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NoH_rx.mdl
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NoH_rx.mdl
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########################################################################
# Higgsless Model (unitary gauge) with anomalous couplings,
# CKM matrix and K-Matrix unitarization
model "NoH_rx"
# Independent parameters
### DO NOT CHANGE THE ORDER OF THESE PARAMETERS
parameter GF = 1.16639E-5 # Fermi constant
parameter mZ = 91.1882 # Z-boson mass
parameter mW = 80.419 # W-boson mass
parameter alphas = 0.1178 # Strong coupling constant (Z point)
parameter me = 0.000511 # electron mass
parameter mmu = 0.1057 # muon mass
parameter mtau = 1.777 # tau-lepton mass
parameter ms = 0.12 # s-quark mass
parameter mc = 1.25 # c-quark mass
parameter mb = 4.2 # b-quark mass
parameter mtop = 174 # t-quark mass
parameter wtop = 1.523 # t-quark width
parameter wZ = 2.443 # Z-boson width
parameter wW = 2.049 # W-boson width
parameter xi0 = 0 # R_xi parameter for Z-boson
parameter xipm = 0 # R_xi parameter for W-boson
parameter a4 = 0 # Coefficient of L4
parameter a5 = 0 # Coefficient of L5
parameter a6 = 0 # Coefficient of L6
parameter a7 = 0 # Coefficient of L7
parameter a10 = 0 # Coefficient of L10
parameter mkm_s = 1.E10 # Mass for scalar isoscalar resonance
parameter mkm_p = 1.E10 # Mass for scalar isotensor resonance
parameter mkm_r = 1.E10 # Mass for vector isovector resonance
parameter mkm_f = 1.E10 # Mass for tensor isotensor resonance
parameter mkm_t = 1.E10 # Mass for tensor isotensor resonance
parameter gkm_s = 0 # Coupling for scalar isoscalar resonance
parameter gkm_p = 0 # Coupling for scalar isotensor resonance
parameter gkm_r = 0 # Coupling for vector isovector resonance
parameter gkm_f = 0 # Coupling for tensor isoscalar resonance
parameter gkm_t = 0 # Coupling for tensor isotensor resonance
parameter wkm_s = 1.E-4 # Width for scalar isoscalar resonance
parameter wkm_p = 1.E-4 # Width for scalar isotensor resonance
parameter wkm_r = 1.E-4 # Width for vector isovector resonance
parameter wkm_f = 1.E-4 # Width for tensor isotensor resonance
parameter wkm_t = 1.E-4 # Width for tensor isotensor resonance
parameter g1a = 1 # anomalous TGC
parameter g1z = 1 # anomalous TGC
parameter g4a = 0 # anomalous TGC
parameter g4z = 0 # anomalous TGC
parameter g5a = 0 # anomalous TGC
parameter g5z = 0 # anomalous TGC
parameter ka = 1 # anomalous TGC
parameter kz = 1 # anomalous TGC
parameter la = 0 # anomalous TGC
parameter lz = 0 # anomalous TGC
parameter k5a = 0 # anomalous TGC
parameter k5z = 0 # anomalous TGC
parameter l5a = 0 # anomalous TGC
parameter l5z = 0 # anomalous TGC
parameter mreg = 1000 # regulator mass for one-loop correction
parameter fkm = 1 # fudge factor to switch K matrix unitarization
# for resonances on or off
parameter wres = 0 # switch for automatic resonance widths (need wkm_* = 0)
parameter gkm_st = 0 # Transversal coupling for scalar isoscalar resonance
parameter gkm_pt = 0 # Transversal coupling for scalar isotensor resonance
parameter gkm_rt = 0 # Transversal Coupling for vector isovector resonance
parameter gkm_ft = 0 # Transversal coupling for tensor isoscalar resonance
parameter gkm_tt = 0 # Coupling for tensor isotensor resonance
parameter fmixed = 1 # Coupling for mixed terms of transversal and longitudinal couplings
parameter fkappa = 0 # kappa Term for tensor isoscalar resonance (experimental)
# Dependent parameters
derived v = 1 / sqrt (sqrt (2.) * GF) # v (Higgs vev)
derived cw = mW / mZ # cos(theta-W)
