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SMLeftRight.wpmod
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SMLeftRight.wpmod
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#*****************************************************************
# This file is useful only if "model" in param_card.dat is set *
# to nonzero. *
# *
# WARNING! WARNING! WARNING! WARNING! WARNING! WARNING! WARNING! *
# Please read the instructions and edit this file carefully, *
# since the calculations will involve ALL of the numbers in this *
# file. *
# WARNING! WARNING! WARNING! WARNING! WARNING! WARNING! WARNING! *
# *
# (A) The first column is reserved for '#' only. *
# *
# (B) Do not use TAB for spacing, use SPACE only. *
# *
# (C) This file contains all the parameters in the most general *
# Lorentz invariant Lagrangian describing the coupling of a *
# W-prime to fermions. While the Lagrangian can be written as *
# *
# \mathcal{L}= *
# *
# \frac{g}{\sqrt{2}}\bar{f_{i}}\gamma_{\mu} *
# (C_{f_{i}f_{j}}^{R}P_{R}+C_{f_{i}f_{j}}^{L}P_{L})W'f_{j}+ *
# \mathrm{H.c.}= (1) *
# *
# \frac{1}{\sqrt{2}}\bar{f_{i}}\gamma_{\mu} *
# (g_{R}e^{i\omega}\cos\zeta V_{f_{i}f_{j}}^{R}P_{R}+ *
# g_{L}\sin\zeta V_{f_{i}f_{j}}^{L}P_{L})W'f_{j}+ *
# \mathrm{H.c.}= (2) *
# *
# \frac{g}{\sqrt{2}}\bar{f_{i}}\gamma_{\mu} *
# (S_{R}e^{i\omega}V_{f_{i}f_{j}}^{R}P_{R}+ *
# S_{L}V_{f_{i}f_{j}}^{L}P_{L})W'f_{j}+ *
# \mathrm{H.c.}, (3) *
# *
# form (3) is used in this file, where the left-right mixing *
# factors \cos\zeta and \sin\zeta in form (2) are absorbed into *
# S_{R} and S_{L} respectively. *
# *
# (D) The real multipliers for the Generalized CKM matrices can *
# be used to switch on/off the sector, or handle the differece *
# between coupling constants of left-handed quarks and *
# left-handed leptons. *
# *
# (E) Enable log, run *
# *
# $ make checkmodel *
# $ ./checkmodel *
# *
# to make sure that the parameters are set correctly. *
# *
#*****************************************************************
# g = W-prime coupling constant variable name
# (Default to SM SU(2)_{L} coupling constant)
6.53078575991675d-1 # g cf(1)
#
#
# S_{R} = multiplier of g for right-handed particles
# (Default to 1d0 to enable right-handed couplings)
1d0 # S_{R} cf(2)
#*****************************************************************
# Note that \cos\zeta in form (2) is absorbed into S_{R}. Also *
# note that S_{R} will be multiplied by BOTH the multiplier for *
# right-handed quarks, and "grscale" in param_card.dat. *
#*****************************************************************
#
#
# S_{L} = multiplier of g for left-handed particles
# (Default to 1d0 for SM)
1d0 # S_{L} cf(3)
#*****************************************************************
# Note that \sin\zeta in form (2) is absorbed into S_{L}. Also *
# note that S_{L} for left-handed quarks/leptons will be *
# multiplied by BOTH the multiplier for left-handed *
# quarks/leptons, and "glscale" in 'param_card.dat'. *
#*****************************************************************
#
#
# omega = CP-violating phase (in Radians)
0d0 # omega f(4)
#*****************************************************************
# Leave omega zero if e^{i\omega} is absorbed into your CKM *
# matrix. *
#*****************************************************************
