Chi_5 Cha_2^* )
1.04995653E-02 2 1000045 -1000047 # BR(Hpm_4^* -> Chi_5 Cha_3^* )
7.34050172E-02 2 1000055 -1000024 # BR(Hpm_4^* -> Chi_6 Cha_1^* )
1.12640370E-02 2 1000055 -1000037 # BR(Hpm_4^* -> Chi_6 Cha_2^* )
7.95604403E-04 2 1000055 -1000047 # BR(Hpm_4^* -> Chi_6 Cha_3^* )
7.02009731E-04 2 6 -3 # BR(Hpm_4^* -> Fu_3 Fd_2^* )
4.09256696E-01 2 6 -5 # BR(Hpm_4^* -> Fu_3 Fd_3^* )
3.31854096E-04 2 16 -15 # BR(Hpm_4^* -> Fv_3 Fe_3^* )
3.81863762E-03 2 47 25 # BR(Hpm_4^* -> Hpm_3^* hh_1 )
3.47300847E-03 2 35 24 # BR(Hpm_4^* -> hh_2 VWm^* )
1.51697801E-04 2 45 24 # BR(Hpm_4^* -> hh_3 VWm^* )
3.76083027E-03 2 47 23 # BR(Hpm_4^* -> Hpm_3^* VZ )
DECAY 3000021 0.00000000E+00 # phiO
# BR NDA ID1 ID2
DECAY 3000022 0.00000000E+00 # sigmaO
# BR NDA ID1 ID2
DECAY 1000021 1.92937222E-02 # Glu_1
# BR NDA ID1 ID2
# BR NDA ID1 ID2 ID3
6.30857643E-04 3 1 -1 1000022 # BR(Glu_1 -> Fd_1 Fd_1^* Chi_1 )
1.11409288E-02 3 1 -1 1000023 # BR(Glu_1 -> Fd_1 Fd_1^* Chi_2 )
1.61290540E-03 3 1 -1 1000025 # BR(Glu_1 -> Fd_1 Fd_1^* Chi_3 )
2.43608051E-02 3 1 -1 1000045 # BR(Glu_1 -> Fd_1 Fd_1^* Chi_5 )
2.25006935E-02 3 1 -1 1000055 # BR(Glu_1 -> Fd_1 Fd_1^* Chi_6 )
1.42093236E-04 3 1 -3 1000022 # BR(Glu_1 -> Fd_1 Fd_2^* Chi_1 )
1.37517809E-04 3 1 -3 1000023 # BR(Glu_1 -> Fd_1 Fd_2^* Chi_2 )
2.63733872E-04 3 1 -3 1000025 # BR(Glu_1 -> Fd_1 Fd_2^* Chi_3 )
2.88243995E-03 3 1 -3 1000045 # BR(Glu_1 -> Fd_1 Fd_2^* Chi_5 )
2.57332565E-03 3 1 -3 1000055 # BR(Glu_1 -> Fd_1 Fd_2^* Chi_6 )
1.42093236E-04 3 3 -1 1000022 # BR(Glu_1 -> Fd_2 Fd_1^* Chi_1 )
1.37517809E-04 3 3 -1 1000023 # BR(Glu_1 -> Fd_2 Fd_1^* Chi_2 )
2.63733872E-04 3 3 -1 1000025 # BR(Glu_1 -> Fd_2 Fd_1^* Chi_3 )
2.88243995E-03 3 3 -1 1000045 # BR(Glu_1 -> Fd_2 Fd_1^* Chi_5 )
2.57332565E-03 3 3 -1 1000055 # BR(Glu_1 -> Fd_2 Fd_1^* Chi_6 )
6.30902788E-04 3 3 -3 1000022 # BR(Glu_1 -> Fd_2 Fd_2^* Chi_1 )
1.11408614E-02 3 3 -3 1000023 # BR(Glu_1 -> Fd_2 Fd_2^* Chi_2 )
1.61315629E-03 3 3 -3 1000025 # BR(Glu_1 -> Fd_2 Fd_2^* Chi_3 )
2.43604009E-02 3 3 -3 1000045 # BR(Glu_1 -> Fd_2 Fd_2^* Chi_5 )
2.25003071E-02 3 3 -3 1000055 # BR(Glu_1 -> Fd_2 Fd_2^* Chi_6 )
6.85392504E-04 3 5 -5 1000022 # BR(Glu_1 -> Fd_3 Fd_3^* Chi_1 )
1.44537818E-03 3 5 -5 1000023 # BR(Glu_1 -> Fd_3 Fd_3^* Chi_2 )
6.25693411E-04 3 5 -5 1000025 # BR(Glu_1 -> Fd_3 Fd_3^* Chi_3 )
4.64951484E-03 3 5 -5 1000045 # BR(Glu_1 -> Fd_3 Fd_3^* Chi_5 )
4.09207105E-03 3 5 -5 1000055 # BR(Glu_1 -> Fd_3 Fd_3^* Chi_6 )
5.38011076E-03 3 1 -2 -1000024 # BR(Glu_1 -> Fd_1 Fu_1^* Cha_1^* )
5.38011076E-03 3 -1 2 1000024 # BR(Glu_1 -> Fd_1^* Fu_1 Cha_1 )
5.23748339E-02 3 1 -2 -1000037 # BR(Glu_1 -> Fd_1 Fu_1^* Cha_2^* )