derived sw = sqrt (1-cw**2) # sin(theta-W)
derived ee = 2 * sw * mW / v # em-coupling (GF scheme)
derived alpha_em_i = 4 * pi / ee**2 # inverse fine structure const
########################################################################
# Particle content
# The quarks
particle D_QUARK 1 parton
spin 1/2 charge -1/3 isospin -1/2 color 3
name d down
anti dbar D "d~"
tex_anti "\bar{d}"
particle U_QUARK 2 parton
spin 1/2 charge 2/3 isospin 1/2 color 3
name u up
anti ubar U "u~"
tex_anti "\bar{u}"
particle S_QUARK 3 like D_QUARK
name s strange
anti sbar S "s~"
tex_anti "\bar{s}"
mass ms
particle C_QUARK 4 like U_QUARK
name c charm
anti cbar C "c~"
tex_anti "\bar{c}"
mass mc
particle B_QUARK 5 like D_QUARK
name b bottom
anti bbar B "b~"
tex_anti "\bar{b}"
mass mb
particle T_QUARK 6 like U_QUARK
name t top
anti tbar T "t~"
tex_anti "\bar{t}"
mass mtop width wtop
# The leptons
particle E_LEPTON 11
spin 1/2 charge -1 isospin -1/2
name "e-" e1 electron e
anti "e+" E1 positron
tex_name "e^-"
tex_anti "e^+"
mass me
particle E_NEUTRINO 12 left
spin 1/2 isospin 1/2
name nue n1 "nu_e" ve "e-neutrino"
anti nuebar N1 "ve~"
tex_name "\nu_e"
tex_anti "\bar\nu_e"
particle MU_LEPTON 13 like E_LEPTON
name "mu-" e2 mu muon
anti "mu+" E2
tex_name "\mu^-"
tex_anti "\mu^+"
mass mmu
particle MU_NEUTRINO 14 like E_NEUTRINO
name numu "nu_mu" n2 vm "mu-neutrino"
anti numubar N2 "vm~"
tex_name "\nu_\mu"
tex_anti "\bar\nu_\mu"
particle TAU_LEPTON 15 like E_LEPTON
name "tau-" e3 tau "ta-" tauon
anti "tau+" E3 "ta+"
tex_name "\tau^-"
tex_anti "\tau^+"
mass mtau
particle TAU_NEUTRINO 16 like E_NEUTRINO
name nutau "nu_tau" n3 vt "tau_neutrino"
anti nutaubar N3 "vt~"
tex_name "\nu_\tau"
tex_anti "\bar\nu_\tau"
# The vector bosons
particle GLUON 21 parton gauge
spin 1 color 8
name gl g G gluon
particle PHOTON 22 gauge
spin 1
name A gamma photon
tex_name "\gamma"
particle Z_BOSON 23 gauge
spin 1
name Z
mass mZ width wZ
particle W_BOSON 24 gauge
spin 1 charge 1
name "W+" Wp
anti "W-" Wm
tex_name "W^+"
tex_anti "W^-"
mass mW width wW
# Hadrons
particle PROTON 2212
spin 1/2 charge 1
name p "p+"
anti pbar "p-"
# Beam remnants for proton colliders
particle HADRON_REMNANT 90
name hr
tex_name "had_r"
particle HADRON_REMNANT_SINGLET 91
name hr1
tex_name "had_r^{(1)}"
particle HADRON_REMNANT_TRIPLET 92
color 3
name hr3
tex_name "had_r^{(3)}"
anti hr3bar
tex_anti "had_r^{(\bar 3)}"
particle HADRON_REMNANT_OCTET 93
color 8
name hr8
tex_name "had_r^{(8)}"
########################################################################
# Vertices of the Standard model with anomalous couplings
# In graphs with identical structure, the first vertex is kept for phase space,
# therefore, lighter particles come before heavier ones.
#
# Note: The electric charge has opposite sign compared to SM.mdl
# QED
vertex D d A
vertex U u A
vertex S s A
vertex C c A
vertex B b A
vertex T t A
vertex E1 e1 A
vertex E2 e2 A
vertex E3 e3 A
# QCD
vertex G G G
vertex D d G
vertex U u G
vertex S s G
vertex C c G
vertex B b G
vertex T t G
# Neutral currents
vertex D d Z
vertex U u Z
vertex S s Z
vertex C c Z
vertex B b Z
vertex T t Z
vertex E1 e1 Z
vertex E2 e2 Z
vertex E3 e3 Z
vertex N1 n1 Z
vertex N2 n2 Z
vertex N3 n3 Z
# Charged currents
vertex U d Wp
vertex C s Wp
vertex T b Wp
vertex D u Wm
vertex S c Wm
vertex B t Wm
vertex N1 e1 Wp
vertex N2 e2 Wp
vertex N3 e3 Wp
vertex E1 n1 Wm
vertex E2 n2 Wm
vertex E3 n3 Wm
# Vector-boson self-interactions
vertex A Wm Wp
vertex Wm Wp Z
vertex A A Wm Wp
vertex A Wm Wp Z
vertex Wm Wm Wp Wp
vertex Wm Wp Z Z
vertex Z Z Z Z
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