Welcome to Sherpa, Daniel Reichelt on ip3-cpu5.phyip3.dur.ac.uk. Initialization of framework underway. The local time is Mon Dec 4 12:40:05 2023. Run_Parameter::Init(): Setting memory limit to 503.276 GB. Random::SetSeed(): Seed set to 1070 Initialization_Handler::LoadLibraries(): Library libSherpaPythia.so loaded. ----------------------------------------------------------------------------- ----------- Event generation run with SHERPA started ....... ----------- ----------------------------------------------------------------------------- ................................................ | + ................................................ || | + + ................................... .... | | / + ................. ................ _,_ | .... || +| + + ............................... __.' ,\| ... || / +| + .............................. ( \ \ ... | | | + + \ + ............................. ( \ -/ .... || + | + ........ ................... (~~~~~~~~~## + + + ............................. ~~(! '~~~~~~~ \ + + + + ............................... `~~~QQQQQDb // | + + + + ........................ .......... IDDDDP|| \ + + + + + + .................................... IDDDI|| \ + .................................... IHD HD|| \ + + + + + + + + ................................... IHD ##| :-) + +\ + ......... ............... ......... IHI ## / / + + + + +\ + ................................... IHI/ / / + + + + + ................................... ## | | / / + + + + / + ....................... /TT\ ..... ##/ /// / + + + + + + +/ + ......................./TTT/T\ ... /TT\/\\\ / + + + + + + +/ \ + ....................../TTT/TTTT\...|TT/T\\\/ + ++ + / ----------------------------------------------------------------------------- SHERPA version 3.0.0beta1 (Dhaulagiri) Authors: Enrico Bothmann, Stefan Hoeche, Frank Krauss, Silvan Kuttimalai, Marek Schoenherr, Holger Schulz, Steffen Schumann, Frank Siegert, Korinna Zapp Former Authors: Timo Fischer, Tanju Gleisberg, Hendrik Hoeth, Ralf Kuhn, Thomas Laubrich, Andreas Schaelicke, Jan Winter This program uses a lot of genuine and original research work by other people. Users are encouraged to refer to the various original publications. Users are kindly asked to refer to the documentation published under JHEP 02(2009)007 Please visit also our homepage http://sherpa.hepforge.org for news, bugreports, updates and new releases. ----------------------------------------------------------------------------- WARNING: You are using an unsupported development branch. Git branch unknownurl, revision unknownrevision. Hadron_Init::Init(): Initializing kf table for hadrons. Beam_Spectra_Handler: type = Collider Setup for P+ (on = 0, p = (4000,0,0,4000)) and P+ (on = 0, p = (4000,0,0,-4000)). ISR handling: PDFs for hard scattering: CT14nnlo + CT14nnlo PDFs for multiple parton interactions: PDF4LHC21_40_pdfas + PDF4LHC21_40_pdfas Remnant_Handlers: hard process: P+: Hadron + P+: Hadron Standard_Model::FixEWParameters() { Input scheme: Gmu Gmu scheme, input: GF, m_W, m_Z, m_h, widths Ren. scheme: Gmu Parameters: sin^2(\theta_W) = 0.223043 - 0.00110541 i vev = 246.218 } Running_AlphaQED::PrintSummary() { Setting \alpha according to EW scheme 1/\alpha(0) = 137.036 1/\alpha(def) = 132.119 } One_Running_AlphaS::PrintSummary() { Setting \alpha_s according to PDF perturbative order 2 \alpha_s(M_Z) = 0.118 } One_Running_AlphaS::PrintSummary() { Setting \alpha_s according to PDF perturbative order 2 \alpha_s(M_Z) = 0.118 } List of Particle Data IDName kfc Mass Width Stable Massive Active Yukawa d 1 0.01 0 1 0 1 0 u 2 0.005 0 1 0 1 0 s 3 0.2 0 1 0 1 0 c 4 1.42 0 1 0 1 0 b 5 4.92 0 1 0 1 0 t 6 172.5 1.32 0 1 1 172.5 e- 11 0.000511 0 1 0 1 0 ve 12 0 0 1 0 1 0 mu- 13 0.105 0 1 0 1 0 vmu 14 0 0 1 0 1 0 tau- 15 1.777 2.26735e-12 0 0 1 0 vtau 16 0 0 1 0 1 0 G 21 0 0 1 0 1 0 P 22 0 0 1 0 1 0 Z 23 91.1876 2.4952 0 1 1 91.1876 W+ 24 80.379 2.085 0 1 1 80.379 h0 25 125.09 0.0041 0 1 1 125.09 string 95 0 0 1 0 1 0 cluster 96 0 0 1 0 1 0 Instanton 999 0 0 0 0 1 0 List of Particle Containers IDName kfc Constituents l 90 {e-,e+,mu-,mu+,tau-,tau+} v 91 {ve,veb,vmu,vmub,vtau,vtaub} f 92 {d,db,u,ub,s,sb,c,cb,b,bb,e-,e+,mu-,mu+,tau-,tau+,ve,veb,vmu,vmub,vtau,vtaub} j 93 {d,db,u,ub,s,sb,c,cb,b,bb,G} Q 94 {d,db,u,ub,s,sb,c,cb,b,bb} ewj 98 {d,db,u,ub,s,sb,c,cb,b,bb,G,P} Alaric_KFrame_TdefII Alaric_KFrame_TdefII Alaric_KFrame_TdefII Alaric_KFrame_TdefII Alaric_KFrame_TdefFF Alaric_KFrame_TdefFF Alaric_KFrame_TdefFF Alaric_KFrame_TdefFF ####### Permutations for 2 partons ############## found 2 entries: 1th permutation = { 0 1 } 2th permutation = { 1 0 } FF: collinear V->FF, G -> (db,d): increase cutoff to 0.02, now t0 = 0.02^2. FF: collinear V->FF, G -> (db,d): increase cutoff to 0.02, now t0 = 0.02^2. FI: collinear V->FF, G -> (db,d): increase cutoff to 0.02, now t0 = 0.02^2. FI: collinear V->FF, G -> (db,d): increase cutoff to 0.02, now t0 = 0.02^2. IF: collinear F->VF, G -> (db,d): increase cutoff to 0.02, now t0 = 0.02^2. IF: collinear F->VF, G -> (db,d): increase cutoff to 0.02, now t0 = 0.02^2. II: collinear F->VF, G -> (db,d): increase cutoff to 0.02, now t0 = 0.02^2. II: collinear F->VF, G -> (db,d): increase cutoff to 0.02, now t0 = 0.02^2. FF: collinear V->FF, G -> (ub,u): increase cutoff to 0.01, now t0 = 0.01^2. FF: collinear V->FF, G -> (ub,u): increase cutoff to 0.01, now t0 = 0.01^2. FI: collinear V->FF, G -> (ub,u): increase cutoff to 0.01, now t0 = 0.01^2. FI: collinear V->FF, G -> (ub,u): increase cutoff to 0.01, now t0 = 0.01^2. IF: collinear F->VF, G -> (ub,u): increase cutoff to 0.01, now t0 = 0.01^2. IF: collinear F->VF, G -> (ub,u): increase cutoff to 0.01, now t0 = 0.01^2. II: collinear F->VF, G -> (ub,u): increase cutoff to 0.01, now t0 = 0.01^2. II: collinear F->VF, G -> (ub,u): increase cutoff to 0.01, now t0 = 0.01^2. FF: collinear V->FF, G -> (sb,s): increase cutoff to 0.4, now t0 = 0.4^2. FF: collinear V->FF, G -> (sb,s): increase cutoff to 0.4, now t0 = 0.4^2. FI: collinear V->FF, G -> (sb,s): increase cutoff to 0.4, now t0 = 0.4^2. FI: collinear V->FF, G -> (sb,s): increase cutoff to 0.4, now t0 = 0.4^2. IF: collinear F->VF, G -> (sb,s): increase cutoff to 0.4, now t0 = 0.4^2. IF: collinear F->VF, G -> (sb,s): increase cutoff to 0.4, now t0 = 0.4^2. II: collinear F->VF, G -> (sb,s): increase cutoff to 0.4, now t0 = 0.4^2. II: collinear F->VF, G -> (sb,s): increase cutoff to 0.4, now t0 = 0.4^2. FF: collinear V->FF, G -> (cb,c): increase cutoff to 2.84, now t0 = 2.84^2. FF: collinear V->FF, G -> (cb,c): increase cutoff to 2.84, now t0 = 2.84^2. FI: collinear V->FF, G -> (cb,c): increase cutoff to 2.84, now t0 = 2.84^2. FI: collinear V->FF, G -> (cb,c): increase cutoff to 2.84, now t0 = 2.84^2. IF: collinear F->VF, G -> (cb,c): increase cutoff to 2.84, now t0 = 2.84^2. IF: collinear F->VF, G -> (cb,c): increase cutoff to 2.84, now t0 = 2.84^2. II: collinear F->VF, G -> (cb,c): increase cutoff to 2.84, now t0 = 2.84^2. II: collinear F->VF, G -> (cb,c): increase cutoff to 2.84, now t0 = 2.84^2. FF: collinear