5.23748339E-02 3 -1 2 1000037 # BR(Glu_1 -> Fd_1^* Fu_1 Cha_2 )
4.62721543E-02 3 1 -2 -1000047 # BR(Glu_1 -> Fd_1 Fu_1^* Cha_3^* )
4.62721543E-02 3 -1 2 1000047 # BR(Glu_1 -> Fd_1^* Fu_1 Cha_3 )
2.63827651E-04 3 1 -4 -1000024 # BR(Glu_1 -> Fd_1 Fu_2^* Cha_1^* )
2.63827651E-04 3 -1 4 1000024 # BR(Glu_1 -> Fd_1^* Fu_2 Cha_1 )
2.28610300E-03 3 1 -4 -1000037 # BR(Glu_1 -> Fd_1 Fu_2^* Cha_2^* )
2.28610300E-03 3 -1 4 1000037 # BR(Glu_1 -> Fd_1^* Fu_2 Cha_2 )
2.47250604E-03 3 1 -4 -1000047 # BR(Glu_1 -> Fd_1 Fu_2^* Cha_3^* )
2.47250604E-03 3 -1 4 1000047 # BR(Glu_1 -> Fd_1^* Fu_2 Cha_3 )
2.64058500E-04 3 3 -2 -1000024 # BR(Glu_1 -> Fd_2 Fu_1^* Cha_1^* )
2.64058500E-04 3 -3 2 1000024 # BR(Glu_1 -> Fd_2^* Fu_1 Cha_1 )
2.28973398E-03 3 3 -2 -1000037 # BR(Glu_1 -> Fd_2 Fu_1^* Cha_2^* )
2.28973398E-03 3 -3 2 1000037 # BR(Glu_1 -> Fd_2^* Fu_1 Cha_2 )
2.47672238E-03 3 3 -2 -1000047 # BR(Glu_1 -> Fd_2 Fu_1^* Cha_3^* )
2.47672238E-03 3 -3 2 1000047 # BR(Glu_1 -> Fd_2^* Fu_1 Cha_3 )
5.37689252E-03 3 3 -4 -1000024 # BR(Glu_1 -> Fd_2 Fu_2^* Cha_1^* )
5.37689252E-03 3 -3 4 1000024 # BR(Glu_1 -> Fd_2^* Fu_2 Cha_1 )
5.22824319E-02 3 3 -4 -1000037 # BR(Glu_1 -> Fd_2 Fu_2^* Cha_2^* )
5.22824319E-02 3 -3 4 1000037 # BR(Glu_1 -> Fd_2^* Fu_2 Cha_2 )
4.61919684E-02 3 3 -4 -1000047 # BR(Glu_1 -> Fd_2 Fu_2^* Cha_3^* )
4.61919684E-02 3 -3 4 1000047 # BR(Glu_1 -> Fd_2^* Fu_2 Cha_3 )
2.07598244E-04 3 3 -6 -1000024 # BR(Glu_1 -> Fd_2 Fu_3^* Cha_1^* )
2.07598244E-04 3 -3 6 1000024 # BR(Glu_1 -> Fd_2^* Fu_3 Cha_1 )
8.06455716E-05 3 3 -6 -1000037 # BR(Glu_1 -> Fd_2 Fu_3^* Cha_2^* )
8.06455716E-05 3 -3 6 1000037 # BR(Glu_1 -> Fd_2^* Fu_3 Cha_2 )
1.12970903E-04 3 3 -6 -1000047 # BR(Glu_1 -> Fd_2 Fu_3^* Cha_3^* )
1.12970903E-04 3 -3 6 1000047 # BR(Glu_1 -> Fd_2^* Fu_3 Cha_3 )
4.03782180E-02 3 5 -6 -1000024 # BR(Glu_1 -> Fd_3 Fu_3^* Cha_1^* )
4.03782180E-02 3 -5 6 1000024 # BR(Glu_1 -> Fd_3^* Fu_3 Cha_1 )
9.33173025E-03 3 5 -6 -1000037 # BR(Glu_1 -> Fd_3 Fu_3^* Cha_2^* )
9.33173025E-03 3 -5 6 1000037 # BR(Glu_1 -> Fd_3^* Fu_3 Cha_2 )
8.49248506E-03 3 5 -6 -1000047 # BR(Glu_1 -> Fd_3 Fu_3^* Cha_3^* )
8.49248506E-03 3 -5 6 1000047 # BR(Glu_1 -> Fd_3^* Fu_3 Cha_3 )
3.78057014E-02 3 2 -2 1000022 # BR(Glu_1 -> Fu_1 Fu_1^* Chi_1 )
1.35880286E-02 3 2 -2 1000023 # BR(Glu_1 -> Fu_1 Fu_1^* Chi_2 )
2.17498511E-03 3 2 -2 1000025 # BR(Glu_1 -> Fu_1 Fu_1^* Chi_3 )
2.68200061E-02 3 2 -2 1000045 # BR(Glu_1 -> Fu_1 Fu_1^* Chi_5 )
2.48164883E-02 3 2 -2 1000055 # BR(Glu_1 -> Fu_1 Fu_1^* Chi_6 )
3.77877069E-02 3 4 -4 1000022 # BR(Glu_1 -> Fu_2 Fu_2^* Chi_1 )
1.35941138E-02 3 4 -4 1000023 # BR(Glu_1 -> Fu_2 Fu_2^* Chi_2 )
