Monte Carlo samples for the Higgs paper

  • The numbers of produced events were last updated on 11/04/2017 at 12:45
  • All samples were generated using WHIZARD 1.95 unless explicitly stated otherwise.

Luminosities for ee, γe, eγ and γγ interactions

For electron-positron ("ee") interactions, the following integrated luminosities are assumed:

  • 500 fb-1 at 350 GeV
  • 1.5 ab-1 at 1.4 TeV
  • 2 ab-1 at 3 TeV
For processes with initial-state photons from Beamstrahlung, the luminosity numbers are different. More details can be found in this presentation by A. Sailer: pdf. The instantaneous luminosities normalised to the ee luminosity are shown in the following table:
  350 GeV 1.4 TeV 3 TeV
L(ee) / L(ee) 1.0 1.0 1.0
L(eγ) / L(ee) 0.45 0.75 0.79
L(γe) / L(ee) 0.45 0.75 0.79
L(γγ) / L(ee) 0.23 0.64 0.69
WARNING: The numbers at 1.4 TeV are still preliminary and might change in the future!

Signal samples

Type Energy Detector ProdID Events planned Events produced σ [fb] Comments
ee -> hvv, h->Zgamma, Z->qq 1.4 TeV CLIC_SiD 2048 20000 20000 244.0* m(h) = 126 GeV
ee -> hvv, h->Zgamma, Z->ll 1.4 TeV CLIC_SiD 2282 20000 30000 244.0* no beam recoil, m(h) = 126 GeV
ee -> hvv, h->gammagamma 1.4 TeV CLIC_SiD 2051 20000 19000 244.0* m(h) = 126 GeV
ee -> hee inclusive 1.4 TeV CLIC_ILD 2031 100000 108500 24.47 no beam recoil, m(h) = 126 GeV
ee -> hvv inclusive 350 GeV CLIC_ILD 2028 500000 500000 51.54 no beam recoil, m(h) = 126 GeV
ee -> hvv inclusive 3 TeV CLIC_ILD 2025 2000000 2000000 415.3 no beam recoil, m(h) = 126 GeV
ee -> hvv inclusive 1.4 TeV CLIC_ILD 2022 1000000 1000000 244.1 no beam recoil, m(h) = 126 GeV
ee -> hvv inclusive 1.4 TeV CLIC_SiD 2019 1000000 1000000 244.1 no beam recoil, m(h) = 126 GeV
ee -> hvv, h->mumu 1.4 TeV CLIC_ILD 2001 20000 24000 244.1* no beam recoil, m(h) = 126 GeV
ee -> hhvv 3 TeV CLIC_ILD 1998 20000 32000 0.594 no beam recoil, m(h) = 125 GeV
ee -> hhvv 1.4 TeV CLIC_ILD 1996 20000 29000 0.149 no beam recoil, m(h) = 126 GeV
ee -> hZ, Z->qq, h->tautau 350 GeV CLIC_ILD 1555 100000 120000 93.47* no beam recoil, m(h) = 126 GeV
ee -> hZ, Z->ee 350 GeV CLIC_ILD 2085 500000 445200 4.62 no beam recoil, m(h) = 126 GeV, extended
ee -> hZ, Z->mumu 350 GeV CLIC_ILD 2088 500000 587800 4.63 no beam recoil, m(h) = 126 GeV, extended
ee -> tth, tt->lvbbqq, h->bb 1400 GeV CLIC_SiD 2441 50000 50000 0.415 Generated using Physsim, m(h) = 125 GeV, q=u,d,s,c,b, reprocessed
ee -> tth, tt->lvbbqq, h->not bb 1400 GeV CLIC_SiD 2444 50000 50000 0.303 Generated using Physsim, m(h) = 125 GeV, q=u,d,s,c,b, reprocessed
ee -> tth, tt->bbqqqq, h->bb 1400 GeV CLIC_SiD 2435 50000 50000 0.431 Generated using Physsim, m(h) = 125 GeV, q=u,d,s,c,b, reprocessed
ee -> tth, tt->bbqqqq, h->not bb 1400 GeV CLIC_SiD 2438 50000 50000 0.315 Generated using Physsim, m(h) = 125 GeV, q=u,d,s,c,b, reprocessed
ee -> hvv inclusive 3 TeV CLIC_SiD 2303 2000000 1880900 415.3 no beam recoil, m(h) = 126 GeV
ee -> hvv inclusive 1.4 TeV CLIC_SiD 2466 1000000 1000000 244.07 Template for mass measurement, m(h) = 125.95 GeV
ee -> hvv inclusive 3 TeV CLIC_SiD 2469 2000000 2000000 415.1 Template for mass measurement, m(h) = 125.95 GeV
ee -> hZ, Z->qq 350 GeV CLIC_ILD 2558 200000 542500 93.44 m(h) = 126 GeV
ee -> hZ, Z->qq, invisible h 350 GeV CLIC_ILD 2610 10000 19000 93.44* m(h) = 126 GeV, stable (invisible) Higgs
ee -> hZ, Z->ee, invisible h 350 GeV CLIC_ILD 2613 10000 18000 4.62* m(h) = 126 GeV, stable (invisible) Higgs
ee -> hZ, Z->mumu, invisible h 350 GeV CLIC_ILD 2616 10000 18000 4.63* m(h) = 126 GeV, stable (invisible) Higgs
ee -> hZ, Z->tautau, invisible h 350 GeV CLIC_ILD 2619 10000 20000 4.62* m(h) = 126 GeV, stable (invisible) Higgs
ee -> hvv, h->tautau 3 TeV CLIC_ILD 2671 100000 395200 415.1* m(h) = 126 GeV, extended
ee -> hZ, Z->qq, h->ZZ 350 GeV CLIC_ILD 2720 20000 25000 93.44* m(h) = 126 GeV reprocessed
ee -> hZ, Z->ee, h->ZZ 350 GeV CLIC_ILD 2723 20000 25000 4.62* m(h) = 126 GeV reprocessed
ee -> hZ, Z->mumu, h->ZZ 350 GeV CLIC_ILD 2726 20000 50000 4.63* m(h) = 126 GeV reprocessed
ee -> hvv, h->ZZ 1.4 TeV CLIC_ILD 2717 20000 25500 244.1* m(h) = 126 GeV reprocessed
ee -> tth, tt->lvbbqq, h->bb 1.4 TeV CLIC_SiD 2713 50000 50000 0.415 like 2441, but no overlay
ee -> tth, tt->bbqqqq, h->bb 1.4 TeV CLIC_SiD 2714 50000 50000 0.431 like 2435, but no overlay
ee -> hvv, h->tautau 1.4 TeV CLIC_ILD 3626 200000 203800 244.0* m(h) = 126 GeV, WHIZARD V54
ee -> hvv inclusive 1.4 TeV CLIC_SiD 3782 1000000 945900 243.93 Template for mass measurement, m(h) = 126.1 GeV, WHIZARD V55
ee -> hvv inclusive 3 TeV CLIC_SiD 3785 2000000 1864200 414.9 Template for mass measurement, m(h) = 126.1 GeV , WHIZARD V55
ee -> hvv inclusive 1.4 TeV CLIC_SiD 4019 1000000 1004600 244.02 Template for mass measurement, m(h) = 126.0 GeV, WHIZARD V55
ee -> hvv inclusive 3 TeV CLIC_SiD 4022 & 4025 2000000 945400+996600 415.05 Template for mass measurement, m(h) = 126.0 GeV, WHIZARD V55
ee -> hZ, Z->qq 350 GeV CLIC_ILD 4106 500000 497000 93.48 Template for mass measurement, m(h) = 125.95 GeV, WHIZARD V55
ee -> hZ, Z->qq 350 GeV CLIC_ILD 4109 500000 498000 93.41 Template for mass measurement, m(h) = 126.05 GeV, WHIZARD V55