V->FF, G -> (bb,b): increase cutoff to 9.84, now t0 = 9.84^2. FF: collinear V->FF, G -> (bb,b): increase cutoff to 9.84, now t0 = 9.84^2. FI: collinear V->FF, G -> (bb,b): increase cutoff to 9.84, now t0 = 9.84^2. FI: collinear V->FF, G -> (bb,b): increase cutoff to 9.84, now t0 = 9.84^2. IF: collinear F->VF, G -> (bb,b): increase cutoff to 9.84, now t0 = 9.84^2. IF: collinear F->VF, G -> (bb,b): increase cutoff to 9.84, now t0 = 9.84^2. II: collinear F->VF, G -> (bb,b): increase cutoff to 9.84, now t0 = 9.84^2. II: collinear F->VF, G -> (bb,b): increase cutoff to 9.84, now t0 = 9.84^2. FF: Soft, d -> (d,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, d -> (d,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, d -> (d,G): increase cutoff to 1, now t0 = 1^2. FF: Soft, db -> (db,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, db -> (db,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, db -> (db,G): increase cutoff to 1, now t0 = 1^2. FF: Soft, u -> (u,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, u -> (u,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, u -> (u,G): increase cutoff to 1, now t0 = 1^2. FF: Soft, ub -> (ub,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, ub -> (ub,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, ub -> (ub,G): increase cutoff to 1, now t0 = 1^2. FF: Soft, s -> (s,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, s -> (s,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, s -> (s,G): increase cutoff to 1, now t0 = 1^2. FF: Soft, sb -> (sb,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, sb -> (sb,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, sb -> (sb,G): increase cutoff to 1, now t0 = 1^2. FF: Soft, c -> (c,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, c -> (c,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, c -> (c,G): increase cutoff to 1, now t0 = 1^2. FF: Soft, cb -> (cb,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, cb -> (cb,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, cb -> (cb,G): increase cutoff to 1, now t0 = 1^2. FF: Soft, b -> (b,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, b -> (b,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, b -> (b,G): increase cutoff to 1, now t0 = 1^2. FF: Soft, bb -> (bb,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, bb -> (bb,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, bb -> (bb,G): increase cutoff to 1, now t0 = 1^2. FF: Soft, t -> (t,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, t -> (t,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, t -> (t,G): increase cutoff to 1, now t0 = 1^2. FF: Soft, tb -> (tb,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, tb -> (tb,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, tb -> (tb,G): increase cutoff to 1, now t0 = 1^2. FF: Soft, G -> (G,G): increase cutoff to 1, now t0 = 1^2. FF: Soft, G -> (G,G): increase cutoff to 1, now t0 = 1^2. FF: collinear V->VV, G -> (G,G): increase cutoff to 1, now t0 = 1^2. FF: collinear V->VV, G -> (G,G): increase cutoff to 1, now t0 = 1^2. FF: collinear V->FF, G -> (db,d): increase cutoff to 1, now t0 = 1^2. FF: collinear V->FF, G -> (db,d): increase cutoff to 1, now t0 = 1^2. FF: collinear V->FF, G -> (ub,u): increase cutoff to 1, now t0 = 1^2. FF: collinear V->FF, G -> (ub,u): increase cutoff to 1, now t0 = 1^2. FF: collinear V->FF, G -> (sb,s): increase cutoff to 1, now t0 = 1^2. FF: collinear V->FF, G -> (sb,s): increase cutoff to 1, now t0 = 1^2. FF: collinear V->FF, G -> (cb,c): increase cutoff to 1, now t0 = 2.84^2. FF: collinear V->FF, G -> (cb,c): increase cutoff to 1, now t0 = 2.84^2. FF: collinear V->FF, G -> (bb,b): increase cutoff to 1, now t0 = 9.84^2. FF: collinear V->FF, G -> (bb,b): increase cutoff to 1, now t0 = 9.84^2. FI: Soft, d -> (d,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, d -> (d,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, d -> (d,G): increase cutoff to 1, now t0 = 1^2. FI: Soft, db -> (db,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, db -> (db,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, db -> (db,G): increase cutoff to 1, now t0 = 1^2. FI: Soft, u -> (u,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, u -> (u,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, u -> (u,G): increase cutoff to 1, now t0 = 1^2. FI: Soft, ub -> (ub,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, ub -> (ub,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, ub -> (ub,G): increase cutoff to 1, now t0 = 1^2. FI: Soft, s -> (s,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, s -> (s,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, s -> (s,G): increase cutoff to 1, now t0 = 1^2. FI: Soft, sb -> (sb,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, sb -> (sb,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, sb -> (sb,G): increase cutoff to 1, now t0 = 1^2. FI: Soft, c -> (c,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, c -> (c,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, c -> (c,G): increase cutoff to 1, now t0 = 1^2. FI: Soft, cb -> (cb,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, cb -> (cb,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, cb -> (cb,G): increase cutoff to 1, now t0 = 1^2. FI: Soft, b -> (b,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, b -> (b,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, b -> (b,G): increase cutoff to 1, now t0 = 1^2. FI: Soft, bb -> (bb,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, bb -> (bb,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, bb -> (bb,G): increase cutoff to 1, now t0 = 1^2. FI: Soft, t -> (t,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, t -> (t,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, t -> (t,G): increase cutoff to 1, now t0 = 1^2. FI: Soft, tb -> (tb,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, tb -> (tb,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, tb -> (tb,G): increase cutoff to 1, now t0 = 1^2. FI: Soft, G -> (G,G): increase cutoff to 1, now t0 = 1^2. FI: Soft, G -> (G,G): increase cutoff to 1, now t0 = 1^2. FI: collinear V->VV, G -> (G,G): increase cutoff to 1, now t0 = 1^2. FI: collinear V->VV, G -> (G,G): increase cutoff to 1, now t0 = 1^2. FI: collinear V->FF, G -> (db,d): increase cutoff to 1, now t0 = 1^2. FI: collinear V->FF, G -> (db,d): increase cutoff to 1, now t0 = 1^2. FI: collinear V->FF, G -> (ub,u): increase cutoff to 1, now t0 = 1^2. FI: collinear V->FF, G -> (ub,u): increase cutoff to 1, now t0 = 1^2. FI: collinear V->FF, G -> (sb,s): increase cutoff to 1, now t0 = 1^2. FI: collinear V->FF, G -> (sb,s): increase cutoff to 1, now t0 = 1^2. FI: collinear V->FF, G -> (cb,c): increase cutoff to 1, now t0 = 2.84^2. FI: collinear V->FF, G -> (cb,c): increase cutoff to 1, now t0 = 2.84^2. FI: collinear V->FF, G -> (bb,b): increase cutoff to 1, now t0 = 9.84^2. FI: collinear V->FF, G -> (bb,b): increase cutoff to 1, now t0 = 9.84^2. IF: Soft, d -> (d,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear V->FF, d -> (d,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->FV, d -> (d,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: Soft, db -> (db,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->FV, db -> (db,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear V->FF, db -> (db,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: Soft, u -> (u,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear V->FF, u -> (u,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->FV, u -> (u,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: Soft, ub -> (ub,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->FV, ub -> (ub,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear V->FF, ub -> (ub,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: Soft, s -> (s,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear V->FF, s -> (s,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->FV, s -> (s,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: Soft, sb -> (sb,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->FV, sb -> (sb,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear V->FF, sb -> (sb,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: Soft, c -> (c,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear V->FF, c -> (c,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->FV, c -> (c,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: Soft, cb -> (cb,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->FV, cb -> (cb,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear V->FF, cb -> (cb,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: Soft, b -> (b,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear V->FF, b -> (b,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->FV, b -> (b,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: Soft, bb -> (bb,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->FV, bb -> (bb,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear V->FF, bb -> (bb,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: Soft, t -> (t,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear V->FF, t -> (t,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->FV, t -> (t,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: Soft, tb -> (tb,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->FV, tb -> (tb,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear V->FF, tb -> (tb,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: Soft, G -> (G,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: Soft, G -> (G,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear V->VV, G -> (G,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear V->VV, G -> (G,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->VF, G -> (db,d): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->VF, G -> (db,d): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->VF, G -> (ub,u): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->VF, G -> (ub,u): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->VF, G -> (sb,s): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->VF, G -> (sb,s): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->VF, G -> (cb,c): increase cutoff to 0.5, now t0 = 2.84^2. IF: collinear F->VF, G -> (cb,c): increase cutoff to 0.5, now t0 = 2.84^2. IF: collinear F->VF, G -> (bb,b): increase cutoff to 0.5, now t0 = 9.84^2. IF: collinear F->VF, G -> (bb,b): increase cutoff to 0.5, now t0 = 9.84^2. II: Soft, d -> (d,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear V->FF, d -> (d,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->FV, d -> (d,G): increase cutoff to 0.5, now t0 = 0.5^2. II: Soft, db -> (db,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->FV, db -> (db,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear V->FF, db -> (db,G): increase cutoff to 0.5, now t0 = 0.5^2. II: Soft, u -> (u,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear V->FF, u -> (u,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->FV, u -> (u,G): increase cutoff to 0.5, now t0 = 0.5^2. II: Soft, ub -> (ub,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->FV, ub -> (ub,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear V->FF, ub -> (ub,G): increase cutoff to 0.5, now t0 = 0.5^2. II: Soft, s -> (s,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear V->FF, s -> (s,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->FV, s -> (s,G): increase cutoff to 0.5, now t0 = 0.5^2. II: Soft, sb -> (sb,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->FV, sb -> (sb,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear V->FF, sb -> (sb,G): increase cutoff to 0.5, now t0 = 0.5^2. II: Soft, c -> (c,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear V->FF, c -> (c,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->FV, c -> (c,G): increase cutoff to 0.5, now t0 = 0.5^2. II: Soft, cb -> (cb,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->FV, cb -> (cb,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear V->FF, cb -> (cb,G): increase cutoff to 0.5, now t0 = 0.5^2. II: Soft, b -> (b,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear V->FF, b -> (b,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->FV, b -> (b,G): increase cutoff to 0.5, now t0 = 0.5^2. II: Soft, bb -> (bb,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->FV, bb -> (bb,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear V->FF, bb -> (bb,G): increase cutoff to 0.5, now t0 = 0.5^2. II: Soft, t -> (t,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear V->FF, t -> (t,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->FV, t -> (t,G): increase cutoff to 0.5, now t0 = 0.5^2. II: Soft, tb -> (tb,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->FV, tb -> (tb,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear V->FF, tb -> (tb,G): increase cutoff to 0.5, now t0 = 0.5^2. II: Soft, G -> (G,G): increase cutoff to 0.5, now t0 = 0.5^2. II: Soft, G -> (G,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear V->VV, G -> (G,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear V->VV, G -> (G,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->VF, G -> (db,d): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->VF, G -> (db,d): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->VF, G -> (ub,u): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->VF, G -> (ub,u): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->VF, G -> (sb,s): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->VF, G -> (sb,s): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->VF, G -> (cb,c): increase cutoff to 0.5, now t0 = 2.84^2. II: collinear F->VF, G -> (cb,c): increase cutoff to 0.5, now t0 = 2.84^2. II: collinear F->VF, G -> (bb,b): increase cutoff to 0.5, now t0 = 9.84^2. II: collinear F->VF, G -> (bb,b): increase cutoff to 0.5, now t0 = 9.84^2. Alaric_KFrame_TdefII Alaric_KFrame_TdefII Alaric_KFrame_TdefII Alaric_KFrame_TdefII Alaric_KFrame_TdefFF Alaric_KFrame_TdefFF