#
#
# Generalized CKM matrix for right-handed quarks
# (Default to SM CKM matrix for left-handed quarks)
# real part imagnary part
9.74190000d-01 0d0 # V_{ud}^{R} rqr(1),rqi(1)
2.25700000d-01 0d0 # V_{us}^{R} rqr(2),rqi(2)
3.59000000d-03 0d0 # V_{ub}^{R} rqr(3),rqi(3)
2.25600000d-01 0d0 # V_{cd}^{R} rqr(4),rqi(4)
9.73340000d-01 0d0 # V_{cs}^{R} rqr(5),rqi(5)
4.15000000d-02 0d0 # V_{cb}^{R} rqr(6),rqi(6)
8.74000000d-03 0d0 # V_{td}^{R} rqr(7),rqi(7)
4.07000000d-02 0d0 # V_{ts}^{R} rqr(8),rqi(8)
9.99133000d-01 0d0 # V_{tb}^{R} rqr(9),rqi(9)
1d0 # multiplier cf(5)
#*****************************************************************
# Note that S_{R} will be scaled by this multiplier for *
# right-handed quarks. *
#*****************************************************************
#
#
#*****************************************************************
# There is no right-handed neutrino in our scope. *
#*****************************************************************
#
#
# Generalized CKM matrix for left-handed quarks
# (Default to SM CKM matrix for left-handed quarks)
# real part imagnary part
9.74190000d-01 0d0 # V_{ud}^{L} lqr(1),lqi(1)
2.25700000d-01 0d0 # V_{us}^{L} lqr(2),lqi(2)
3.59000000d-03 0d0 # V_{ub}^{L} lqr(3),lqi(3)
2.25600000d-01 0d0 # V_{cd}^{L} lqr(4),lqi(4)
9.73340000d-01 0d0 # V_{cs}^{L} lqr(5),lqi(5)
4.15000000d-02 0d0 # V_{cb}^{L} lqr(6),lqi(6)
8.74000000d-03 0d0 # V_{td}^{L} lqr(7),lqi(7)
4.07000000d-02 0d0 # V_{ts}^{L} lqr(8),lqi(8)
9.99133000d-01 0d0 # V_{tb}^{L} lqr(9),lqi(9)
1d0 # multiplier cf(6)
#*****************************************************************
# Note that S_{L} will be scaled by this multiplier for *
# left-handed quarks. *
#*****************************************************************
#
#
# Generalized CKM matrix for left-handed leptons
# (Default to diagonal unitary matrix)
# real part imagnary part
1d0 0d0 # V_{eve}^{L} llr(1),lli(1)
0d0 0d0 # V_{evm}^{L} llr(2),lli(2)
0d0 0d0 # V_{evt}^{L} llr(3),lli(3)
0d0 0d0 # V_{mve}^{L} llr(4),lli(4)
1d0 0d0 # V_{mvm}^{L} llr(5),lli(5)
0d0 0d0 # V_{mvt}^{L} llr(6),lli(6)
0d0 0d0 # V_{tve}^{L} llr(7),lli(7)
0d0 0d0 # V_{tvm}^{L} llr(8),lli(8)
1d0 0d0 # V_{tvt}^{L} llr(9),lli(9)
1d0 # multiplier cf(7)
#*****************************************************************
# Note that S_{L} will be scaled by this multiplier for *
# left-handed leptons. *
#*****************************************************************
#
#
# Log settings sets(1)-sets(6)
.true. # log enabled
.true. # log coupling constants and CKM matrices for right- and
# left-handed quarks and leptons
.true. # log W-prime width; W-prime mass is set to WPMASS in
# 'param_card.dat'
.true. # log branching ratios
.true. # log R_{u} and R_{t} for quick view. See the footnote
# of README for the definations of R_{u} and R_{t}.
.true. # log R_{u}, R_{t} with higher precision (which takes
# ~170 more lines), and g_{SM}/g_{effctive} if R_{u}=0
#*****************************************************************
# Log will not be saved as files automatically, but will be *
# printed to the terminal, which can be directed to files. *
#*****************************************************************
#
#
EOF