2.17596081E-03 3 4 -4 1000025 # BR(Glu_1 -> Fu_2 Fu_2^* Chi_3 )
2.67247743E-02 3 4 -4 1000045 # BR(Glu_1 -> Fu_2 Fu_2^* Chi_5 )
2.47327970E-02 3 4 -4 1000055 # BR(Glu_1 -> Fu_2 Fu_2^* Chi_6 )
1.11450085E-04 3 4 -6 1000025 # BR(Glu_1 -> Fu_2 Fu_3^* Chi_3 )
1.21500633E-04 3 4 -6 1000035 # BR(Glu_1 -> Fu_2 Fu_3^* Chi_4 )
1.11450085E-04 3 6 -4 1000025 # BR(Glu_1 -> Fu_3 Fu_2^* Chi_3 )
1.21500633E-04 3 6 -4 1000035 # BR(Glu_1 -> Fu_3 Fu_2^* Chi_4 )
2.60488941E-03 3 6 -6 1000022 # BR(Glu_1 -> Fu_3 Fu_3^* Chi_1 )
2.91909121E-03 3 6 -6 1000023 # BR(Glu_1 -> Fu_3 Fu_3^* Chi_2 )
5.63667795E-02 3 6 -6 1000025 # BR(Glu_1 -> Fu_3 Fu_3^* Chi_3 )
1.00414588E-02 3 6 -6 1000035 # BR(Glu_1 -> Fu_3 Fu_3^* Chi_4 )
5.77988388E-03 3 6 -6 1000045 # BR(Glu_1 -> Fu_3 Fu_3^* Chi_5 )
1.37557830E-02 3 6 -6 1000055 # BR(Glu_1 -> Fu_3 Fu_3^* Chi_6 )
DECAY 2000021 1.95980411E-02 # Glu_2
# BR NDA ID1 ID2
# BR NDA ID1 ID2 ID3
1.16236637E-02 3 1 -1 1000022 # BR(Glu_2 -> Fd_1 Fd_1^* Chi_1 )
5.05154398E-04 3 1 -1 1000023 # BR(Glu_2 -> Fd_1 Fd_1^* Chi_2 )
3.46179371E-03 3 1 -1 1000025 # BR(Glu_2 -> Fd_1 Fd_1^* Chi_3 )
2.43096161E-02 3 1 -1 1000045 # BR(Glu_2 -> Fd_1 Fd_1^* Chi_5 )
2.06056771E-02 3 1 -1 1000055 # BR(Glu_2 -> Fd_1 Fd_1^* Chi_6 )
1.39889588E-04 3 1 -3 1000022 # BR(Glu_2 -> Fd_1 Fd_2^* Chi_1 )
1.35385325E-04 3 1 -3 1000023 # BR(Glu_2 -> Fd_1 Fd_2^* Chi_2 )
2.59643858E-04 3 1 -3 1000025 # BR(Glu_2 -> Fd_1 Fd_2^* Chi_3 )
2.83774779E-03 3 1 -3 1000045 # BR(Glu_2 -> Fd_1 Fd_2^* Chi_5 )
2.53342710E-03 3 1 -3 1000055 # BR(Glu_2 -> Fd_1 Fd_2^* Chi_6 )
1.39889588E-04 3 3 -1 1000022 # BR(Glu_2 -> Fd_2 Fd_1^* Chi_1 )
1.35385325E-04 3 3 -1 1000023 # BR(Glu_2 -> Fd_2 Fd_1^* Chi_2 )
2.59643858E-04 3 3 -1 1000025 # BR(Glu_2 -> Fd_2 Fd_1^* Chi_3 )
2.83774779E-03 3 3 -1 1000045 # BR(Glu_2 -> Fd_2 Fd_1^* Chi_5 )
2.53342710E-03 3 3 -1 1000055 # BR(Glu_2 -> Fd_2 Fd_1^* Chi_6 )
1.16235908E-02 3 3 -3 1000022 # BR(Glu_2 -> Fd_2 Fd_2^* Chi_1 )
5.05201076E-04 3 3 -3 1000023 # BR(Glu_2 -> Fd_2 Fd_2^* Chi_2 )
3.46165769E-03 3 3 -3 1000025 # BR(Glu_2 -> Fd_2 Fd_2^* Chi_3 )
2.43092504E-02 3 3 -3 1000045 # BR(Glu_2 -> Fd_2 Fd_2^* Chi_5 )
2.06053870E-02 3 3 -3 1000055 # BR(Glu_2 -> Fd_2 Fd_2^* Chi_6 )
1.51962485E-03 3 5 -5 1000022 # BR(Glu_2 -> Fd_3 Fd_3^* Chi_1 )
6.36970026E-04 3 5 -5 1000023 # BR(Glu_2 -> Fd_3 Fd_3^* Chi_2 )
4.56937909E-04 3 5 -5 1000025 # BR(Glu_2 -> Fd_3 Fd_3^* Chi_3 )
1.01098746E-04 3 5 -5 1000035 # BR(Glu_2 -> Fd_3 Fd_3^* Chi_4 )
4.66961323E-03 3 5 -5 1000045 # BR(Glu_2 -> Fd_3 Fd_3^* Chi_5 )
4.14685651E-03 3 5 -5 1000055 # BR(Glu_2 -> Fd_3 Fd_3^* Chi_6 )