Alaric_KFrame_TdefFF Alaric_KFrame_TdefFF ####### Permutations for 2 partons ############## found 2 entries: 1th permutation = { 0 1 } 2th permutation = { 1 0 } FF: collinear V->FF, G -> (db,d): increase cutoff to 0.02, now t0 = 0.02^2. FF: collinear V->FF, G -> (db,d): increase cutoff to 0.02, now t0 = 0.02^2. FI: collinear V->FF, G -> (db,d): increase cutoff to 0.02, now t0 = 0.02^2. FI: collinear V->FF, G -> (db,d): increase cutoff to 0.02, now t0 = 0.02^2. IF: collinear F->VF, G -> (db,d): increase cutoff to 0.02, now t0 = 0.02^2. IF: collinear F->VF, G -> (db,d): increase cutoff to 0.02, now t0 = 0.02^2. II: collinear F->VF, G -> (db,d): increase cutoff to 0.02, now t0 = 0.02^2. II: collinear F->VF, G -> (db,d): increase cutoff to 0.02, now t0 = 0.02^2. FF: collinear V->FF, G -> (ub,u): increase cutoff to 0.01, now t0 = 0.01^2. FF: collinear V->FF, G -> (ub,u): increase cutoff to 0.01, now t0 = 0.01^2. FI: collinear V->FF, G -> (ub,u): increase cutoff to 0.01, now t0 = 0.01^2. FI: collinear V->FF, G -> (ub,u): increase cutoff to 0.01, now t0 = 0.01^2. IF: collinear F->VF, G -> (ub,u): increase cutoff to 0.01, now t0 = 0.01^2. IF: collinear F->VF, G -> (ub,u): increase cutoff to 0.01, now t0 = 0.01^2. II: collinear F->VF, G -> (ub,u): increase cutoff to 0.01, now t0 = 0.01^2. II: collinear F->VF, G -> (ub,u): increase cutoff to 0.01, now t0 = 0.01^2. FF: collinear V->FF, G -> (sb,s): increase cutoff to 0.4, now t0 = 0.4^2. FF: collinear V->FF, G -> (sb,s): increase cutoff to 0.4, now t0 = 0.4^2. FI: collinear V->FF, G -> (sb,s): increase cutoff to 0.4, now t0 = 0.4^2. FI: collinear V->FF, G -> (sb,s): increase cutoff to 0.4, now t0 = 0.4^2. IF: collinear F->VF, G -> (sb,s): increase cutoff to 0.4, now t0 = 0.4^2. IF: collinear F->VF, G -> (sb,s): increase cutoff to 0.4, now t0 = 0.4^2. II: collinear F->VF, G -> (sb,s): increase cutoff to 0.4, now t0 = 0.4^2. II: collinear F->VF, G -> (sb,s): increase cutoff to 0.4, now t0 = 0.4^2. FF: collinear V->FF, G -> (cb,c): increase cutoff to 2.84, now t0 = 2.84^2. FF: collinear V->FF, G -> (cb,c): increase cutoff to 2.84, now t0 = 2.84^2. FI: collinear V->FF, G -> (cb,c): increase cutoff to 2.84, now t0 = 2.84^2. FI: collinear V->FF, G -> (cb,c): increase cutoff to 2.84, now t0 = 2.84^2. IF: collinear F->VF, G -> (cb,c): increase cutoff to 2.84, now t0 = 2.84^2. IF: collinear F->VF, G -> (cb,c): increase cutoff to 2.84, now t0 = 2.84^2. II: collinear F->VF, G -> (cb,c): increase cutoff to 2.84, now t0 = 2.84^2. II: collinear F->VF, G -> (cb,c): increase cutoff to 2.84, now t0 = 2.84^2. FF: collinear V->FF, G -> (bb,b): increase cutoff to 9.84, now t0 = 9.84^2. FF: collinear V->FF, G -> (bb,b): increase cutoff to 9.84, now t0 = 9.84^2. FI: collinear V->FF, G -> (bb,b): increase cutoff to 9.84, now t0 = 9.84^2. FI: collinear V->FF, G -> (bb,b): increase cutoff to 9.84, now t0 = 9.84^2. IF: collinear F->VF, G -> (bb,b): increase cutoff to 9.84, now t0 = 9.84^2. IF: collinear F->VF, G -> (bb,b): increase cutoff to 9.84, now t0 = 9.84^2. II: collinear F->VF, G -> (bb,b): increase cutoff to 9.84, now t0 = 9.84^2. II: collinear F->VF, G -> (bb,b): increase cutoff to 9.84, now t0 = 9.84^2. FF: Soft, d -> (d,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, d -> (d,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, d -> (d,G): increase cutoff to 1, now t0 = 1^2. FF: Soft, db -> (db,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, db -> (db,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, db -> (db,G): increase cutoff to 1, now t0 = 1^2. FF: Soft, u -> (u,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, u -> (u,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, u -> (u,G): increase cutoff to 1, now t0 = 1^2. FF: Soft, ub -> (ub,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, ub -> (ub,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, ub -> (ub,G): increase cutoff to 1, now t0 = 1^2. FF: Soft, s -> (s,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, s -> (s,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, s -> (s,G): increase cutoff to 1, now t0 = 1^2. FF: Soft, sb -> (sb,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, sb -> (sb,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, sb -> (sb,G): increase cutoff to 1, now t0 = 1^2. FF: Soft, c -> (c,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, c -> (c,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, c -> (c,G): increase cutoff to 1, now t0 = 1^2. FF: Soft, cb -> (cb,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, cb -> (cb,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, cb -> (cb,G): increase cutoff to 1, now t0 = 1^2. FF: Soft, b -> (b,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, b -> (b,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, b -> (b,G): increase cutoff to 1, now t0 = 1^2. FF: Soft, bb -> (bb,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, bb -> (bb,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, bb -> (bb,G): increase cutoff to 1, now t0 = 1^2. FF: Soft, t -> (t,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, t -> (t,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, t -> (t,G): increase cutoff to 1, now t0 = 1^2. FF: Soft, tb -> (tb,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, tb -> (tb,G): increase cutoff to 1, now t0 = 1^2. FF: collinear F->FV, tb -> (tb,G): increase cutoff to 1, now t0 = 1^2. FF: Soft, G -> (G,G): increase cutoff to 1, now t0 = 1^2. FF: Soft, G -> (G,G): increase cutoff to 1, now t0 = 1^2. FF: collinear V->VV, G -> (G,G): increase cutoff to 1, now t0 = 1^2. FF: collinear V->VV, G -> (G,G): increase cutoff to 1, now t0 = 1^2. FF: collinear V->FF, G -> (db,d): increase cutoff to 1, now t0 = 1^2. FF: collinear V->FF, G -> (db,d): increase cutoff to 1, now t0 = 1^2. FF: collinear V->FF, G -> (ub,u): increase cutoff to 1, now t0 = 1^2. FF: collinear V->FF, G -> (ub,u): increase cutoff to 1, now t0 = 1^2. FF: collinear V->FF, G -> (sb,s): increase cutoff to 1, now t0 = 1^2. FF: collinear V->FF, G -> (sb,s): increase cutoff to 1, now t0 = 1^2. FF: collinear V->FF, G -> (cb,c): increase cutoff to 1, now t0 = 2.84^2. FF: collinear V->FF, G -> (cb,c): increase cutoff to 1, now t0 = 2.84^2. FF: collinear V->FF, G -> (bb,b): increase cutoff to 1, now t0 = 9.84^2. FF: collinear V->FF, G -> (bb,b): increase cutoff to 1, now t0 = 9.84^2. FI: Soft, d -> (d,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, d -> (d,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, d -> (d,G): increase cutoff to 1, now t0 = 1^2. FI: Soft, db -> (db,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, db -> (db,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, db -> (db,G): increase cutoff to 1, now t0 = 1^2. FI: Soft, u -> (u,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, u -> (u,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, u -> (u,G): increase cutoff to 1, now t0 = 1^2. FI: Soft, ub -> (ub,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, ub -> (ub,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, ub -> (ub,G): increase cutoff to 1, now t0 = 1^2. FI: Soft, s -> (s,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, s -> (s,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, s -> (s,G): increase cutoff to 1, now t0 = 1^2. FI: Soft, sb -> (sb,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, sb -> (sb,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, sb -> (sb,G): increase cutoff to 1, now t0 = 1^2. FI: Soft, c -> (c,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, c -> (c,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, c -> (c,G): increase cutoff to 1, now t0 = 1^2. FI: Soft, cb -> (cb,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, cb -> (cb,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, cb -> (cb,G): increase cutoff to 1, now t0 = 1^2. FI: Soft, b -> (b,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, b -> (b,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, b -> (b,G): increase cutoff to 1, now t0 = 1^2. FI: Soft, bb -> (bb,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, bb -> (bb,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, bb -> (bb,G): increase cutoff to 1, now t0 = 1^2. FI: Soft, t -> (t,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, t -> (t,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, t -> (t,G): increase cutoff to 1, now t0 = 1^2. FI: Soft, tb -> (tb,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, tb -> (tb,G): increase cutoff to 1, now t0 = 1^2. FI: collinear F->FV, tb -> (tb,G): increase cutoff to 1, now t0 = 1^2. FI: Soft, G -> (G,G): increase cutoff to 1, now t0 = 1^2. FI: Soft, G -> (G,G): increase cutoff to 1, now t0 = 1^2. FI: collinear V->VV, G -> (G,G): increase cutoff to 1, now t0 = 1^2. FI: collinear V->VV, G -> (G,G): increase cutoff to 1, now t0 = 1^2. FI: collinear V->FF, G -> (db,d): increase cutoff to 1, now t0 = 1^2. FI: collinear V->FF, G -> (db,d): increase cutoff to 1, now t0 = 1^2. FI: collinear V->FF, G -> (ub,u): increase cutoff to 1, now t0 = 1^2. FI: collinear V->FF, G -> (ub,u): increase cutoff to 1, now t0 = 1^2. FI: collinear V->FF, G -> (sb,s): increase cutoff to 1, now t0 = 1^2. FI: collinear V->FF, G -> (sb,s): increase cutoff to 1, now t0 = 1^2. FI: collinear V->FF, G -> (cb,c): increase cutoff to 1, now t0 = 2.84^2. FI: collinear V->FF, G -> (cb,c): increase cutoff to 1, now t0 = 2.84^2. FI: collinear V->FF, G -> (bb,b): increase cutoff to 1, now t0 = 9.84^2. FI: collinear V->FF, G -> (bb,b): increase cutoff to 1, now t0 = 9.84^2. IF: Soft, d -> (d,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear V->FF, d -> (d,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->FV, d -> (d,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: Soft, db -> (db,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->FV, db -> (db,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear V->FF, db -> (db,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: Soft, u -> (u,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear V->FF, u -> (u,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->FV, u -> (u,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: Soft, ub -> (ub,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->FV, ub -> (ub,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear V->FF, ub -> (ub,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: Soft, s -> (s,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear V->FF, s -> (s,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->FV, s -> (s,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: Soft, sb -> (sb,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->FV, sb -> (sb,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear V->FF, sb -> (sb,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: Soft, c -> (c,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear V->FF, c -> (c,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->FV, c -> (c,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: Soft, cb -> (cb,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->FV, cb -> (cb,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear V->FF, cb -> (cb,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: Soft, b -> (b,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear V->FF, b -> (b,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->FV, b -> (b,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: Soft, bb -> (bb,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->FV, bb -> (bb,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear V->FF, bb -> (bb,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: Soft, t -> (t,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear V->FF, t -> (t,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->FV, t -> (t,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: Soft, tb -> (tb,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->FV, tb -> (tb,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear V->FF, tb -> (tb,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: Soft, G -> (G,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: Soft, G -> (G,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear V->VV, G -> (G,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear V->VV, G -> (G,G): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->VF, G -> (db,d): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->VF, G -> (db,d): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->VF, G -> (ub,u): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->VF, G -> (ub,u): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->VF, G -> (sb,s): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->VF, G -> (sb,s): increase cutoff to 0.5, now t0 = 0.5^2. IF: collinear F->VF, G -> (cb,c): increase cutoff to 0.5, now t0 = 2.84^2. IF: collinear F->VF, G -> (cb,c): increase cutoff to 0.5, now t0 = 2.84^2. IF: collinear F->VF, G -> (bb,b): increase cutoff to 0.5, now t0 = 9.84^2. IF: collinear F->VF, G -> (bb,b): increase cutoff to 0.5, now t0 = 9.84^2. II: Soft, d -> (d,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear V->FF, d -> (d,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->FV, d -> (d,G): increase cutoff to 0.5, now t0 = 0.5^2. II: Soft, db -> (db,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->FV, db -> (db,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear V->FF, db -> (db,G): increase cutoff to 0.5, now t0 = 0.5^2. II: Soft, u -> (u,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear V->FF, u -> (u,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->FV, u -> (u,G): increase cutoff to 0.5, now t0 = 0.5^2. II: Soft, ub -> (ub,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->FV, ub -> (ub,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear V->FF, ub -> (ub,G): increase cutoff to 0.5, now t0 = 0.5^2. II: Soft, s -> (s,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear V->FF, s -> (s,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->FV, s -> (s,G): increase cutoff to 0.5, now t0 = 0.5^2. II: Soft, sb -> (sb,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->FV, sb -> (sb,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear V->FF, sb -> (sb,G): increase cutoff to 0.5, now t0 = 0.5^2. II: Soft, c -> (c,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear V->FF, c -> (c,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->FV, c -> (c,G): increase cutoff to 0.5, now t0 = 0.5^2. II: Soft, cb -> (cb,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->FV, cb -> (cb,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear V->FF, cb -> (cb,G): increase cutoff to 0.5, now t0 = 0.5^2. II: Soft, b -> (b,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear V->FF, b -> (b,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->FV, b -> (b,G): increase cutoff to 0.5, now t0 = 0.5^2. II: Soft, bb -> (bb,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->FV, bb -> (bb,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear V->FF, bb -> (bb,G): increase cutoff to 0.5, now t0 = 0.5^2. II: Soft, t -> (t,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear V->FF, t -> (t,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->FV, t -> (t,G): increase cutoff to 0.5, now t0 = 0.5^2. II: Soft, tb -> (tb,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->FV, tb -> (tb,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear V->FF, tb -> (tb,G): increase cutoff to 0.5, now t0 = 0.5^2. II: Soft, G -> (G,G): increase cutoff to 0.5, now t0 = 0.5^2. II: Soft, G -> (G,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear V->VV, G -> (G,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear V->VV, G -> (G,G): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->VF, G -> (db,d): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->VF, G -> (db,d): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->VF, G -> (ub,u): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->VF, G -> (ub,u): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->VF, G -> (sb,s): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->VF, G -> (sb,s): increase cutoff to 0.5, now t0 = 0.5^2. II: collinear F->VF, G -> (cb,c): increase cutoff to 0.5, now t0 = 2.84^2. II: collinear F->VF, G -> (cb,c): increase cutoff to 0.5, now t0 = 2.84^2. II: collinear F->VF, G -> (bb,b): increase cutoff to 0.5, now t0 = 9.84^2. II: collinear F->VF, G -> (bb,b): increase cutoff to 0.5, now t0 = 9.84^2. Shower_Handler initialised. +-----------------------------------------+ | X X X XXXX XXX XXX XXX | | X X XX XX X X X X X X | | X X X X X XXX X XXX X X XXX XXX | | XXXXX X X X X X X X X X | | X X X X XXXX XXX XXX XXX | +-----------------------------------------+ | please cite: JHEP 0202:044,2002 | +-----------------------------------------+ Matrix_Element_Handler::Matrix_Element_Handler(): Set pilot run mode to 0. ME_Generator_Base::SetPSMasses(): Massive PS flavours for Comix: (none) +----------------------------------+ | | | CCC OOO M M I X X | | C O O MM MM I X X | | C O O M M M I X | | C O O M M I X X | | CCC OOO M M I X X | | | +==================================+ | Color dressed Matrix Elements | | http://comix.freacafe.de | | please cite JHEP12(2008)039 | +----------------------------------+ ME_Generator_Base::SetPSMasses(): Massive PS flavours for Amegic: (none) ME_Generator_Base::SetPSMasses(): Massive PS flavours for Internal: (none) Matrix_Element_Handler::BuildProcesses(): 3 ME generators, 1 process blocks. Matrix_Element_Handler::BuildProcesses(): Setting up processes ............ done ( 55 MB, 0s / 0s ). Matrix_Element_Handler::InitializeProcesses(): Performing tests ............ done ( 55 MB, 0s / 0s ). Matrix_Element_Handler::InitializeProcesses(): Initializing scales done ( 55 MB, 0s / 0s ). Initialized the Matrix_Element_Handler for the hard processes. Initialized the Beam_Remnant_Handler. ME_Generator_Base::SetPSMasses(): Massive PS flavours for Amisic::Processes: (none) MI_Handler::MI_Handler(id = 2, name = Amisic, type = 1) Underlying event/multiple interactions handler: MI[2]: on = 1 (type = 1, Amisic) Soft-collision handlers: Type[2]: None Hadron_Init::Init(): Initializing kf table for hadrons. Pythia8_Hadronisation::Pythia8_Hadronisation:("Initialising Pythia8 hadronisation interface") Pythia8_Hadronisation::ApplyPythiaSettings:("Applying Pythia8 settings") Pythia8_Hadronisation::HarmonizeMasses:("Harmonizing particle masses and widths!") Pythia8_Hadronisation::ModifyPythiaValues:("Changing Pythia Values") Initialized the Fragmentation_Handler. Initialized the Hadron_Decay_Handler, Decay model = HADRONS++ Initialized the Soft_Photon_Handler. Initialized the Reweighting. ISR_Channels::CheckForStructuresFromME for 0: (none) Read in channels from directory: Results/Comix/MC_2_2__j__j__j__j Process_Group::CalculateTotalXSec(): Calculate xs for '2_2__j__j__j__j' (Comix) 2_2__j__j__j__j : 5.81404e+09 pb +- ( 7.55324e+07 pb = 1.29914 % )  exp. eff: 2.39841e-05 % reduce max for 2_2__j__j__j__j to 1 ( eps = 0.001 -> exp. eff 2.39841e-07 ) ---------------------------------------------------------- -- SHERPA generates events with the following structure -- ---------------------------------------------------------- Event generation : Weighted Perturbative : Signal_Processes Perturbative : Minimum_Bias: None Perturbative : Hard_Decays Perturbative : Jet_Evolution:CFP Perturbative : Lepton_FS_QED_Corrections:None Perturbative : Multiple_Interactions: Amisic Hadronization : Beam_Remnants:Parametrised Hadronization : Hadronization:Pythia8 Hadronization : Hadron_Decays Userhook : Analysis : Rivet --------------------------------------------------------- #-------------------------------------------------------------------------- # FastJet release 3.3.2 [fjcore] # M. Cacciari, G.P. Salam and G. Soyez # A software package for jet finding and analysis at colliders # http://fastjet.fr # # Please cite EPJC72(2012)1896 [arXiv:1111.6097] if you use this package # for scientific work and optionally PLB641(2006)57 [hep-ph/0512210]. # # FastJet is provided without warranty under the terms of the GNU GPLv2. # It uses T. Chan's closest pair algorithm, S. Fortune's Voronoi code # and 3rd party plugin jet algorithms. See COPYING file for details. #-------------------------------------------------------------------------- Event 1 ( 4s elapsed / 5d 11h 23m 15s left ) -> ETA: Sun Dec 10 00:03 XS = 6.9408 pb +- ( 6.9408 pb = 100 % ) Event 2 ( 4s elapsed / 2d 18h 48m 15s left ) -> ETA: Thu Dec 07 07:28 XS = 335.991 pb +- ( 329.05 pb = 97 % ) Event 3 ( 4s elapsed / 1d 20h 54m 21s left ) -> ETA: Wed Dec 06 09:34 XS = 4.70568e+08 pb +- ( 4.70567e+08 pb = 99 % ) Event 4 ( 4s elapsed / 1d 10h 1m 35s left ) -> ETA: Tue Dec 05 22:41 XS = 3.76459e+08 pb +- ( 3.76453e+08 pb = 99 % ) Event 5 ( 4s elapsed / 1d 3h 33m 15s left ) -> ETA: Tue Dec 05 16:13 XS = 2.35287e+08 pb +- ( 2.35283e+08 pb = 99 % ) Event 6 ( 5s elapsed / 23h 11m 34s left ) -> ETA: Tue Dec 05 11:51 XS = 2.12992e+08 pb +- ( 