ee -> hZ, Z->qq 420 GeV CLIC_ILD 4118 500000 489000 67.9 Luminosity spectrum for 500 GeV machine scaled to 420 GeV, m(h) = 126 GeV, WHIZARD V55
ee -> hvv, h->Zgamma, Z->qq 1.4 TeV CLIC_ILD 4149 200000 251600 244.0* m(h) = 126 GeV, Improved photon reconstruction compared to 2048
ee -> hvv, h->Zgamma, Z->ll 1.4 TeV CLIC_ILD 4193 600000 640800 244.0* m(h) = 126 GeV, Improved photon reconstruction compared to 2282
ee -> hvv inclusive 420 GeV CLIC_ILD 4221 700000 735500 60.3 WHIZARD V55, m(h) = 126 GeV, 500 GeV lumi spectrum scaled, 0.17 γγ -> had. / BX
ee -> hZ, Z->qq, invisible h 420 GeV CLIC_ILD 4224 20000 25000 67.9* WHIZARD V55, m(h) = 126 GeV, 500 GeV lumi spectrum scaled, 0.17 γγ -> had. / BX
ee -> hvv inclusive 350 GeV CLIC_ILD 4234 500000 528000 96.0 WHIZARD V55, m(h) = 126 GeV, 500 GeV lumi spectrum scaled, 0.17 γγ -> had. / BX
ee -> hZ, Z->qq, invisible h 350 GeV CLIC_ILD 4237 20000 26000 96.0* WHIZARD V55, m(h) = 126 GeV, 500 GeV lumi spectrum scaled, 0.17 γγ -> had. / BX
ee -> hZ, Z->qq 250 GeV CLIC_ILD 4245 700000 751000 136.0 WHIZARD V55, m(h) = 126 GeV, 350 GeV lumi spectrum scaled, no overlay
ee -> hZ, Z->qq, invisible h 250 GeV CLIC_ILD 4278 20000 25000 136.0 WHIZARD V55, m(h) = 126 GeV, 350 GeV lumi spectrum scaled, no overlay
ee -> hvv inclusive 250 GeV CLIC_ILD 4281 500000 600000 46.4 WHIZARD V55, m(h) = 126 GeV, 350 GeV lumi spectrum scaled, no overlay
ee -> hZ, Z->qq, h->cc 350 GeV CLIC_ILD 4308 100000 125000 93.44* WHIZARD V55, m(h) = 126 GeV
ee -> hZ, Z->qq, h->gg 350 GeV CLIC_ILD 4613 100000 125000 93.44* WHIZARD V57, m(h) = 126 GeV reprocessed
ee -> hvv, h->cc 350 GeV CLIC_ILD 4311 100000 125000 51.53* WHIZARD V55, m(h) = 126 GeV
ee -> hvv, h->gg 350 GeV CLIC_ILD 4610 100000 125000 51.53* WHIZARD V57, m(h) = 126 GeV reprocessed
ee -> hZ, Z->mumu 380 GeV CLIC_ILD 4381 100000 125000 3.94 WHIZARD V55, m(h) = 126 GeV, 350 GeV lumi spectrum scaled, 0.0464 γγ -> had. / BX
ee -> hZ, Z->ee 380 GeV CLIC_ILD 4384 100000 125000 3.94 WHIZARD V55, m(h) = 126 GeV, 350 GeV lumi spectrum scaled, 0.0464 γγ -> had. / BX
ee -> hvv, h->mumu 1.4 TeV CLIC_ILD 4722 20000 30000 244.0* WHIZARD V57, m(h) = 126 GeV
ee -> hvv inclusive 1.4 TeV CLIC_ILD 5218 1000000 999900 244.02 WHIZARD V57, m(h) = 126 GeV
ee -> hZ, Z->ee 350 GeV CLIC_ILD 5769 500000 591000 4.62 WHIZARD V57, m(h) = 126 GeV
ee -> hZ, Z->mumu 350 GeV CLIC_ILD 5772 500000 564500 4.63 WHIZARD V57, m(h) = 126 GeV
ee -> hhvv 1.4 TeV CLIC_ILD 6022 150000 215800 0.149 WHIZARD V57, m(h) = 126 GeV
ee -> hhvv 3 TeV CLIC_ILD 6025 150000 178500 0.588 WHIZARD V57, m(h) = 126 GeV
ee -> hvv inclusive 1.4 TeV CLIC_SiD 6141 3000000 2942700 244.02 WHIZARD V57, m(h) = 126 GeV
ee -> hvv inclusive 1.4 TeV CLIC_SiD 6144 2000000 1953900 243.93 WHIZARD V57, m(h) = 126.1 GeV
ee -> hvv inclusive 1.4 TeV CLIC_SiD 6147 2000000 1989700 244.07 WHIZARD V57, m(h) = 125.95 GeV
ee -> hvv inclusive 1.4 TeV CLIC_SiD 6188 3000000 2995600 243.97 WHIZARD V57, m(h) = 126.05 GeV
ee -> hvv inclusive 3 TeV CLIC_SiD 6159 4000000 3992300 415.05 WHIZARD V57, m(h) = 126 GeV
ee -> hvv inclusive 3 TeV CLIC_SiD 6171 4000000 3980300 415.10 WHIZARD V57, m(h) = 125.95 GeV
ee -> hvv, h->gammagamma 3 TeV CLIC_ILD 6265 25000 24550 415.04* WHIZARD V57, m(h) = 126 GeV
ee -> hvv inclusive 3 TeV CLIC_SiD 6249 4000000 2954500 414.94 WHIZARD V57, m(h) = 126.1 GeV
ee -> hvv, h->bb 1.4 TeV CLIC_SiD 6253 1000000 971200 243.53 WHIZARD V57, m(h) = 126.5 GeV
ee -> hvv, h->bb 1.4 TeV CLIC_SiD 6256 1000000 970200 244.51 WHIZARD V57, m(h) = 125.5 GeV
ee -> hvv, h->bb 1.4 TeV CLIC_SiD 6259 1000000 968800 245.01 WHIZARD V57, m(h) = 125.0 GeV
ee -> hvv, h->bb 1.4 TeV CLIC_SiD 6262 1000000 967800 243.04 WHIZARD V57, m(h) = 127.0 GeV
ee -> hvv, h->bb 3 TeV CLIC_SiD 6273 1500000 1489100 414.52* WHIZARD V57, m(h) = 126.5 GeV
ee -> hvv, h->bb 3 TeV CLIC_SiD 6276 1500000 1491100 415.58* WHIZARD V57, m(h) = 125.5 GeV
ee -> hZ, Z->qq 350 GeV CLIC_ILD 6281 500000 499500 93.06 WHIZARD V57, m(h) = 126.5 GeV
ee -> hZ, Z->qq 350 GeV CLIC_ILD 6284 500000 498000 93.83 WHIZARD V57, m(h) = 125.5 GeV
ee -> hvv inclusive 350 GeV CLIC_ILD 6479 500000 500000 51.85 WHIZARD V57, m(h) = 125.5 GeV
ee -> hvv inclusive 350 GeV CLIC_ILD 6482 500000 500000 51.22 WHIZARD V57, m(h) = 126.5 GeV
ee -> hvv inclusive 350 GeV CLIC_ILD 6525 500000 495000 52.53 WHIZARD V57, m(h) = 126.0 GeV, like 2028, but with beam recoil
ee -> hvv inclusive 3 TeV CLIC_ILD 6534 2000000 1930800 415.04 WHIZARD V57, m(h) = 126.0 GeV
ee -> hvv, h->gammagamma 3 TeV CLIC_ILD 6814 25000 30000 415.1* WHIZARD V57, m(h) = 126 GeV, no overlay
ee -> hZ, Z->qq 1.4 TeV CLIC_SiD 6972 100000 119900 9.31 WHIZARD V57, m(h) = 126.0 GeV
ee -> hZ, Z->qq 3 TeV CLIC_SiD 6975 100000 114400 3.67 WHIZARD V57, m(h) = 126.0 GeV
ee -> hz, Z->qq, h->ZZ* 350 GeV CLIC_ILD 9593 200000 216400 93.44* WHIZARD V57, m(h) = 126.0 GeV NEW
* = does not include the Higgs branching fraction

  • Higgs branching fractions should be taken from: http://arxiv.org/abs/1201.3084
  • Older signal samples with different Higgs masses (mostly 120 GeV) should not be used any more.