5.29668239E-03 3 1 -2 -1000024 # BR(Glu_2 -> Fd_1 Fu_1^* Cha_1^* )
5.29668239E-03 3 -1 2 1000024 # BR(Glu_2 -> Fd_1^* Fu_1 Cha_1 )
5.15627350E-02 3 1 -2 -1000037 # BR(Glu_2 -> Fd_1 Fu_1^* Cha_2^* )
5.15627350E-02 3 -1 2 1000037 # BR(Glu_2 -> Fd_1^* Fu_1 Cha_2 )
4.55546867E-02 3 1 -2 -1000047 # BR(Glu_2 -> Fd_1 Fu_1^* Cha_3^* )
4.55546867E-02 3 -1 2 1000047 # BR(Glu_2 -> Fd_1^* Fu_1 Cha_3 )
2.59730044E-04 3 1 -4 -1000024 # BR(Glu_2 -> Fd_1 Fu_2^* Cha_1^* )
2.59730044E-04 3 -1 4 1000024 # BR(Glu_2 -> Fd_1^* Fu_2 Cha_1 )
2.25074134E-03 3 1 -4 -1000037 # BR(Glu_2 -> Fd_1 Fu_2^* Cha_2^* )
2.25074134E-03 3 -1 4 1000037 # BR(Glu_2 -> Fd_1^* Fu_2 Cha_2 )
2.43419771E-03 3 1 -4 -1000047 # BR(Glu_2 -> Fd_1 Fu_2^* Cha_3^* )
2.43419771E-03 3 -1 4 1000047 # BR(Glu_2 -> Fd_1^* Fu_2 Cha_3 )
2.59963529E-04 3 3 -2 -1000024 # BR(Glu_2 -> Fd_2 Fu_1^* Cha_1^* )
2.59963529E-04 3 -3 2 1000024 # BR(Glu_2 -> Fd_2^* Fu_1 Cha_1 )
2.25423135E-03 3 3 -2 -1000037 # BR(Glu_2 -> Fd_2 Fu_1^* Cha_2^* )
2.25423135E-03 3 -3 2 1000037 # BR(Glu_2 -> Fd_2^* Fu_1 Cha_2 )
2.43832202E-03 3 3 -2 -1000047 # BR(Glu_2 -> Fd_2 Fu_1^* Cha_3^* )
2.43832202E-03 3 -3 2 1000047 # BR(Glu_2 -> Fd_2^* Fu_1 Cha_3 )
5.28940577E-03 3 3 -4 -1000024 # BR(Glu_2 -> Fd_2 Fu_2^* Cha_1^* )
5.28940577E-03 3 -3 4 1000024 # BR(Glu_2 -> Fd_2^* Fu_2 Cha_1 )
5.14742876E-02 3 3 -4 -1000037 # BR(Glu_2 -> Fd_2 Fu_2^* Cha_2^* )
5.14742876E-02 3 -3 4 1000037 # BR(Glu_2 -> Fd_2^* Fu_2 Cha_2 )
4.54771666E-02 3 3 -4 -1000047 # BR(Glu_2 -> Fd_2 Fu_2^* Cha_3^* )
4.54771666E-02 3 -3 4 1000047 # BR(Glu_2 -> Fd_2^* Fu_2 Cha_3 )
2.12307021E-04 3 3 -6 -1000024 # BR(Glu_2 -> Fd_2 Fu_3^* Cha_1^* )
2.12307021E-04 3 -3 6 1000024 # BR(Glu_2 -> Fd_2^* Fu_3 Cha_1 )
7.90313833E-05 3 3 -6 -1000037 # BR(Glu_2 -> Fd_2 Fu_3^* Cha_2^* )
7.90313833E-05 3 -3 6 1000037 # BR(Glu_2 -> Fd_2^* Fu_3 Cha_2 )
1.12728592E-04 3 3 -6 -1000047 # BR(Glu_2 -> Fd_2 Fu_3^* Cha_3^* )
1.12728592E-04 3 -3 6 1000047 # BR(Glu_2 -> Fd_2^* Fu_3 Cha_3 )
3.45168262E-02 3 5 -6 -1000024 # BR(Glu_2 -> Fd_3 Fu_3^* Cha_1^* )
3.45168262E-02 3 -5 6 1000024 # BR(Glu_2 -> Fd_3^* Fu_3 Cha_1 )
7.62866868E-03 3 5 -6 -1000037 # BR(Glu_2 -> Fd_3 Fu_3^* Cha_2^* )
7.62866868E-03 3 -5 6 1000037 # BR(Glu_2 -> Fd_3^* Fu_3 Cha_2 )
1.93970003E-02 3 5 -6 -1000047 # BR(Glu_2 -> Fd_3 Fu_3^* Cha_3^* )
1.93970003E-02 3 -5 6 1000047 # BR(Glu_2 -> Fd_3^* Fu_3 Cha_3 )
1.41719142E-02 3 2 -2 1000022 # BR(Glu_2 -> Fu_1 Fu_1^* Chi_1 )
3.45488297E-02 3 2 -2 1000023 # BR(Glu_2 -> Fu_1 Fu_1^* Chi_2 )
6.59158304E-03 3 2 -2 1000025 # BR(Glu_2 -> Fu_1 Fu_1^* Chi_3 )
2.70550307E-02 3 2 -2 1000045 # BR(Glu_2 -> Fu_1 Fu_1^* Chi_5 )
