mcfm_version = 10.3 writerefs = .true. [general] # process number nproc = 76 # part: lo, nlo, nnlo, nlocoeff, nnlocoeff part = resonlyNLO # string to identify run runstring = wmveto25 # directory for output files #rundir = 2110.11231 sqrts = 13000 # ih1, ih2: +1 for proton, -1 for antiproton ih1 = +1 ih2 = +1 zerowidth = .false. removebr = .false. # electroweak corrections: none, sudakov or exact ewcorr = none ewscheme = 4 [nnlo] # optional: tau cutoff for NNLO processes, otherwise default value is chosen # for less than 1% cutoff effects in the total cross section. # taucut = 0.001 # optional array of numerical taucut values that should be sampled on the fly in addition. # these values can be smaller or larger than the nominal taucut value # tcutarray = 0.002 0.003 0.004 0.005 0.01 0.02 0.03 0.05 0.1 0.2 0.4 0.8 1.0 useptveto = T qtcut = 0.01 [resummation] ptveto = 25 scalevar_rapidity = T [pdf] # PDF label for internal routines pdlabel = 'CT14.NN' [lhapdf] # LHAPDF PDF label lhapdfset = NNPDF31_nnlo_as_0118 # LHAPDF PDF member number, -1 for PDF uncertainties lhapdfmember = 0 # calculate PDF uncertainties. # note: can only do PDF uncertainties or scale variation at the same time. dopdferrors = .false. [scales] # Renormalization scale # Factorization scale # Controls use of dynamical scale # when different from 'none', set renscale and facscale to 1 dynamicscale = m(3456) renscale = 1.0 facscale = 1.0 # perform scale variation doscalevar = .true. # can be 2 or 6 for 2-point or 6-point scale-variation maxscalevar = 6 [masses] # Higgs mass hmass = 125 # Top-quark mass mt = 173.3 # Bottom-quark mass mb = 4.66 # Charm-quark mass mc = 1.275 # Diagonal CKM? CKMdiag = .true. [basicjets] # Jet-inclusive cross section inclusive = .true. # Jet-clustering algorithm: ankt, ktal, cone, hqrk, none algorithm = ankt # minimum jet pT; can also have ptjetmax ptjetmin = 25 # maximum jet rapidity; can also have etajetmin etajetmax = 4.5 Rcutjet = 0.4 [masscuts] # minimum mass of 3-4 system m34min = 0 # optional, maximum mass of 3-4 system, otherwise sqrts m34max = 14000 # minimum mass of 5-6 system m56min = 81.2 # optional, maximum mass of 5-6 system, otherwise sqrts m56max = 101.2 # minimum mass of 3-4-5-6 system m3456min = 0 # optional, maximum mass of 3-4-5-6 system, otherwise sqrts # m3456max = 14000 [cuts] # make additional cuts in this section makecuts = .true. # minimum lepton pT; can also have ptleptmax ptleptmin = 25 # maximum lepton rapidity, absolute value; can also have etaleptmin etaleptmax = 2.5 # rapidity veto on leptons etaleptveto = 0.0 0.0 # minimum missing pT ptminmiss = 0.0 # minimum pT for additional leptons; can also have ptlept2max ptlept2min = 15.0 # maximum rapidity for additional leptons, absolute value; can also have etalept2min etalept2max = 2.5 # rapidity veto on additional leptons etalept2veto = 0.0 0.0 # minimum pT for additional leptons; can also have ptlept2max ptlept3min = 15.0 # maximum rapidity for additional leptons, absolute value; can also have etalept2min etalept3max = 2.5 # electron comes from the W elptmin = 20 # mass-cut on trilepton system #m3lmin = 100 # minimum (3,4) transverse mass m34transmin = 30.0 # minimum R(jet,lept) Rjlmin = 0.0 # minimum R(lept,lept) Rllmin = 0.0 # minimum rapidity separation between jets delyjjmin = 0.0 # enforce jets to be in opposite hemispheres jetsopphem = .false. lbjscheme = 0 # b-jet minimum pT; can also have ptbjetmax ptbjetmin = 0.0 # b-jet maximum rapidity; can also have etabjetmin etabjetmax = 99.0 [photon] # include fragmentation fragmentation = .false. # fragmentation set fragmentation_set = GdRG__LO # fragmentation scale fragmentation_scale = 1.0 # minimum photon pT; can also have gammptmax gammptmin = 40 # maximum photon rapidity; can also have gammrapmin gammrapmax = 2.5 # second photon minimum pT gammpt2 = 25 # third photon minimum pT gammpt3 = 25 # minimum R(photon,lepton) Rgalmin = 0 # minimum R(photon,photon) Rgagamin = 0.4 # minimum R(photon,jet) Rgajetmin = 0 # cone size for isolation cone_ang = 0.4 # energy fraction for isolation epsilon_h = 0.5 # exponent for smooth-cone isolation n_pow = 1 [histogram] # write raw table file for each histogram writetxt = .true. newstyle = .true. [integration] # use sobol low discrepancy sequence usesobol = .true. # random number seed, when not using sobol, 0 means random seed = 0 # relative precision goal precisiongoal = 0.001 # resume from previous integration snapshot readin = .false. # write histograms and results after each vegas iteration writeintermediate = .true. # warmup precision goal in percent (default: 25%) # unless this precision is reached, the number of calls will be # increased and the warmup runs again warmupprecisiongoal = 0.25 # warmup chisq goal (default: 2.5) # unless this value of chisq/it is reached, the number of calls will be # increased and the warmup runs again warmupchisqgoal = 2.5 # process specific initializations # Single top SMEFT, nproc=164, 169 [singletop] # C_phiq (O1), real-valued c_phiq = 0 # C_phiphi (O2), real and imaginary part c_phiphi = 0.0 0.0 # C_tW (O3), real and imaginary part c_tw = 0.0 0.0 # C_bW (O4), real and imaginary part c_bw = 0.0 0.0 # C_tG (O6), real and imaginary part c_tg = 0.0 0.0 # C_bG (O7), real and imaginary part c_bg = 0.0 0.0 # Lambda, scale of EFT breakdown in GeV lambda = 1000 # enable 1/Lambda^4 contributions enable_lambda4 = .false. # disable Standard Model contributions disable_sm = .false. # anomalous couplings mode (only LO) mode_anomcoup = .false. # Anomalous couplings of the W and Z [anom_wz] # enable anomalous W/Z couplings enable = .false. # Delta g1(Z) delg1_z = 0 # Delta K(Z) delk_z = 0 # Delta K(gamma) delk_g = 0 # Lambda(Z) lambda_z = 0 # Lambda(gamma) lambda_g = 0 # h1(Z) h1Z = 0 # h1(gamma) h1gam = 0 # h2(Z) h2Z = 0 # h2(gamma) h2gam = 0 # h3(Z) h3Z = 0 # h3(gamma) h3gam = 0 # h4(Z) h4Z = 0 # h4(gamma) h4gam = 0 # Form-factor scale, in TeV tevscale = 2.0 # Higgs+jet with mass corrections, process 200 [hjetmass] mtex = 0 [anom_higgs] # Gamma_H / Gamma_H(SM) hwidth_ratio = 1.0 cttH = 1.0 cWWH = 1.0 [dipoles] alpha = 1.0