Samples to train the flavour tagging

Type Energy Detector ProdID Events planned Events produced Comments
ee -> qqqq 350 GeV CLIC_ILD 2010 50000 47900 q = u,d,s
ee -> cccc 350 GeV CLIC_ILD 2007 50000 35600  
ee -> bbbb 350 GeV CLIC_ILD 2004 50000 41600  
ee -> qqqq 3 TeV CLIC_SiD 2060 50000 46000 q = u,d,s
ee -> cccc 3 TeV CLIC_SiD 2057 50000 49200  
ee -> bbbb 3 TeV CLIC_SiD 2054 50000 45800  
ee -> uuuuuu 1.4 TeV CLIC_SiD 2255 10000 10000
 
ee -> dddddd 1.4 TeV CLIC_SiD 2253 10000 10000
 
ee -> ssssss 1.4 TeV CLIC_SiD 2251 10000 10000  
ee -> cccccc 1.4 TeV CLIC_SiD 2249 10000 9800  
ee -> bbbbbb 1.4 TeV CLIC_SiD 2247 10000 9800  
ee -> Zvv, Z->bb 350 GeV CLIC_ILD 2285 100000 111500  
ee -> Zvv, Z->cc 350 GeV CLIC_ILD 2288 100000 122500  
ee -> Zvv, Z->uu/dd/ss 350 GeV CLIC_ILD 2291 100000 109500  
ee -> Zvv, Z->bb 1.4 TeV CLIC_ILD 2804 100000 99000  
ee -> Zvv, Z->cc 1.4 TeV CLIC_ILD 2807 100000 99600  
ee -> Zvv, Z->uu/dd/ss 1.4 TeV CLIC_ILD 2801 100000 99800  
ee -> Zvv, Z->bb 3 TeV CLIC_ILD 3039 100000 94050  
ee -> Zvv, Z->cc 3 TeV CLIC_ILD 3042 100000 96600  
ee -> Zvv, Z->uu/dd/ss 3 TeV CLIC_ILD 3045 100000 97950  
ee -> Zvv, Z->bb 3 TeV CLIC_SiD 4592 100000 124800 m(H) = 12 TeV
ee -> Zvv, Z->cc 3 TeV CLIC_SiD 4595 100000 124300 m(H) = 12 TeV
ee -> Zvv, Z->uu/dd/ss 3 TeV CLIC_SiD 4598 100000 124550 m(H) = 12 TeV
ee -> Zvv, Z->bb 1.4 TeV CLIC_SiD 4601 100000 124850 m(H) = 12 TeV
ee -> Zvv, Z->cc 1.4 TeV CLIC_SiD 4604 100000 125000 m(H) = 12 TeV
ee -> Zvv, Z->uu/dd/ss 1.4 TeV CLIC_SiD 4607 100000 124950 m(H) = 12 TeV
ee -> bb 3 TeV CLIC_ILD 6194 100000 99850  

Background samples

Type Energy Detector ProdID Events planned Events produced σ [fb] Comments
ee -> tth, tt->llvvbb, h->bb 1400 GeV CLIC_SiD 2429 50000 50000 0.100 Generated using Physsim, m(h) = 125 GeV, q=u,d,s,c,b, reprocessed
ee -> tth, tt->llvvbb, h->not bb 1400 GeV CLIC_SiD 2432 50000 50000 0.073 Generated using Physsim, m(h) = 125 GeV,, q=u,d,s,c,b, reprocessed
ee -> ttZ, tt->llvvbb 1400 GeV CLIC_SiD 2447 50000 50000 0.439 Generated using Physsim, q=u,d,s,c,b, reprocessed
ee -> ttZ, tt->lvbbqq 1400 GeV CLIC_SiD 2453 50000 50000 1.825 Generated using Physsim, q=u,d,s,c,b, reprocessed
ee -> ttZ, tt->bbqqqq 1400 GeV CLIC_SiD 2450 50000 50000 1.895 Generated using Physsim, q=u,d,s,c,b, reprocessed
ee -> ttbb, tt->llvvbb 1400 GeV CLIC_SiD 2420 50000 50000 0.127 Generated using Physsim, q=u,d,s,c,b, reprocessed
ee -> ttbb, tt->lvbbqq 1400 GeV CLIC_SiD 2426 50000 50000 0.529 Generated using Physsim, q=u,d,s,c,b, reprocessed
ee -> ttbb, tt->bbqqqq 1400 GeV CLIC_SiD 2423 50000 50000 0.549 Generated using Physsim, q=u,d,s,c,b, reprocessed
ee -> qq 1400 GeV CLIC_SiD 2098 500000 525000 4008.8 m(h) = 126 GeV, q=u,d,s,c,b
ee -> qqvv 1400 GeV CLIC_SiD 2096 500000 482000 933.8 m(h) = 126 GeV, q=u,d,s,c,b
ee -> qq 1400 GeV CLIC_ILD 2091 500000 459000 4009.5 m(h) = 126 GeV, q=u,d,s,c,b
ee -> qqvv 1400 GeV CLIC_ILD 2094 500000 474000 933.9 m(h) = 126 GeV, q=u,d,s,c,b
ee -> qqvv 1400 GeV CLIC_ILD 2199 500000 439000 788.0 no beam recoil, m(h) = 12.6 TeV, q=u,d,s,c,b
ee -> qqvv 1400 GeV CLIC_SiD 2201 500000 474000 788.0 no beam recoil, m(h) = 12.6 TeV, q=u,d,s,c,b
ee -> ttbar 1400 GeV CLIC_SiD 2417 300000 300000 135.8 Generated using PYTHIA, reprocessed
ee -> qqll 1400 GeV CLIC_SiD 2301 200000 237000 2726.7 no beam recoil, m(h) = 12 TeV, q=u,d,s,c,b, l=e,mu,tau
ee -> qqlv 1400 GeV CLIC_SiD 2159 200000 429000 4312.9 no beam recoil, m(h) = 12 TeV, q=u,d,s,c,b, l=e,mu,tau, v=nu_e,nu_mu,nu_tau
ee -> qqqq 1400 GeV CLIC_ILD 2163 500000 429000 1328.1 no beam recoil, m(h) = 10 TeV, q=u,d,s,c,b, same events as ProdID =1097
ee -> qqqqvv 1400 GeV CLIC_ILD 2152 100000 117000 24.7 no beam recoil, m(h) = 10 TeV, q=u,d,s,c,b, v=nu_e,nu_mu,nu_tau, same events as ProdID =1081
ee -> qqqqlv 1400 GeV CLIC_ILD 2169 200000 176000 115.3 no beam recoil, m(h) = 10 TeV, q=u,d,s,c,b, l=e,mu,tau, v=nu_e,nu_mu,nu_tau, same events as ProdID =1085
ee -> qqqqll 1400 GeV CLIC_ILD 2166 120000 205000 71.7 no beam recoil, m(h) = 10 TeV, q=u,d,s,c,b, l=e,mu,tau, v=nu_e,nu_mu,nu_tau, same events as ProdID =1089
ee -> mu+mu-nunu 1400 GeV CLIC_ILD 2172 200000 236000 129.0 no beam recoil, m(h) = 12 TeV
ee -> tau+tau- 1400 GeV CLIC_ILD 2187 500000 482500 358.0 no beam recoil, m(h) = 12 TeV
ee -> tau+tau-nunu 1400 GeV CLIC_ILD 2190 150000 133000 84.5 no beam recoil, m(h) = 12 TeV
ee -> e+e-tau+tau- 1400 GeV CLIC_ILD 2193 500000 464500 1942.2 no beam recoil, m(h) = 12 TeV
ee -> qqqq 3 TeV CLIC_ILD 2207 500000 746400 593.0 no beam recoil, m(h) = 12 TeV, q=u,d,s,c,b
ee -> qqqqnunu 3 TeV CLIC_ILD 2210 309600 309600 74.1 no beam recoil, m(h) = 12 TeV, same events as ProdID =1460
ee -> qqqqll 3 TeV CLIC_ILD 2212 157000 157000 182.4 no beam recoil, m(h) = 12 TeV, same events as ProdiD =1458
ee -> eemumu 1400 GeV CLIC_ILD 2146 1000000 1000000 431 stdhep files generated locally
eg -> emumu 1400 GeV CLIC_ILD 2148 1000000 1000000 1280 stdhep files generated locally
ge -> emumu 1400 GeV CLIC_ILD 2182 1000000 1000000 1280 stdhep files generated locally
ee -> mu+mu- 1400 GeV CLIC_ILD 2215 30000 50000 17.0 no beam recoil, 100 < M(mu+mu-) < 150 GeV
ee -> gammagamma 1400 GeV CLIC_SiD 2306 20000 22800
1735.9* m(h) = 12 TeV, preselection cuts for the h->gammagamma analysis
ee -> vvgamma 1400 GeV CLIC_SiD 2327 150000 148800 13379.3* m(h) = 12 TeV, preselection cuts for the h->gammagamma analysis
ee -> vvgammagamma 1400 GeV CLIC_SiD 2330 20000 19800
1679.9* m(h) = 12 TeV, preselection cuts for the h->gammagamma analysis
ee -> e+e-gamma 1400 GeV CLIC_SiD 2321 20000 (maybe more later) 19600 184536.3* m(h) = 12 TeV, preselection cuts for the h->gammagamma analysis