2.13896573E-02 3 2 -2 1000055 # BR(Glu_2 -> Fu_1 Fu_1^* Chi_6 )
1.41765069E-02 3 4 -4 1000022 # BR(Glu_2 -> Fu_2 Fu_2^* Chi_1 )
3.45306128E-02 3 4 -4 1000023 # BR(Glu_2 -> Fu_2 Fu_2^* Chi_2 )
6.57327374E-03 3 4 -4 1000025 # BR(Glu_2 -> Fu_2 Fu_2^* Chi_3 )
2.69638753E-02 3 4 -4 1000045 # BR(Glu_2 -> Fu_2 Fu_2^* Chi_5 )
2.13128326E-02 3 4 -4 1000055 # BR(Glu_2 -> Fu_2 Fu_2^* Chi_6 )
1.08958792E-04 3 4 -6 1000025 # BR(Glu_2 -> Fu_2 Fu_3^* Chi_3 )
1.20056044E-04 3 4 -6 1000035 # BR(Glu_2 -> Fu_2 Fu_3^* Chi_4 )
1.08958792E-04 3 6 -4 1000025 # BR(Glu_2 -> Fu_3 Fu_2^* Chi_3 )
1.20056044E-04 3 6 -4 1000035 # BR(Glu_2 -> Fu_3 Fu_2^* Chi_4 )
8.70542313E-03 3 6 -6 1000022 # BR(Glu_2 -> Fu_3 Fu_3^* Chi_1 )
4.57738861E-03 3 6 -6 1000023 # BR(Glu_2 -> Fu_3 Fu_3^* Chi_2 )
1.22921385E-02 3 6 -6 1000025 # BR(Glu_2 -> Fu_3 Fu_3^* Chi_3 )
6.36396440E-02 3 6 -6 1000035 # BR(Glu_2 -> Fu_3 Fu_3^* Chi_4 )
2.70921504E-03 3 6 -6 1000045 # BR(Glu_2 -> Fu_3 Fu_3^* Chi_5 )
1.92368492E-03 3 6 -6 1000055 # BR(Glu_2 -> Fu_3 Fu_3^* Chi_6 )
DECAY 1000022 0.00000000E+00 # Chi_1
# BR NDA ID1 ID2
DECAY 1000023 1.01824186E-14 # Chi_2
# BR NDA ID1 ID2
# BR NDA ID1 ID2 ID3
# 2.02161507E-01 3 1000022 -1 1 # BR(Chi_2 -> Chi_1 Fd_1^* Fd_1 )
# 2.01119336E-01 3 1000022 -3 3 # BR(Chi_2 -> Chi_1 Fd_2^* Fd_2 )
# 2.40988599E-02 3 1000022 -11 11 # BR(Chi_2 -> Chi_1 Fe_1^* Fe_1 )
# 2.38587878E-02 3 1000022 -13 13 # BR(Chi_2 -> Chi_1 Fe_2^* Fe_2 )
# 2.00865464E-04 3 1000022 -15 15 # BR(Chi_2 -> Chi_1 Fe_3^* Fe_3 )
# 1.89489818E-01 3 1000022 -2 2 # BR(Chi_2 -> Chi_1 Fu_1^* Fu_1 )
# 6.48987546E-02 3 1000022 -4 4 # BR(Chi_2 -> Chi_1 Fu_2^* Fu_2 )
# 9.80567536E-02 3 1000022 -12 12 # BR(Chi_2 -> Chi_1 Fv_1^* Fv_1 )
# 9.80567537E-02 3 1000022 -14 14 # BR(Chi_2 -> Chi_1 Fv_2^* Fv_2 )
# 9.80567907E-02 3 1000022 -16 16 # BR(Chi_2 -> Chi_1 Fv_3^* Fv_3 )
5.00000000E-01 3 1000022 -11 11 # BR(Chi_2 -> Chi_1 Fe_1^* Fe_1 )
5.00000000E-01 3 1000022 -13 13 # BR(Chi_2 -> Chi_1 Fe_2^* Fe_2 )
DECAY 1000025 2.12473527E-01 # Chi_3
# BR NDA ID1 ID2
1.18121873E-01 2 1000022 25 # BR(Chi_3 -> Chi_1 hh_1 )
1.73635904E-01 2 1000023 25 # BR(Chi_3 -> Chi_2 hh_1 )
4.35969887E-01 2 1000022 23 # BR(Chi_3 -> Chi_1 VZ )
2.72272182E-01 2 1000023 23 # BR(Chi_3 -> Chi_2 VZ )
DECAY 1000035 2.86157711E-01 # Chi_4
# BR NDA ID1 ID2
4.90430759E-01 2 1000022 25 # BR(Chi_4 -> Chi_1 hh_1 )
1.41683140E-01 2 1000023 25 # BR(Chi_4 -> Chi_2 hh_1 )
2.02821184E-01 2 1000022 23 # BR(Chi_4 -> Chi_1 VZ )
1.65018975E-01 2 1000023 23 # BR(Chi_4 -> Chi_2 VZ )
DECAY 1000045 7.97556911E-02 # Chi_5
# BR NDA ID1 ID2
2.61092849E-01 2 1000024 24 # BR(Chi_5 -> Cha_1 VWm^* )