1.87101e+08 pb = 87 % ) Event 7 ( 5s elapsed / 20h 2m 17s left ) -> ETA: Tue Dec 05 08:42 XS = 2.04405e+08 pb +- ( 1.69457e+08 pb = 82 % ) Event 8 ( 5s elapsed / 17h 34m 4s left ) -> ETA: Tue Dec 05 06:14 XS = 1.87371e+08 pb +- ( 1.55627e+08 pb = 83 % ) Event 9 ( 5s elapsed / 15h 42m 30s left ) -> ETA: Tue Dec 05 04:22 XS = 1.72959e+08 pb +- ( 1.4388e+08 pb = 83 % ) Event 10 ( 5s elapsed / 14h 13m 14s left ) -> ETA: Tue Dec 05 02:53 XS = 1.97035e+08 pb +- ( 1.35365e+08 pb = 68 % ) Event 20 ( 5s elapsed / 7h 45m 44s left ) -> ETA: Mon Dec 04 20:25 XS = 1.45928e+09 pb +- ( 9.65776e+08 pb = 66 % ) Event 30 ( 6s elapsed / 5h 35m 27s left ) -> ETA: Mon Dec 04 18:15 XS = 1.04446e+09 pb +- ( 6.62378e+08 pb = 63 % ) Event 40 ( 6s elapsed / 4h 22m 23s left ) -> ETA: Mon Dec 04 17:02 XS = 7.30255e+08 pb +- ( 4.57569e+08 pb = 62 % ) Event 50 ( 6s elapsed / 3h 43m 33s left ) -> ETA: Mon Dec 04 16:23 XS = 5.66127e+08 pb +- ( 3.4953e+08 pb = 61 % ) Event 60 ( 7s elapsed / 3h 14m 36s left ) -> ETA: Mon Dec 04 15:54 XS = 5.87262e+08 pb +- ( 3.12474e+08 pb = 53 % ) Event 70 ( 7s elapsed / 2h 53m 41s left ) -> ETA: Mon Dec 04 15:33 XS = 6.17029e+08 pb +- ( 2.87531e+08 pb = 46 % ) Event 80 ( 7s elapsed / 2h 40m 4s left ) -> ETA: Mon Dec 04 15:20 XS = 6.92808e+08 pb +- ( 2.8796e+08 pb = 41 % ) Event 90 ( 7s elapsed / 2h 27m 16s left ) -> ETA: Mon Dec 04 15:07 XS = 8.49325e+08 pb +- ( 2.93732e+08 pb = 34 % ) Event 100 ( 8s elapsed / 2h 21m 11s left ) -> ETA: Mon Dec 04 15:01 XS = 2.3705e+09 pb +- ( 1.58445e+09 pb = 66 % ) Event 200 ( 12s elapsed / 1h 39m 52s left ) -> ETA: Mon Dec 04 14:20 XS = 6.72366e+09 pb +- ( 2.74004e+09 pb = 40 % ) Event 300 ( 15s elapsed / 1h 27m 17s left ) -> ETA: Mon Dec 04 14:07 XS = 5.58969e+09 pb +- ( 1.87115e+09 pb = 33 % ) Event 400 ( 19s elapsed / 1h 19m 13s left ) -> ETA: Mon Dec 04 13:59 XS = 5.23121e+09 pb +- ( 1.53341e+09 pb = 29 % ) Event 500 ( 22s elapsed / 1h 15m 45s left ) -> ETA: Mon Dec 04 13:56 XS = 4.91353e+09 pb +- ( 1.27688e+09 pb = 25 % ) Warning: Kinematics_Generator::TransverseKinematicsHH: Not able to create the breakup kinematics for Particle List with 3 elements [I] 1 u 5 ( -> 2) [( 2.0447e+02,-0.0000e+00,-0.0000e+00, 2.0447e+02), p^2= 0.0000e+00, m= 3.0000e-01] (610, 0) 0 [I] 1 u 40 ( -> 4) [( 1.2847e+03,-0.0000e+00,-0.0000e+00, 1.2847e+03), p^2= 0.0000e+00, m= 3.0000e-01] (626, 0) 0 [I] 1 c 67 ( -> 6) [( 2.0854e+02,-0.0000e+00,-0.0000e+00, 2.0854e+02), p^2= 0.0000e+00, m= 1.8000e+00] (648, 0) 0 and Particle List with 3 elements [I] 1 d 6 ( -> 2) [( 3.9433e+03,-0.0000e+00,-0.0000e+00,-3.9433e+03), p^2= 0.0000e+00, m= 3.0000e-01] (601, 0) 1 [I] 1 G 41 ( -> 4) [( 5.5505e+01,-0.0000e+00,-0.0000e+00,-5.5505e+01), p^2= 0.0000e+00, m= 0.0000e+00] (630,601) 1 [I] 1 u 68 ( -> 6) [( 6.0300e-01,-0.0000e+00,-0.0000e+00,-6.0300e-01), p^2= 0.0000e+00, m= 3.0000e-01] (646, 0) 1 and the corresponding remnants are Particle List with 3 elements [B] 1 ud_0 78 ( -> ) [( 1.2534e+03, 0.0000e+00, 0.0000e+00, 1.2534e+03), p^2= 1.5019e-01, m= 5.7933e-01] ( 0,648) 0 [B] 1 cb 74 ( -> ) [( 9.6936e+00, 0.0000e+00, 0.0000e+00, 9.6936e+00), p^2= 8.9828e-06, m= 0.0000e+00] ( 0,610) 0 [B] 1 ub 35 ( -> ) [( 1.0391e+03, 0.0000e+00, 0.0000e+00, 1.0391e+03), p^2= 1.0322e-01, m= 0.0000e+00] ( 0,626) 0 and Particle List with 2 elements [B] 1 uu_1 79 ( -> ) [( 0.0000e+00, 0.0000e+00, 0.0000e+00,-0.0000e+00), p^2= 0.0000e+00, m= 7.7133e-01] ( 0,646) 1 [B] 1 ub 75 ( -> ) [( 5.6621e-01, 0.0000e+00, 0.0000e+00,-5.6610e-01), p^2= 1.2460e-04, m= 0.0000e+00] ( 0,630) 1 Event 600 ( 26s elapsed / 1h 13m 15s left ) -> ETA: Mon Dec 04 13:53 XS = 5.42391e+09 pb +- ( 1.25397e+09 pb = 23 % ) Event 700 ( 30s elapsed / 1h 11m 11s left ) -> ETA: Mon Dec 04 13:51 XS = 5.31021e+09 pb +- ( 1.09965e+09 pb = 20 % ) Warning: Kinematics_Generator::TransverseKinematicsHH: Not able to create the breakup kinematics for Particle List with 4 elements [I] 1 G 5 ( -> 2) [( 1.5431e+03,-0.0000e+00,-0.0000e+00, 1.5431e+03), p^2= 0.0000e+00, m= 0.0000e+00] (601,603) 0 [I] 1 G 66 ( -> 4) [( 9.2851e+01,-0.0000e+00,-0.0000e+00, 9.2851e+01), p^2= 0.0000e+00, m= 0.0000e+00] (603,671) 0 [I] 1 ub 95 ( -> 6) [( 3.9634e+02,-0.0000e+00,-0.0000e+00, 3.9634e+02), p^2= 0.0000e+00, m= 3.0000e-01] ( 0,681) 0 [I] 1 G 123 ( -> 8) [( 4.0179e+02,-0.0000e+00,-0.0000e+00, 4.0179e+02), p^2= 0.0000e+00, m= 0.0000e+00] (681,696) 0 and Particle List with 4 elements [I] 1 G 6 ( -> 2) [( 3.4389e+03,-0.0000e+00,-0.0000e+00,-3.4389e+03), p^2= 0.0000e+00, m= 0.0000e+00] (604,602) 1 [I] 1 G 67 ( -> 4) [( 4.6740e+02,-0.0000e+00,-0.0000e+00,-4.6740e+02), p^2= 0.0000e+00, m= 0.0000e+00] (656,604) 1 [I] 1 G 96 ( -> 6) [( 9.0795e+01,-0.0000e+00,-0.0000e+00,-9.0795e+01), p^2= 0.0000e+00, m= 0.0000e+00] (602,688) 1 [I] 1 s 124 ( -> 8) [( 1.6264e+00,-0.0000e+00,-0.0000e+00,-1.6264e+00), p^2= 0.0000e+00, m= 4.0000e-01] (694, 0) 1 and the corresponding remnants are Particle List with 3 elements [B] 1 uu_1 136 ( -> ) [( 1.5543e+03, 0.0000e+00, 0.0000e+00, 1.5543e+03), p^2= 3.3956e-01, m= 7.7133e-01] ( 0,601) 0 [B] 1 u 118 ( -> ) [( 6.5379e-01, 0.0000e+00, 0.0000e+00, 6.5379e-01), p^2= 6.0077e-08, m= 0.0000e+00] (671, 0) 0 [B] 1 d 135 ( -> ) [( 1.0913e+01, 0.0000e+00, 0.0000e+00, 1.0913e+01), p^2= 1.6738e-05, m= 0.0000e+00] (696, 0) 0 and Particle List with 3 elements [B] 1 ud_0 138 ( -> ) [( 0.0000e+00, 0.0000e+00, 0.0000e+00,-0.0000e+00), p^2= 0.0000e+00, m= 5.7933e-01] ( 0,694) 1 [B] 1 sb 132 ( -> ) [( 8.2067e-01, 0.0000e+00, 0.0000e+00,-8.2060e-01), p^2= 1.1522e-04, m= 0.0000e+00] ( 0,656) 1 [B] 1 u 137 ( -> ) [( 4.6576e-01, 0.0000e+00, 0.0000e+00,-4.6572e-01), p^2= 3.7112e-05, m= 0.0000e+00] (688, 0) 1 Event 800 ( 33s elapsed / 1h 9m 33s left ) -> ETA: Mon Dec 04 13:50 XS = 5.38149e+09 pb +- ( 1.0473e+09 pb = 19 % ) Event 900 ( 37s elapsed / 1h 8m 21s left ) -> ETA: Mon Dec 04 13:49 XS = 5.15706e+09 pb +- ( 9.43227e+08 pb = 18 % ) Event 1000 ( 40s elapsed / 1h 7m 9s left ) -> ETA: Mon Dec 04 13:47 XS = 5.23786e+09 pb +- ( 8.96427e+08 pb = 17 % ) Warning: Kinematics_Generator::TransverseKinematicsHH: Not able to create the breakup kinematics for Particle List with 4 elements [I] 1 G 5 ( -> 2) [( 2.9786e+02,-0.0000e+00,-0.0000e+00, 2.9786e+02), p^2= 0.0000e+00, m= 0.0000e+00] (635,634) 0 [I] 1 db 46 ( -> 4) [( 2.9803e+02,-0.0000e+00,-0.0000e+00, 2.9803e+02), p^2= 0.0000e+00, m= 3.0000e-01] ( 0,635) 0 [I] 1 G 60 ( -> 6) [( 7.5135e+01,-0.0000e+00,-0.0000e+00, 7.5135e+01), p^2= 0.0000e+00, m= 0.0000e+00] (654,649) 0 [I] 1 G 72 ( -> 8) [( 1.2333e+02,-0.0000e+00,-0.0000e+00, 1.2333e+02), p^2= 0.0000e+00, m= 0.0000e+00] (634,668) 0 and Particle List with 4 elements [I] 1 G 6 ( -> 2) [( 3.9919e+03,-0.0000e+00,-0.0000e+00,-3.9919e+03), p^2= 0.0000e+00, m= 0.0000e+00] (604,602) 1 [I] 1 G 47 ( -> 4) [( 2.8218e+00,-0.0000e+00,-0.0000e+00,-2.8218e+00), p^2= 0.0000e+00, m= 0.0000e+00] (648,604) 1 [I] 1 ub 61 ( -> 6) [( 1.6120e+00,-0.0000e+00,-0.0000e+00,-1.6120e+00), p^2= 0.0000e+00, m= 3.0000e-01] ( 0,650) 1 [I] 1 G 73 ( -> 8) [( 2.1040e+00,-0.0000e+00,-0.0000e+00,-2.1040e+00), p^2= 0.0000e+00, m= 