ee -> e+e-gammagamma 1400 GeV CLIC_SiD 2318 20000 20200
4119.5* m(h) = 12 TeV, preselection cuts for the h->gammagamma analysis
ee -> mu+mu-gamma 1400 GeV CLIC_SiD 2315 20000 17200 151.2* m(h) = 12 TeV, preselection cuts for the h->gammagamma analysis
ee -> mu+mu-gammagamma 1400 GeV CLIC_SiD 2312 20000 16000
29.7* m(h) = 12 TeV, preselection cuts for the h->gammagamma analysis
ee -> qqgamma 1400 GeV CLIC_SiD 2324 70000 72200 1175.7* m(h) = 12 TeV, preselection cuts for the h->gammagamma analysis
ee -> qqgammagamma 1400 GeV CLIC_SiD 2309 20000 26000 144.7* m(h) = 12 TeV, preselection cuts for the h->gammagamma analysis
ee -> vvqqgamma 1400 GeV CLIC_SiD 2859 200000 197000 120.7* m(h) = 10 TeV, 8 < theta(q,gamma) < 172 degrees, preselection cuts for the h->Zgamma analysis, efficiency of the preselection cuts: 30.9% replaced
ee -> vvqq 1400 GeV CLIC_SiD 2336 20000 19800 787.6* m(h) = 12 TeV, preselection cuts for the h->Zgamma analysis
ee -> vvllgamma 1400 GeV CLIC_SiD 2821 200000 200000 142.5* m(h) = 10 TeV, 8 < theta(l,gamma) < 172 degrees, preselection cuts for the h->Zgamma analysis, efficiencey of the preselection cuts: 6.1% obsolete (see ProdID =3492)
ee -> vvll 1400 GeV CLIC_SiD 2342 40000 37800 2163.7* m(h) = 12 TeV, preselection cuts for the h->Zgamma analysis
ee -> llll 1400 GeV CLIC_SiD 2345 20000 18200 7088.4* m(h) = 12 TeV, preselection cuts for the h->Zgamma analysis
ee -> qqllgamma 1400 GeV CLIC_SiD 2348 40000 39000 136.0* m(h) = 10 TeV, preselection cuts for the h->Zgamma analysis, efficiency of the preselection cuts: 13.4%
ee -> qqll 1400 GeV CLIC_SiD 2351 1600000 1932800 2725.6* m(h) = 12 TeV, preselection cuts for the h->Zgamma analysis
eγ -> eqqqq (γ from BS) 1400 GeV CLIC_SiD 2358 500000 419800
1160.8 m(h) = 12 TeV
γe -> eqqqq (γ from BS) 1400 GeV CLIC_SiD 2364 500000 386800
1156.5 m(h) = 12 TeV
eγ -> eqqqq (γ from BS) 3 TeV CLIC_SiD 2370 500000 165100 2650.7 m(h) = 12 TeV
γe -> eqqqq (γ from BS) 3 TeV CLIC_SiD 2376 500000 163200 2545.9 m(h) = 12 TeV
eγ -> eqqqq (γ from EPA) 1400 GeV CLIC_SiD 2355 500000 423400 287.0 m(h) = 12 TeV
γe -> eqqqq (γ from EPA) 1400 GeV CLIC_SiD 2361 500000 401800 287.0 m(h) = 12 TeV
eγ -> eqqqq (γ from EPA) 3 TeV CLIC_SiD 2367 500000 141600 661.8 m(h) = 12 TeV
γe -> eqqqq (γ from EPA) 3 TeV CLIC_SiD 2373 500000 128100
661.2 m(h) = 12 TeV
eγ -> eqq (γ from BS) 1.4 TeV CLIC_SiD 2501 500000 500000 37313 m(h) = 12 TeV
γe -> eqq (γ from BS) 1.4 TeV CLIC_SiD 2507 500000 500000 37362 m(h) = 12 TeV
eγ -> eqq (γ from EPA) 1.4 TeV CLIC_SiD 2498 500000 500000 16154 m(h) = 12 TeV
γe -> eqq (γ from EPA) 1.4 TeV CLIC_SiD 2504 500000 500000 16153 m(h) = 12 TeV
eγ -> eqq (γ from BS) 1.4 TeV CLIC_ILD 2523 500000 500000 37313 m(h) = 12 TeV
γe -> eqq (γ from BS) 1.4 TeV CLIC_ILD 2527 500000 500000 37362 m(h) = 12 TeV
eγ -> eqq (γ from EPA) 1.4 TeV CLIC_ILD 2515 500000 500000 16154 m(h) = 12 TeV
γe -> eqq (γ from EPA) 1.4 TeV CLIC_ILD 2525 500000 500000 16153 m(h) = 12 TeV
eγ -> qqqqnu (γ from BS) 1.4 TeV CLIC_SiD 2576 500000 427500 136.9 m(h) = 12 TeV
γe -> qqqqnu (γ from BS) 1.4 TeV CLIC_SiD 2582 500000 395000 136.4 m(h) = 12 TeV
eγ -> qqqqnu (γ from EPA) 1.4 TeV CLIC_SiD 2573 500000 441000 32.6 m(h) = 12 TeV
γe -> qqqqnu (γ from EPA) 1.4 TeV CLIC_SiD 2579 500000 403000 32.6 m(h) = 12 TeV
eγ -> qqqqnu (γ from BS) 3 TeV CLIC_SiD 2588 500000 434200 360.5 m(h) = 12 TeV
γe -> qqqqnu (γ from BS) 3 TeV CLIC_SiD 2594 500000 428400 360.0 m(h) = 12 TeV
eγ -> qqqqnu (γ from EPA) 3 TeV CLIC_SiD 2585 500000 206200 84.3 m(h) = 12 TeV
γe -> qqqqnu (γ from EPA) 3 TeV CLIC_SiD 2591 500000 208200 84.3 m(h) = 12 TeV
γγ -> qqqq (both γ from BS) 1.4 TeV CLIC_SiD 2643 400000 482400 4009.0 m(h) = 12 TeV, m(b) = m(c) = m(s) = m(u) = m(d) = 0, m(qq) > 40 GeV for quark pairs
γγ -> qqqq (first γ from BS, second γ from EPA) 1.4 TeV CLIC_SiD 2640 200000 234800 692.1 m(h) = 12 TeV, m(b) = m(c) = m(s) = m(u) = m(d) = 0, m(qq) > 40 GeV for quark pairs
γγ -> qqqq (first γγ from EPA, second γ from BS) 1.4 TeV CLIC_SiD 2637 200000 234400 696.3 m(h) = 12 TeV, m(b) = m(c) = m(s) = m(u) = m(d) = 0, m(qq) > 40 GeV for quark pairs
γγ -> qqqq (both γ from EPA) 1.4 TeV CLIC_SiD 2634 100000 116400 128.1 m(h) = 12 TeV, m(b) = m(c) = m(s) = m(u) = m(d) = 0, m(qq) > 40 GeV for quark pairs
ee -> qqll 1.4 TeV CLIC_ILD 2645 200000 226500 2726.7 m(h) = 12 TeV, q=u,d,s,c,b, l=e,mu,tau, same events as used for ProdID =2301
γγ -> qqqq (both γ from BS) 3 TeV CLIC_SiD 2657 400000 396400 11739.7 m(h) = 12 TeV, m(b) = m(c) = m(s) = m(u) = m(d) = 0, m(qq) > 40 GeV for quark pairs
γγ -> qqqq (first γ from BS, second γ from EPA) 3 TeV CLIC_SiD 2654 200000 125900 2066.9 m(h) = 12 TeV, m(b) = m(c) = m(s) = m(u) = m(d) = 0, m(qq) > 40 GeV for quark pairs
γγ -> qqqq (first γγ from EPA, second γ from BS) 3 TeV CLIC_SiD 2651 200000 131700 2070.0 m(h) = 12 TeV, m(b) = m(c) = m(s) = m(u) = m(d) = 0, m(qq) > 40 GeV for quark pairs
γγ -> qqqq (both γ from EPA) 3 TeV CLIC_SiD 2648 100000 48600 325.0 m(h) = 12 TeV, m(b) = m(c) = m(s) = m(u) = m(d) = 0, m(qq) > 40 GeV for quark pairs
ee -> qqnunu 3 TeV CLIC_ILD 2660 200000 195600 1317.5 m(h) = 12 TeV, q=u,d,s,c,b
ee -> hqq 1.4 TeV CLIC_SiD 2665 20000 49000 9.31 m(h) = 126 GeV, q=u,d,s,c,b
ee -> hqq 3 TeV CLIC_SiD 2668 20000 18600 3.67 m(h) = 126 GeV, q=u,d,s,c,b
ee -> tautau 3 TeV CLIC_ILD 2848 20000 20000 243.1* m(h) = 12 TeV, preselection cuts for the H->tautau analysis
ee -> tautauvv 3 TeV CLIC_ILD 2851 80000 98900 95.5* m(h) = 12 TeV, preselection cuts for the H->tautau analysis