2.61092849E-01 2 -1000024 -24 # BR(Chi_5 -> Cha_1^* VWm )
1.11481764E-01 2 1000022 25 # BR(Chi_5 -> Chi_1 hh_1 )
3.23373320E-02 2 1000023 25 # BR(Chi_5 -> Chi_2 hh_1 )
3.22680004E-02 2 1000025 25 # BR(Chi_5 -> Chi_3 hh_1 )
2.65270011E-02 2 1000035 25 # BR(Chi_5 -> Chi_4 hh_1 )
5.51417142E-02 2 1000022 23 # BR(Chi_5 -> Chi_1 VZ )
3.07208896E-04 2 1000023 23 # BR(Chi_5 -> Chi_2 VZ )
4.74029453E-02 2 1000025 23 # BR(Chi_5 -> Chi_3 VZ )
1.72327165E-01 2 1000035 23 # BR(Chi_5 -> Chi_4 VZ )
DECAY 1000055 1.23215836E+00 # Chi_6
# BR NDA ID1 ID2
2.85066724E-01 2 1000024 24 # BR(Chi_6 -> Cha_1 VWm^* )
2.85066724E-01 2 -1000024 -24 # BR(Chi_6 -> Cha_1^* VWm )
2.55272900E-03 2 1000022 25 # BR(Chi_6 -> Chi_1 hh_1 )
7.30954316E-03 2 1000023 25 # BR(Chi_6 -> Chi_2 hh_1 )
2.08059399E-01 2 1000025 25 # BR(Chi_6 -> Chi_3 hh_1 )
3.12669926E-04 2 1000035 25 # BR(Chi_6 -> Chi_4 hh_1 )
6.00386902E-02 2 1000022 23 # BR(Chi_6 -> Chi_1 VZ )
2.04628916E-02 2 1000023 23 # BR(Chi_6 -> Chi_2 VZ )
3.16756468E-03 2 1000025 23 # BR(Chi_6 -> Chi_3 VZ )
1.27961528E-01 2 1000035 23 # BR(Chi_6 -> Chi_4 VZ )
DECAY 1000024 2.42129630E-01 # Cha_1
# BR NDA ID1 ID2
6.22794754E-01 2 1000022 -24 # BR(Cha_1 -> Chi_1 VWm )
3.77194439E-01 2 1000023 -24 # BR(Cha_1 -> Chi_2 VWm )
DECAY 1000037 1.46963935E-01 # Cha_2
# BR NDA ID1 ID2
3.92268114E-02 2 1000024 25 # BR(Cha_2 -> Cha_1 hh_1 )
1.23218064E-01 2 1000024 23 # BR(Cha_2 -> Cha_1 VZ )
1.94062865E-01 2 1000022 -24 # BR(Cha_2 -> Chi_1 VWm )
7.93482232E-03 2 1000023 -24 # BR(Cha_2 -> Chi_2 VWm )
3.71789024E-01 2 1000025 -24 # BR(Cha_2 -> Chi_3 VWm )
2.63411348E-01 2 1000035 -24 # BR(Cha_2 -> Chi_4 VWm )
# BR NDA ID1 ID2 ID3
3.34460855E-04 3 1000022 -6 5 # BR(Cha_2 -> Chi_1 Fu_3^* Fd_3 )
DECAY 1000047 1.19982610E+00 # Cha_3
# BR NDA ID1 ID2
2.08643885E-01 2 1000024 25 # BR(Cha_3 -> Cha_1 hh_1 )
2.59099379E-01 2 1000024 23 # BR(Cha_3 -> Cha_1 VZ )
5.18255122E-02 2 1000022 -24 # BR(Cha_3 -> Chi_1 VWm )
2.84172848E-02 2 1000023 -24 # BR(Cha_3 -> Chi_2 VWm )
2.93148260E-01 2 1000025 -24 # BR(Cha_3 -> Chi_3 VWm )
1.58726930E-01 2 1000035 -24 # BR(Cha_3 -> Chi_4 VWm )
# BR NDA ID1 ID2 ID3
1.03529903E-04 3 1000022 -6 5 # BR(Cha_3 -> Chi_1 Fu_3^* Fd_3 )
DECAY 2 0.00000000E+00 # Fu_1
# BR NDA ID1 ID2
DECAY 4 0.00000000E+00 # Fu_2
# BR NDA ID1 ID2
DECAY 6 1.61201460E+00 # Fu_3
# BR NDA ID1 ID2
1.67594663E-03 2 3 24 # BR(Fu_3 -> Fd_2 VWm^* )
9.98288615E-01 2 5 24 # BR(Fu_3 -> Fd_3 VWm^* )
DECAY 21 0.00000000E+00 # VG
DECAY 22 0.00000000E+00 # VP
DECAY 23 2.49520000E+00 # VZ
DECAY 24 2.14100000E+00 # VWm
DECAY 12 0.00000000E+00 # Fv_1
DECAY 14 0.00000000E+00 # Fv_2