0.0000e+00] (664,648) 1 and the corresponding remnants are Particle List with 3 elements [B] 1 ud_0 83 ( -> ) [( 3.0864e+03, 0.0000e+00, 0.0000e+00, 3.0864e+03), p^2= 6.5402e-01, m= 5.7933e-01] ( 0,654) 0 [B] 1 d 55 ( -> ) [( 3.8875e+00, 0.0000e+00, 0.0000e+00, 3.8875e+00), p^2= 1.0376e-06, m= 0.0000e+00] (649, 0) 0 [B] 1 u 82 ( -> ) [( 1.1535e+02, 0.0000e+00, 0.0000e+00, 1.1535e+02), p^2= 9.1356e-04, m= 0.0000e+00] (668, 0) 0 and Particle List with 3 elements [B] 1 uu_1 85 ( -> ) [( 0.0000e+00, 0.0000e+00, 0.0000e+00,-0.0000e+00), p^2= 0.0000e+00, m= 7.7133e-01] ( 0,664) 1 [B] 1 u 67 ( -> ) [( 5.1896e-01, 0.0000e+00, 0.0000e+00,-5.1892e-01), p^2= 3.8903e-05, m= 0.0000e+00] (602, 0) 1 [B] 1 d 84 ( -> ) [( 1.0046e+00, 0.0000e+00, 0.0000e+00,-1.0046e+00), p^2= 1.4579e-04, m= 0.0000e+00] (650, 0) 1 Warning: Kinematics_Generator::TransverseKinematicsHH: Not able to create the breakup kinematics for Particle List with 2 elements [I] 1 u 6 ( -> 2) [( 3.9958e+03,-0.0000e+00,-0.0000e+00, 3.9958e+03), p^2= 0.0000e+00, m= 3.0000e-01] (606, 0) 0 [I] 1 ub 34 ( -> 4) [( 3.1806e+00,-0.0000e+00,-0.0000e+00, 3.1806e+00), p^2= 0.0000e+00, m= 3.0000e-01] ( 0,606) 0 and Particle List with 2 elements [I] 1 u 5 ( -> 2) [( 5.9234e+02,-0.0000e+00,-0.0000e+00,-5.9234e+02), p^2= 0.0000e+00, m= 3.0000e-01] (619, 0) 1 [I] 1 G 35 ( -> 4) [( 1.4016e+03,-0.0000e+00,-0.0000e+00,-1.4016e+03), p^2= 0.0000e+00, m= 0.0000e+00] (632,619) 1 and the corresponding remnants are Particle List with 2 elements [B] 1 ud_0 46 ( -> ) [( 0.0000e+00, 0.0000e+00, 0.0000e+00, 0.0000e+00), p^2= 0.0000e+00, m= 5.7933e-01] ( 0,636) 0 [B] 1 u 43 ( -> ) [( 1.0524e+00, 0.0000e+00, 0.0000e+00, 1.0523e+00), p^2= 2.3161e-04, m= 0.0000e+00] (636, 0) 0 and Particle List with 1 elements [B] 1 ud_0 47 ( -> ) [( 2.0060e+03, 0.0000e+00, 0.0000e+00,-2.0060e+03), p^2= 4.4151e-01, m= 5.7933e-01] ( 0,632) 1 Warning: Kinematics_Generator::TransverseKinematicsHH: Not able to create the breakup kinematics for Particle List with 2 elements [I] 1 ub 6 ( -> 2) [( 3.7437e+03,-0.0000e+00,-0.0000e+00, 3.7437e+03), p^2= 0.0000e+00, m= 3.0000e-01] ( 0,601) 0 [I] 1 u 61 ( -> 4) [( 1.9236e+02,-0.0000e+00,-0.0000e+00, 1.9236e+02), p^2= 0.0000e+00, m= 3.0000e-01] (601, 0) 0 and Particle List with 2 elements [I] 1 d 5 ( -> 2) [( 3.9963e+03,-0.0000e+00,-0.0000e+00,-3.9963e+03), p^2= 0.0000e+00, m= 3.0000e-01] (601, 0) 1 [I] 1 ub 62 ( -> 4) [( 2.3128e+00,-0.0000e+00,-0.0000e+00,-2.3128e+00), p^2= 0.0000e+00, m= 3.0000e-01] ( 0,647) 1 and the corresponding remnants are Particle List with 2 elements [B] 1 ud_0 71 ( -> ) [( 5.8100e+01, 0.0000e+00, 0.0000e+00, 5.8100e+01), p^2= 1.1616e-02, m= 5.7933e-01] ( 0,643) 0 [B] 1 u 56 ( -> ) [( 5.8553e+00, 0.0000e+00, 0.0000e+00, 5.8553e+00), p^2= 1.1798e-04, m= 0.0000e+00] (643, 0) 0 and Particle List with 2 elements [B] 1 uu_1 72 ( -> ) [( 0.0000e+00, 0.0000e+00, 0.0000e+00,-0.0000e+00), p^2= 0.0000e+00, m= 7.7133e-01] ( 0,601) 1 [B] 1 u 68 ( -> ) [( 1.4229e+00, 0.0000e+00, 0.0000e+00,-1.4228e+00), p^2= 3.1315e-04, m= 0.0000e+00] (647, 0) 1 Event 2000 ( 1m 16s elapsed / 1h 2m 46s left ) -> ETA: Mon Dec 04 13:44 XS = 4.61214e+09 pb +- ( 5.49015e+08 pb = 11 % ) Pythia8 hadronisation failed. Warning: Kinematics_Generator::TransverseKinematicsHH reduced overall prescale for kt to scale = 0.1 Event 3000 ( 1m 52s elapsed / 1h 33s left ) -> ETA: Mon Dec 04 13:42 XS = 5.03311e+09 pb +- ( 4.93604e+08 pb = 9 % ) Event 4000 ( 2m 27s elapsed / 59m left ) -> ETA: Mon Dec 04 13:41 XS = 5.22706e+09 pb +- ( 4.71502e+08 pb = 9 % ) Warning: Kinematics_Generator::TransverseKinematicsHH reduced overall prescale for kt to scale = 0.1 Event 5000 ( 3m 2s elapsed / 57m 44s left ) -> ETA: Mon Dec 04 13:40 XS = 5.3995e+09 pb +- ( 4.78207e+08 pb = 8 % ) Event 6000 ( 3m 38s elapsed / 57m 8s left ) -> ETA: Mon Dec 04 13:40 XS = 5.61912e+09 pb +- ( 4.78289e+08 pb = 8 % ) Warning: Kinematics_Generator::TransverseKinematicsHH reduced overall prescale for kt to scale = 0.1 Warning: Kinematics_Generator::TransverseKinematicsHH reduced overall prescale for kt to scale = 0.1 Event 7000 ( 4m 13s elapsed / 56m 13s left ) -> ETA: Mon Dec 04 13:40 XS = 5.78229e+09 pb +- ( 4.68884e+08 pb = 8 % ) Warning: Kinematics_Generator::TransverseKinematicsHH reduced overall prescale for kt to scale = 0.1 Event 8000 ( 4m 48s elapsed / 55m 21s left ) -> ETA: Mon Dec 04 13:40 XS = 6.05695e+09 pb +- ( 4.88481e+08 pb = 8 % ) Event 9000 ( 5m 25s elapsed / 54m 55s left ) -> ETA: Mon Dec 04 13:40 XS = 5.97581e+09 pb +- ( 4.56976e+08 pb = 7 % ) Event 10000 ( 6m 1s elapsed / 54m 11s left ) -> ETA: Mon Dec 04 13:40 XS = 5.96118e+09 pb +- ( 4.24936e+08 pb = 7 % ) Pythia8 hadronisation failed. Event 20000 ( 12m 2s elapsed / 48m 8s left ) -> ETA: Mon Dec 04 13:40 XS = 5.5175e+09 pb +- ( 2.66294e+08 pb = 4 % ) Event 30000 ( 17m 59s elapsed / 41m 59s left ) -> ETA: Mon Dec 04 13:40 XS = 5.57257e+09 pb +- ( 2.07306e+08 pb = 3 % ) Pythia8 hadronisation failed. Event 40000 ( 24m 3s elapsed / 36m 5s left ) -> ETA: Mon Dec 04 13:40 XS = 5.56145e+09 pb +- ( 1.76702e+08 pb = 3 % ) Event 50000 ( 30m 1s elapsed / 30m 1s left ) -> ETA: Mon Dec 04 13:40 XS = 5.67317e+09 pb +- ( 1.57738e+08 pb = 2 % ) Pythia8 hadronisation failed. Pythia8 hadronisation failed. Event 60000 ( 36m elapsed / 24m left ) -> ETA: Mon Dec 04 13:40 XS = 5.63151e+09 pb +- ( 1.44096e+08 pb = 2 % ) Pythia8 hadronisation failed. Event 70000 ( 42m 1s elapsed / 18m left ) -> ETA: Mon Dec 04 13:40 XS = 5.62905e+09 pb +- ( 1.30633e+08 pb = 2 % ) Pythia8 hadronisation failed. Event 80000 ( 48m 3s elapsed / 12m left ) -> ETA: Mon Dec 04 13:40 XS = 5.65029e+09 pb +- ( 1.22182e+08 pb = 2 % ) Event 90000 ( 54m 6s elapsed / 6m left ) -> ETA: Mon Dec 04 13:40 XS = 5.59802e+09 pb +- ( 1.13816e+08 pb = 2 % ) Pythia8 hadronisation failed. Event 100000 ( 3609 s total ) = 2.39373e+06 evts/day In Event_Handler::Finish : Summarizing the run may take some time. Rivet_Interface::Finish(Analysis_Alaric/1070){ } -------------------------------------------------------------------------- Nominal or variation name XS [pb] RelDev AbsErr [pb] RelErr -------------------------------------------------------------------------- Nominal  5.57556e+09 0 % 1.07129e+08 1.92 % -------------------------------------------------------------------------- Return_Value::PrintStatistics(): Statistics { Generated events: 100000 Errors { From "Hadronization:Pythia8": 8 (100008) -> 0 % } New events { From "Beam_Remnants:Parametrised": 334 (100342) -> 0.3 % } } Blob_List: Momentum Fail Statistics { } Decay_Channel: Kinematics max fail statistics { } WARNING: You are using an unsupported development branch. Remnant handling yields 334 fails in creating good beam breakups. Remnant Kinematics: 334 errors (no kinematics found) and 62 warnings (scale kt down by factor of 10). WARNING: Some settings that have been defined in the input files and/or the command line have not been used. For more details, see the Settings Report. Time: 1h 13s on Mon Dec 4 13:40:19 2023 (User: 59m 58s, System: 0s, Children User: 0s, Children System: 0s)