ee -> tautauee 3 TeV CLIC_ILD 2854 200000 203400 2373.8* m(h) = 12 TeV, preselection cuts for the H->tautau analysis
ee -> tautaumumu 3 TeV CLIC_ILD 2857 20000 19900 0.96* m(h) = 12 TeV, preselection cuts for the H->tautau analysis
γγ -> tautaull (both γ from BS) 3 TeV CLIC_ILD 2833 200000 200300 1106.9* m(h) = 12 TeV, preselection cuts for the H->tautau analysis
γγ -> tautaull (first γ from BS, second γ from EPA) 3 TeV CLIC_ILD 2830 100000 100700 235.5* m(h) = 12 TeV, preselection cuts for the H->tautau analysis
γγ -> tautaull (first γ from EPA, second γ from BS) 3 TeV CLIC_ILD 2827 100000 101200 235.6* m(h) = 12 TeV, preselection cuts for the H->tautau analysis
γγ -> tautaull (both γ from EPA) 3 TeV CLIC_ILD 2824 50000 50600 40.1* m(h) = 12 TeV, preselection cuts for the H->tautau analysis
γγ -> tautauvv (both γ from BS) 3 TeV CLIC_ILD 2845 200000 200400 389.2* m(h) = 12 TeV, preselection cuts for the H->tautau analysis
γγ -> tautauvv (first γ from BS, second γ from EPA) 3 TeV CLIC_ILD 2842 100000 101300 72.5* m(h) = 12 TeV, preselection cuts for the H->tautau analysis
γγ -> tautauvv (first γ from EPA, second γ from BS) 3 TeV CLIC_ILD 2839 100000 100800 72.5* m(h) = 12 TeV, preselection cuts for the H->tautau analysis
γγ -> tautauvv (both γ from EPA) 3 TeV CLIC_ILD 2836 50000 50300 11.7* m(h) = 12 TeV, preselection cuts for the H->tautau analysis
ee -> qqvv 350 GeV CLIC_ILD 2862 300000 306500 324.6 m(h) = 12 TeV
ee -> qqlv 350 GeV CLIC_ILD 2865 1500000 1437500 5914 m(h) = 12 TeV
ee -> qqll 350 GeV CLIC_ILD 2868 500000 488500 1704 m(h) = 12 TeV
ee -> qqqq 350 GeV CLIC_ILD 2871 1500000 1440500 5847 m(h) = 12 TeV
eγ -> eqqgamma (γ from BS) 1.4 TeV CLIC_SiD 2955 85000 97000 648.0* m(h) = 12 TeV, preselection cuts for the h->Zgamma analysis
γe -> eqqgamma (γ from BS) 1.4 TeV CLIC_SiD 2961 85000 100800 648.5* m(h) = 12 TeV, preselection cuts for the h->Zgamma analysis
eγ -> eqqgamma (γ from EPA) 1.4 TeV CLIC_SiD 2952 65000 70800 246.8* m(h) = 12 TeV, preselection cuts for the h->Zgamma analysis
γe -> eqqgamma (γ from EPA) 1.4 TeV CLIC_SiD 2958 65000 77400 246.7* m(h) = 12 TeV, preselection cuts for the h->Zgamma analysis
eγ -> nunuqqe (γ from BS) 1.4 TeV CLIC_SiD 3003 20000 19600 15.1* m(h) = 12 TeV, preselection cuts for the h->Zgamma analysis
γe -> nunuqqe (γ from BS) 1.4 TeV CLIC_SiD 3009 20000 19400 15.0* m(h) = 12 TeV, preselection cuts for the h->Zgamma analysis
eγ -> nunuqqe (γ from EPA) 1.4 TeV CLIC_SiD 3000 20000 18600 3.3* m(h) = 12 TeV, preselection cuts for the h->Zgamma analysis
γe -> nunuqqe (γ from EPA) 1.4 TeV CLIC_SiD 3006 20000 17800 3.3* m(h) = 12 TeV, preselection cuts for the h->Zgamma analysis
eγ -> ellgamma (γ from BS) 1.4 TeV CLIC_SiD 2967 80000 90600 1928.1* m(h) = 12 TeV, preselection cuts for the h->Zgamma analysis
γe -> ellgamma (γ from BS) 1.4 TeV CLIC_SiD 2973 80000 90600 1928.3* m(h) = 12 TeV, preselection cuts for the h->Zgamma analysis
eγ -> ellgamma (γ from EPA) 1.4 TeV CLIC_SiD 2964 80000 93600 778.9* m(h) = 12 TeV, preselection cuts for the h->Zgamma analysis
γe -> ellgamma (γ from EPA) 1.4 TeV CLIC_SiD 2970 80000 92800 779.0* m(h) = 12 TeV, preselection cuts for the h->Zgamma analysis
eγ -> ellqq (γ from BS) 1.4 TeV CLIC_SiD 3256 20000 22500   m(h) = 12 TeV, preselection cuts for the h->Zgamma analysis
γe -> ellqq (γ from BS) 1.4 TeV CLIC_SiD 3260 20000 23500   m(h) = 12 TeV, preselection cuts for the h->Zgamma analysis
eγ -> ellqq (γ from EPA) 1.4 TeV CLIC_SiD 3254 20000 22500   m(h) = 12 TeV, preselection cuts for the h->Zgamma analysis
γe -> ellqq (γ from EPA) 1.4 TeV CLIC_SiD 3258 20000 21000   m(h) = 12 TeV, preselection cuts for the h->Zgamma analysis
eγ -> ell (γ from BS) 1.4 TeV CLIC_SiD 3015 300000 309800 21569.4* m(h) = 12 TeV, preselection cuts for the h->Zgamma analysis, E(l) > 10 GeV, 8 < theta(l) < 172 degrees
γe -> ell (γ from BS) 1.4 TeV CLIC_SiD 3021 300000 309400 21646.0* m(h) = 12 TeV, preselection cuts for the h->Zgamma analysis, E(l) > 10 GeV, 8 < theta(l) < 172 degrees
eγ -> ell (γ from EPA) 1.4 TeV CLIC_SiD 3012 1000000 1008600 19796.5* m(h) = 12 TeV, preselection cuts for the h->Zgamma analysis, E(l) > 10 GeV, 8 < theta(l) < 172 degrees
γe -> ell (γ from EPA) 1.4 TeV CLIC_SiD 3018 1000000 1027400 19802.3* m(h) = 12 TeV, preselection cuts for the h->Zgamma analysis, E(l) > 10 GeV, 8 < theta(l) < 172 degrees
eγ -> eqq (γ from BS) 1.4 TeV CLIC_SiD 3027 500000 507200 10466.8* m(h) = 12 TeV, preselection cuts for the h->Zgamma analysis, E(q) > 10 GeV, 8 < theta(q) < 172 degrees
γe -> eqq (γ from BS) 1.4 TeV CLIC_SiD 3033 500000 506400 10504.4* m(h) = 12 TeV, preselection cuts for the h->Zgamma analysis, E(q) > 10 GeV, 8 < theta(q) < 172 degrees
eγ -> eqq (γ from EPA) 1.4 TeV CLIC_SiD 3024 800000 811600 7480.1* m(h) = 12 TeV, preselection cuts for the h->Zgamma analysis, E(q) > 10 GeV, 8 < theta(q) < 172 degrees
γe -> eqq (γ from EPA) 1.4 TeV CLIC_SiD 3030 800000 793200 7482.0* m(h) = 12 TeV, preselection cuts for the h->Zgamma analysis, E(q) > 10 GeV, 8 < theta(q) < 172 degrees
ee -> qqll 3 TeV CLIC_ILD 3048 500000 482500 3319.6 m(h) = 12 TeV
eγ -> eqq (γ from BS) 3 TeV CLIC_ILD 3222   293350 40683.4* m(h) = 12 TeV, preselection cuts for the H->tautau analysis extended
γe -> eqq (γ from BS) 3 TeV CLIC_ILD 3228   317300 40703.5* m(h) = 12 TeV, preselection cuts for the H->tautau analysis extended
eγ -> eqq (γ from EPA) 3 TeV CLIC_ILD 3219   298700 21317.4* m(h) = 12 TeV, preselection cuts for the H->tautau analysis extended
γe -> eqq (γ from EPA) 3 TeV CLIC_ILD 3225   305250 21308.3* m(h) = 12 TeV, preselection cuts for the H->tautau analysis extended