DECAY 16 0.00000000E+00 # Fv_3
DECAY 11 0.00000000E+00 # Fe_1
DECAY 13 0.00000000E+00 # Fe_2
DECAY 15 0.00000000E+00 # Fe_3
DECAY 1 0.00000000E+00 # Fd_1
DECAY 3 0.00000000E+00 # Fd_2
DECAY 5 0.00000000E+00 # Fd_3
]]>
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<weight id="27" MUR="1.0" MUF="2.0" DYN_SCALE="2" PDF="260000" > MUF=2.0 dyn_scale_choice=HT </weight>
<weight id="28" MUR="1.0" MUF="2.0" DYN_SCALE="3" PDF="260000" > MUF=2.0 dyn_scale_
<weight id="29" MUR="1.0" MUF="2.0" DYN_SCALE="4" PDF="260000" > MUF=2.0 dyn_scale_
<weight id="30" MUR="2.0" MUF="0.5" PDF="260000" > MUR=2.0 MUF=0.5 </weight>
<weight id="31" MUR="2.0" MUF="0.5" DYN_SCALE="1" PDF="260000" > MUR=2.0 MUF=0.5 dyn_scale_
<weight id="32" MUR="2.0" MUF="0.5" DYN_SCALE="2" PDF="260000" > MUR=2.0 MUF=0.5 dyn_scale_choice=HT </weight>
<weight id="33" MUR="2.0" MUF="0.5" DYN_SCALE="3" PDF="260000" > MUR=2.0 MUF=0.5 dyn_scale_
<weight id="34" MUR="2.0" MUF="0.5" DYN_SCALE="4" PDF="260000" > MUR=2.0 MUF=0.5 dyn_scale_
<weight id="35" MUR="2.0" MUF="1.0" PDF="260000" > MUR=2.0 </weight>
<weight id="36" MUR="2.0" MUF="1.0" DYN_SCALE="1" PDF="260000" > MUR=2.0 dyn_scale_
<weight id="37" MUR="2.0" MUF="1.0" DYN_SCALE="2" PDF="260000" > MUR=2.0 dyn_scale_choice=HT </weight>
<weight id="38" MUR="2.0" MUF="1.0" DYN_SCALE="3" PDF="260000" > MUR=2.0 dyn_scale_
<weight id="39" MUR="2.0" MUF="1.0" DYN_SCALE="4" PDF="260000" > MUR=2.0 dyn_scale_
<weight id="40" MUR="2.0" MUF="2.0" PDF="260000" > MUR=2.0 MUF=2.0 </weight>
<weight id="41" MUR="2.0" MUF="2.0" DYN_SCALE="1" PDF="260000" > MUR=2.0 MUF=2.0 dyn_scale_
<weight id="42" MUR="2.0" MUF="2.0" DYN_SCALE="2" PDF="260000" > MUR=2.0 MUF=2.0 dyn_scale_choice=HT </weight>
<weight id="43" MUR="2.0" MUF="2.0" DYN_SCALE="3" PDF="260000" > MUR=2.0 MUF=2.0 dyn_scale_
<weight id="44" MUR="2.0" MUF="2.0" DYN_SCALE="4" PDF="260000" > MUR=2.0 MUF=2.0 dyn_scale_
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</initrwgt>
<MGGenerationInfo>
# Number of Events : 100
# Integrated weight (pb) : 2.01629545539e-05
</MGGenerationInfo>
<MGPythiaCard>
<![CDATA[
!
! It is possible to run this card manually with:
! LD_LIBRARY_
!
!
! Pythia8 cmd card automatically generated by MadGraph5_aMC@NLO
! For more information on the use of the MG5aMC / Pythia8 interface, visit
! https:/
!
! ==================
! General parameters
! ==================
!
Main:numberOfEvents = -1
!
! -------
! Specify the HEPMC output of the Pythia8 shower. You can set it to:
! auto : MG5aMC will automatically place it the run_<i> directory
! /dev/null : to turn off the HEPMC output.