eγ -> qqvve (γ from BS) 3 TeV CLIC_ILD 3234   39000 47.09* m(h) = 12 TeV, preselection cuts for the H->tautau analysis
γe -> qqvve (γ from BS) 3 TeV CLIC_ILD 3240   18350 47.04* m(h) = 12 TeV, preselection cuts for the H->tautau analysis
eγ -> qqvve (γ from EPA) 3 TeV CLIC_ILD 3231   18600 10.17* m(h) = 12 TeV, preselection cuts for the H->tautau analysis
γe -> qqvve (γ from EPA) 3 TeV CLIC_ILD 3237   18100 10.16* m(h) = 12 TeV, preselection cuts for the H->tautau analysis
γγ -> tautau (both γ from BS) 3 TeV CLIC_ILD 3132   295400 1841288.2* m(h) = 12 TeV, preselection cuts for the H->tautau analysis extended
γγ -> tautau (first γ from BS, second γ from EPA) 3 TeV CLIC_ILD 3129   320900 846888.2* m(h) = 12 TeV, preselection cuts for the H->tautau analysis extended
γγ -> tautau (first γ from EPA, second γ from BS) 3 TeV CLIC_ILD 3126   337200 846395.1* m(h) = 12 TeV, preselection cuts for the H->tautau analysis extended
γγ -> tautau (both γ from EPA) 3 TeV CLIC_ILD 3123   315100 154427.4* m(h) = 12 TeV, preselection cuts for the H->tautau analysis extended
γγ -> qqvv (both γ from BS) 3 TeV CLIC_ILD 3204   19750 9.56* m(h) = 12 TeV, preselection cuts for the H->tautau analysis
γγ -> qqvv (first γ from BS, second γ from EPA) 3 TeV CLIC_ILD 3201   19500 2.03* m(h) = 12 TeV, preselection cuts for the H->tautau analysis
γγ -> qqvv (first γ from EPA, second γ from BS) 3 TeV CLIC_ILD 3198   19750 2.03* m(h) = 12 TeV, preselection cuts for the H->tautau analysis
γγ -> qqvv (both γ from EPA) 3 TeV CLIC_ILD 3195   19250 0.345* m(h) = 12 TeV, preselection cuts for the H->tautau analysis
γγ -> qqee (both γ from BS) 3 TeV CLIC_ILD 3216   18250 208.6* m(h) = 12 TeV, preselection cuts for the H->tautau analysis
γγ -> qqee (first γ from BS, second γ from EPA) 3 TeV CLIC_ILD 3213   18050 45.3* m(h) = 12 TeV, preselection cuts for the H->tautau analysis
γγ -> qqee (first γ from EPA, second γ from BS) 3 TeV CLIC_ILD 3210   18150 45.4* m(h) = 12 TeV, preselection cuts for the H->tautau analysis
γγ -> qqee (both γ from EPA) 3 TeV CLIC_ILD 3207   19100 7.76* m(h) = 12 TeV, preselection cuts for the H->tautau analysis
eγ -> tautaue (γ from BS) 3 TeV CLIC_ILD 3162   319750 72735.9* m(h) = 12 TeV, preselection cuts for the H->tautau analysis extended
γe -> tautaue (γ from BS) 3 TeV CLIC_ILD 3168   315100 72775.0* m(h) = 12 TeV, preselection cuts for the H->tautau analysis extended
eγ -> tautaue (γ from EPA) 3 TeV CLIC_ILD 3159   312050 35874.3* m(h) = 12 TeV, preselection cuts for the H->tautau analysis extended
γe -> tautaue (γ from EPA) 3 TeV CLIC_ILD 3165   320500 35858.8* m(h) = 12 TeV, preselection cuts for the H->tautau analysis extended
ee->qqvv 1.4 TeV CLIC_ILD 3243 600000 577200
787.7 q=u,d,s,c,b, m(h) = 12 TeV
ee->qqll 1.4 TeV CLIC_ILD 3246 2000000 2104400 2725.8 q=u,d,s,c,b, m(h) = 12 TeV
ee->qqlv 1.4 TeV CLIC_ILD 3249 2000000 2043200 4309.7 q=u,d,s,c,b, m(h) = 12 TeV
ee->e e mu mu nu nu 1.4 TeV CLIC_ILD 3263 3200 3900 1.59 m(h) = 12 TeV, nu = nu_mu
γγ -> mu mu nu nu (both γ from EPA) 1.4 TeV CLIC_ILD 3266 14000 14900 5.61 m(h) = 12 TeV, nu = nu_mu
γγ -> mu mu nu nu (first γ from EPA, second γ from BS) 1.4 TeV CLIC_ILD 3269 52000 56800 30.52 m(h) = 12 TeV, nu = nu_mu
γγ -> mu mu nu nu (second γ from EPA, first γ from BS) 1.4 TeV CLIC_ILD 3272 52000 56300 30.36 m(h) = 12 TeV, nu = nu_mu
γγ -> mu mu nu nu (both γ from BS) 1.4 TeV CLIC_ILD 3275 220000 241000 172.3 m(h) = 12 TeV, nu = nu_mu
eγ -> e mu mu nu nu (γ from EPA) 1.4 TeV CLIC_ILD 3278 7000 10000 3.52 m(h) = 12 TeV, nu = nu_mu
eγ -> e mu mu nu nu (γ from BS) 1.4 TeV CLIC_ILD 3281 25000 29600 15.28 m(h) = 12 TeV, nu = nu_mu
γe -> e mu mu nu nu (γ from EPA) 1.4 TeV CLIC_ILD 3284 7000 9700 3.50 m(h) = 12 TeV, nu = nu_mu
γe -> e mu mu nu nu (γ from BS) 1.4 TeV CLIC_ILD 3287 25000 29300 15.22 m(h) = 12 TeV, nu = nu_mu
ee -> e e mu mu 1.4 TeV CLIC_ILD 3290 48000 58500 24.47 m(h) = 12 TeV, 100 GeV < m(mu,mu) < 150 GeV, 8 < θ(mu) < 172
eγ -> e mu mu (γ from EPA) 1.4 TeV CLIC_ILD 3306 170000 194200 217.3 m(h) = 12 TeV, 100 GeV < m(mu,mu) < 150 GeV, 8 < θ(mu) < 172
eγ -> e mu mu (γ from BS) 1.4 TeV CLIC_ILD 3309 486000 572400 330.7 m(h) = 12 TeV, 100 GeV < m(mu,mu) < 150 GeV, 8 < θ(mu) < 172
γe -> e mu mu (γ from EPA) 1.4 TeV CLIC_ILD 3312 170000 192000 216.9 m(h) = 12 TeV, 100 GeV < m(mu,mu) < 150 GeV, 8 < θ(mu) < 172
γe -> e mu mu (γ from BS) 1.4 TeV CLIC_ILD 3315 486000 576300 333.3 m(h) = 12 TeV, 100 GeV < m(mu,mu) < 150 GeV, 8 < θ(mu) < 172
eγ -> qqqqe (γ from EPA) 1.4 TeV CLIC_ILD 3366 150000 129100 287.1 m(h) = 12 TeV
eγ -> qqqqe (γ from BS) 1.4 TeV CLIC_ILD 3369 150000 126300 1160.7 m(h) = 12 TeV
γe -> qqqqe (γ from EPA) 1.4 TeV CLIC_ILD 3372 150000 137400 286.9 m(h) = 12 TeV
γe -> qqqqe (γ from BS) 1.4 TeV CLIC_ILD 3375 150000 120200 1156.3 m(h) = 12 TeV
eγ -> qqqqnu (γ from EPA) 1.4 TeV CLIC_ILD 3378 150000 180100 32.6 m(h) = 12 TeV
eγ -> qqqqnu (γ from BS) 1.4 TeV CLIC_ILD 3381 150000 175000 136.9 m(h) = 12 TeV
γe -> qqqqnu (γ from EPA) 1.4 TeV CLIC_ILD 3384 150000 177800 32.6 m(h) = 12 TeV
γe -> qqqqnu (γ from BS) 1.4 TeV CLIC_ILD 3387 150000 173800 136.4 m(h) = 12 TeV
γγ -> qqqq (both γ from EPA) 1.4 TeV CLIC_ILD 3414 150000 167300 753.0 m(h) = 12 TeV, m(qqqq) > 50 GeV
γγ -> qqqq (first γ from EPA, second γ from BS) 1.4 TeV CLIC_ILD 3417 150000 167900 4034.8 m(h) = 12 TeV, m(qqqq) > 50 GeV
γγ -> qqqq (first γ from BS, second γ from EPA) 1.4 TeV CLIC_ILD 3420 150000 170700 4018.7 m(h) = 12 TeV, m(qqqq) > 50 GeV
γγ -> qqqq (both γ from BS) 1.4 TeV CLIC_ILD 3423 150000 159800 21406.2 m(h) = 12 TeV, m(qqqq) > 50 GeV
γγ -> qq (both γ from EPA) 1.4 TeV CLIC_ILD 3426 500000 472100 3439.0 m(h) = 12 TeV, m(qq) > 50 GeV