! <path> : to select where the HEPMC file must written. It will
! therefore not be placed in the run_<i> directory. The
! specified path, if not absolute, will be relative to
! the Event/run_<i> directory of the process output.
! fifo : to have MG5aMC setup the piping of the PY8 output to
! analysis tools such as MadAnalysis5.
! fifo@<fifo_path> :
! Same as 'fifo', but selecting a custom path to create the
! fifo pipe. (useful to select a mounted drive that supports
! fifo). Note that the fifo file extension *must* be '.hepmc.fifo'.
! -------
!
HEPMCoutput:file = tag_1_pythia8_
!
! -------
! Parameters relevant only when performing MLM merging, which can be
! turned on by setting ickkw to '1' in the run_card and chosing a
! positive value for the parameter xqcut.
! For details, see section 'Jet Matching' on the left-hand menu of
! http://
! -------
! If equal to -1.0, MadGraph5_aMC@NLO will set it automatically based
! on the parameter 'xqcut' of the run_card.dat
! The following parameter was forced to be commented out by MG5aMC.
! JetMatching:qCut = -1.0
! Use default kt-MLM to match parton level jets to those produced by the
! shower. But the other Shower-kt scheme is available too with this option.
! The following parameter was forced to be commented out by MG5aMC.
! JetMatching:
! A value of -1 means that it is automatically guessed by MadGraph.
! It is however always safer to explicitly set it.
! The following parameter was forced to be commented out by MG5aMC.
! JetMatching:nJetMax = -1
!
! -------
! Parameters relevant only when performing CKKW-L merging, which can
! be turned on by setting the parameter 'ptlund' *or* 'ktdurham' to
! a positive value.
! For details, see section 'CKKW-L Merging' on the left-hand menu of
! http://
! -------
! Central merging scale values you want to be used.
! If equal to -1.0, then MadGraph5_aMC@NLO will set this automatically
! based on the parameter 'ktdurham' of the run_card.dat
! The following parameter was forced to be commented out by MG5aMC.
! Merging:TMS = -1.0
! This must be set manually, according to Pythia8 directives.
! An example of possible value is 'pp>LEPTONS,
! Alternatively, from Pythia v8.223 onwards, the value 'guess' can be
! used to instruct Pythia to guess the hard process. The guess would mean
! that all particles apart from light partons will be considered as a part
! of the hard process. This guess is prone to errors if the desired hard
! process is complicated (i.e. contains light partons). The user should
! then be wary of suspicious error messages in the Pythia log file.
! The following parameter was forced to be commented out by MG5aMC.
! Merging:Process = <set_by_user>
! A value of -1 means that it is automatically guessed by MadGraph.
! It is however always safer to explicitly set it.
! The following parameter was forced to be commented out by MG5aMC.
! Merging:nJetMax = -1
!
! For all merging schemes, decide whehter you want the merging scale
! variation computed for only the central weights or all other
! PDF and scale variation weights as well
SysCalc:
!
! =======
! User customized parameters
! =======
!
! By default, Pythia8 generates multi-parton interaction events. This is
! often irrelevant for phenomenology and very slow. You can turn this
! feature off by uncommenting the line below if so desired.
!partonlevel:mpi = off
!
! Additional general parameters.
!
#1000023:
#1000023:
#1000023:tau0=70.
##1000023:
SUSY:all=off
##SUSYResonance
!
! Additional technical parameters set by MG5_aMC.
!
! Tell Pythia8 that an LHEF input is used.
Beams:frameType=4
! Specify one must read inputs from the MadGraph banner.
JetMatching:
JetMatching:
! 1.0 corresponds to HEPMC weight given in [mb]. We choose here the [pb] normalization.
HEPMCoutput:
! Be more forgiving with momentum mismatches.
Check:epTolErr=
!
! =======
! Subrun definitions
! =======
!
LHEFInputs:
Main:subrun=0
!
! Definition of subrun 0
!
Beams:LHEF=
]]>
</MGPythiaCard>
<madspin>
<![CDATA[
#******
#* MadSpin *
#* *
#* P. Artoisenet, R. Frederix, R. Rietkerk, O. Mattelaer *
#* *
#* Part of the MadGraph5_aMC@NLO Framework: *
#* The MadGraph5_aMC@NLO Development Team - Find us at *
#* https:/
#* *
#* Manual: *
#* cp3.irmp.
#* *
#******
#Some options (uncomment to apply)
#
# set seed 1
# set Nevents_
# set BW_cut 15 # cut on how far the particle can be off-shell
set spinmode none # Use one of the madspin special mode
set max_weight_ps_point 400 # number of PS to estimate the maximum for each event
# specify the decay for the final state particles
decay n2 > l+ l- n1
# running the actual code
launch
]]>
</madspin>
</header>
<init>
2212 2212 6.500000e+03 6.500000e+03 0 0 260000 260000 -4 1
+2.7444131e-08 +4.8796094e-10 +2.7454802e-08 1
<generator name='MadGraph5
</init>
</LesHouchesEvents>
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#5 |
Thanks Olivier Mattelaer, that solved my question.