γγ -> qq (first γ from EPA, second γ from BS) 1.4 TeV CLIC_ILD 3429 500000 470100 17505.8 m(h) = 12 TeV, m(qq) > 50 GeV
γγ -> qq (first γ from BS, second γ from EPA) 1.4 TeV CLIC_ILD 3432 500000 471600 17494.4 m(h) = 12 TeV, m(qq) > 50 GeV
γγ -> qq (both γ from BS) 1.4 TeV CLIC_ILD 3435 500000 470800 73599.4 m(h) = 12 TeV, m(qq) > 50 GeV
eγ -> qqnu (γ from EPA) 1.4 TeV CLIC_ILD 3438 150000 148400 4019.9 m(h) = 12 TeV, m(qq) > 50 GeV
eγ -> qqnu (γ from BS) 1.4 TeV CLIC_ILD 3441 150000 148800 14408.0 m(h) = 12 TeV, m(qq) > 50 GeV
γe -> qqnu (γ from EPA) 1.4 TeV CLIC_ILD 3444 150000 150200 4095.6 m(h) = 12 TeV
γe -> qqnu (γ from BS) 1.4 TeV CLIC_ILD 3447 150000 163400 14602.7 m(h) = 12 TeV
eγ -> qqe (γ from EPA) 1.4 TeV CLIC_ILD 3450 150000 184200 2806.3 m(h) = 12 TeV, m(qq) > 50 GeV
eγ -> qqe (γ from BS) 1.4 TeV CLIC_ILD 3453 150000 173100 7518.0 m(h) = 12 TeV, m(qq) > 50 GeV
γe -> qqe (γ from EPA) 1.4 TeV CLIC_ILD 3456 150000 168500 16152.7 m(h) = 12 TeV
γe -> qqe (γ from BS) 1.4 TeV CLIC_ILD 3459 150000 160700 37362.8 m(h) = 12 TeV
γe -> qqnu (γ from EPA) 1.4 TeV CLIC_ILD 3468 150000 191200 4020.1 m(h) = 12 TeV, m(qq) > 50 GeV
γe -> qqnu (γ from BS) 1.4 TeV CLIC_ILD 3471 150000 191300 14384.4 m(h) = 12 TeV, m(qq) > 50 GeV
γe -> qqe (γ from EPA) 1.4 TeV CLIC_ILD 3480 150000 191000 2806.3 m(h) = 12 TeV, m(qq) > 50 GeV
γe -> qqe (γ from BS) 1.4 TeV CLIC_ILD 3483 150000 189800 7530.4 m(h) = 12 TeV, m(qq) > 50 GeV
ee -> vvllgamma 1.4 TeV CLIC_SiD 3492 2000000 1947000 187.3* m(h) = 12 TeV, m(ll) > 50 GeV, 8 < θ(l) < 172, preselection cuts for the h->Zgamma analysis
γγ -> qqee (both γ from EPA/noISR) 1.4 TeV CLIC_ILD 3507 10000 16700 0.17 m(h) = 12 TeV, m(qq) > 50 GeV, E(e) > 75 GeV
γγ -> qqee (first γ from EPA/noISR, second γ from BS) 1.4 TeV CLIC_ILD 3510 10000 19200 0.80 m(h) = 12 TeV, m(qq) > 50 GeV, E(e) > 75 GeV
γγ -> qqee (first γ from BS, second γ from EPA/noISR) 1.4 TeV CLIC_ILD 3513 10000 19300 0.80 m(h) = 12 TeV, m(qq) > 50 GeV, E(e) > 75 GeV
γγ -> qqee (both γ from BS) 1.4 TeV CLIC_ILD 3516 10000 16100 4.21 m(h) = 12 TeV, m(qq) > 50 GeV, E(e) > 75 GeV
γγ -> qq (both γ from EPA/noISR) 1.4 TeV CLIC_SiD 3633 100000 96600 3495.4 WHIZARD V54, m(h) = 12 TeV, m(qq) > 50 GeV
γγ -> qq (first γ from EPA/noISR, second γ from BS) 1.4 TeV CLIC_SiD 3636 100000 95200 17335.4 WHIZARD V54, m(h) = 12 TeV, m(qq) > 50 GeV
γγ -> qq (first γ from BS, second γ from EPA/noISR) 1.4 TeV CLIC_SiD 3639 100000 97200 17328.0 WHIZARD V54, m(h) = 12 TeV, m(qq) > 50 GeV
γγ -> qq (both γ from BS) 1.4 TeV CLIC_SiD 3642 100000 96500 73600.5 WHIZARD V54, m(h) = 12 TeV, m(qq) > 50 GeV
γγ -> qq (both γ from EPA/noISR) 3 TeV CLIC_SiD 3645 100000 71000 4228.2 WHIZARD V54, m(h) = 12 TeV, m(qq) > 50 GeV
γγ -> qq (first γ from EPA/noISR, second γ from BS) 3 TeV CLIC_SiD 3648 100000 81700 21893.8 WHIZARD V54, m(h) = 12 TeV, m(qq) > 50 GeV
γγ -> qq (first γ from BS, second γ from EPA/noISR) 3 TeV CLIC_SiD 3651 100000 79500 21888.7 WHIZARD V54, m(h) = 12 TeV, m(qq) > 50 GeV
γγ -> qq (both γ from BS) 3 TeV CLIC_SiD 3654 100000 91100 77365.9 WHIZARD V54, m(h) = 12 TeV, m(qq) > 50 GeV
γγ -> qqqq (both γ from EPA) 1.4 TeV CLIC_SiD 3661 100000 88600 187.5 WHIZARD V54, m(h) = 12 TeV, m(qqqq) > 50 GeV, alpha_s = 1e-6
γγ -> qqqq (first γ from EPA, second γ from BS) 1.4 TeV CLIC_SiD 3664 100000 85000 991.0 WHIZARD V54, m(h) = 12 TeV, m(qqqq) > 50 GeV, alpha_s = 1e-6
γγ -> qqqq (first γ from BS, second γ from EPA) 1.4 TeV CLIC_SiD 3667 100000 86500 986.1 WHIZARD V54, m(h) = 12 TeV, m(qqqq) > 50 GeV, alpha_s = 1e-6
γγ -> qqqq (both γ from BS) 1.4 TeV CLIC_SiD 3670 100000 85100 5489.9 WHIZARD V54, m(h) = 12 TeV, m(qqqq) > 50 GeV, alpha_s = 1e-6
γγ -> qqqq (both γ from EPA) 3 TeV CLIC_SiD 3673 100000 66000 402.7 WHIZARD V54, m(h) = 12 TeV, m(qqqq) > 50 GeV, alpha_s = 1e-6
γγ -> qqqq (first γ from EPA, second γ from BS) 3 TeV CLIC_SiD 3676 100000 89500 2422.8 WHIZARD V54, m(h) = 12 TeV, m(qqqq) > 50 GeV, alpha_s = 1e-6
γγ -> qqqq (first γ from BS, second γ from EPA) 3 TeV CLIC_SiD 3679 100000 98400 2420.7 WHIZARD V54, m(h) = 12 TeV, m(qqqq) > 50 GeV, alpha_s = 1e-6
γγ -> qqqq (both γ from BS) 3 TeV CLIC_SiD 3682 100000 119800 13050.2 WHIZARD V54, m(h) = 12 TeV, m(qqqq) > 50 GeV, alpha_s = 1e-6
γγ -> mu mu nu nu (both γ from EPA/noISR) 3 TeV CLIC_SiD 3788 50000 48600 12.7 WHIZARD V55, m(h) = 12 TeV, nu = nu_mu
γγ -> mu mu nu nu (first γ from EPA/noISR, second γ from BS) 3 TeV CLIC_SiD 3791 100000 101300 76.1 WHIZARD V55, m(h) = 12 TeV, nu = nu_mu
γγ -> mu mu nu nu (second γ from EPA/noISR, first γ from BS) 3 TeV CLIC_SiD 3794 100000 103100 76.0 WHIZARD V55, m(h) = 12 TeV, nu = nu_mu
γγ -> mu mu nu nu (both γ from BS) 3 TeV CLIC_SiD 3797 400000 380300 409.8 WHIZARD V55, m(h) = 12 TeV, nu = nu_mu
eγ -> e mu mu nu nu (γ from EPA/noISR) 3 TeV CLIC_SiD 3800 60000 52400 8.7 WHIZARD V55, m(h) = 12 TeV, nu = nu_mu
eγ -> e mu mu nu nu (γ from BS) 3 TeV CLIC_SiD 3803 100000 96500 38.3 WHIZARD V55, m(h) = 12 TeV, nu = nu_mu
γe -> e mu mu nu nu (γ from EPA/noISR) 3 TeV CLIC_SiD 3806 60000 57100 8.7 WHIZARD V55, m(h) = 12 TeV, nu = nu_mu
γe -> e mu mu nu nu (γ from BS) 3 TeV CLIC_SiD 3809 100000 93800 38.2 WHIZARD V55, m(h) = 12 TeV, nu = nu_mu
eγ -> e mu mu (γ from EPA/noISR) 3 TeV CLIC_SiD 3812 400000 184700 310.4 WHIZARD V55, m(h) = 12 TeV, 100 GeV < m(mu,mu) < 150 GeV, 8 < θ(mu) < 172
eγ -> e mu mu (γ from BS) 3 TeV CLIC_SiD 3815 500000 630900 335.2 WHIZARD V55, m(h) = 12 TeV, 100 GeV < m(mu,mu) < 150 GeV, 8 < θ(mu) < 172
γe -> e mu mu (γ from EPA/noISR) 3 TeV CLIC_SiD 3818 400000 183200 309.1 WHIZARD V55, m(h) = 12 TeV, 100 GeV < m(mu,mu) < 150 GeV, 8 < θ(mu) < 172
γe -> e mu mu (γ from BS) 3 TeV CLIC_SiD 3821 500000 640500 336.6 WHIZARD V55, m(h) = 12 TeV, 100 GeV < m(mu,mu) < 150 GeV, 8 < θ(mu) < 172
eγ -> qqe (γ from EPA/noISR) 1.4 TeV CLIC_SiD 3758 100000 96200
2664.5 WHIZARD V55, m(h) = 12 TeV, m(qq) > 50 GeV
eγ -> qqe (γ from BS) 1.4 TeV CLIC_SiD 3761 100000 96500
7517.2 WHIZARD V55, m(h) = 12 TeV, m(qq) > 50 GeV
γe -> qqe (γ from EPA/noISR) 1.4 TeV CLIC_SiD 3764 100000 96600
2664.6 WHIZARD V55, m(h) = 12 TeV, m(qq) > 50 GeV
γe -> qqe (γ from BS) 1.4 TeV CLIC_SiD 3767 100000 95800
7529.5 WHIZARD V55, m(h) = 12 TeV, m(qq) > 50 GeV
eγ -> qqe (γ from EPA/noISR) 3 TeV CLIC_SiD 3770 100000 58700
3525.2 WHIZARD V55, m(h) = 12 TeV, m(qq) > 50 GeV
eγ -> qqe (γ from BS) 3 TeV CLIC_SiD 3773 100000 83000
8530.8 WHIZARD V55, m(h) = 12 TeV, m(qq) > 50 GeV
γe -> qqe (γ from EPA/noISR) 3 TeV CLIC_SiD 3776 100000 58100 3523.4 WHIZARD V55, m(h) = 12 TeV, m(qq) > 50 GeV
γe -> qqe (γ from BS) 3 TeV CLIC_SiD 3779 100000 84600
8533.2 WHIZARD V55, m(h) = 12 TeV, m(qq) > 50 GeV
eγ -> qqnu (γ from EPA/noISR) 1.4 TeV CLIC_SiD 3848 100000 93400 3874.6 WHIZARD V55, m(h) = 12 TeV, m(qq) > 50 GeV
eγ -> qqnu (γ from BS) 1.4 TeV CLIC_SiD 3851 100000 90400 14407.9 WHIZARD V55, m(h) = 12 TeV, m(qq) > 50 GeV
γe -> qqnu (γ from EPA/noISR) 1.4 TeV CLIC_SiD 3854 100000 92600 3875.1 WHIZARD V55, m(h) = 12 TeV, m(qq) > 50 GeV
γe -> qqnu (γ from BS) 1.4 TeV CLIC_SiD 3857 100000 95900 14384.0 WHIZARD V55, m(h) = 12 TeV, m(qq) > 50 GeV
eγ -> qqnu (γ from EPA/noISR) 3 TeV CLIC_SiD 3836 100000 70300 6417.5 WHIZARD V55, m(h) = 12 TeV, m(qq) > 50 GeV
eγ -> qqnu (γ from BS) 3 TeV CLIC_SiD 3839 100000 93400 21234.9 WHIZARD V55, m(h) = 12 TeV, m(qq) > 50 GeV
γe -> qqnu (γ from EPA/noISR) 3 TeV CLIC_SiD 3842 100000 63100 6414.1 WHIZARD V55, m(h) = 12 TeV, m(qq) > 50 GeV
γe -> qqnu (γ from BS) 3 TeV CLIC_SiD 3845 100000 92900 21230.6 WHIZARD V55, m(h) = 12 TeV, m(qq) > 50 GeV
γγ -> tautaull (both γ from EPA/noISR) 1.4 TeV CLIC_ILD 3872 20000 22600 24.9* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_taus_1400.txt")
γγ -> tautaull (first γ from EPA/noISR, second γ from BS) 1.4 TeV CLIC_ILD 3875 50000 46800 127.5* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_taus_1400.txt")
γγ -> tautaull (first γ from BS, second γ from EPA/noISR) 1.4 TeV CLIC_ILD 3878 50000 48600 127.2* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_taus_1400.txt")
γγ -> tautaull (both γ from BS) 1.4 TeV CLIC_ILD 3881 100000 123600 625.4* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_taus_1400.txt")
γγ -> tautauvv (both γ from EPA/noISR) 1.4 TeV CLIC_ILD 3896 20000 19550 5.63* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_taus_1400.txt")
γγ -> tautauvv (first γ from EPA/noISR, second γ from BS) 1.4 TeV CLIC_ILD 3899 50000 46000 29.7* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_taus_1400.txt")
γγ -> tautauvv (first γ from BS, second γ from EPA/noISR) 1.4 TeV CLIC_ILD 3902 50000 50050 29.6* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_taus_1400.txt")
γγ -> tautauvv (both γ from BS) 1.4 TeV CLIC_ILD 3905 100000 93900 164.7* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_taus_1400.txt")
eγ -> eqq (γ from EPA/noISR) 1.4 TeV CLIC_ILD 3908 200000 215600 15512.2* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_quarks_1400.txt")
eγ -> eqq (γ from BS) 1.4 TeV CLIC_ILD 3911 200000 213350 37309.8* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_quarks_1400.txt")
γe -> eqq (γ from EPA/noISR) 1.4 TeV CLIC_ILD 3914 200000 218000 15511.4* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_quarks_1400.txt")
γe -> eqq (γ from BS) 1.4 TeV CLIC_ILD 3917 200000 214750 37362.3* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_quarks_1400.txt")
eγ -> qqvve (γ from EPA/noISR) 1.4 TeV CLIC_ILD 3932 20000 27300 3.33* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_quarks_1400.txt")
eγ -> qqvve (γ from BS) 1.4 TeV CLIC_ILD 3935 20000 25750 15.1* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_quarks_1400.txt")
γe -> qqvve (γ from EPA/noISR) 1.4 TeV CLIC_ILD 3938 20000 22200 3.33* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_quarks_1400.txt")
γe -> qqvve (γ from BS) 1.4 TeV CLIC_ILD 3941 20000 24700 15.0* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_quarks_1400.txt")
γγ -> tautau (both γ from EPA/noISR) 1.4 TeV CLIC_ILD 3944 300000 325350 185645.1* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_taus_1400.txt")
γγ -> tautau (first γ from EPA/noISR, second γ from BS) 1.4 TeV CLIC_ILD 3947 300000 322100 905918.4* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_taus_1400.txt")
γγ -> tautau (first γ from BS, second γ from EPA/noISR) 1.4 TeV CLIC_ILD 3950 300000 329800
906645.7* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_taus_1400.txt")
γγ -> tautau (both γ from BS) 1.4 TeV CLIC_ILD 3953 300000 323000
2522839.0* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_taus_1400.txt")
γγ -> qqvv (both γ from EPA/noISR) 1.4 TeV CLIC_ILD 3956 5000 5600 0.21* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_quarks_1400.txt")
γγ -> qqvv (first γ from EPA/noISR, second γ from BS) 1.4 TeV CLIC_ILD 3959 10000 11150 1.11* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_quarks_1400.txt")
γγ -> qqvv (first γ from BS, second γ from EPA/noISR) 1.4 TeV CLIC_ILD 3962 10000 9400 1.10* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_quarks_1400.txt")
γγ -> qqvv (both γ from BS) 1.4 TeV CLIC_ILD 3965 20000 27200 5.86* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_quarks_1400.txt")
γγ -> qqee (both γ from EPA/noISR) 1.4 TeV CLIC_ILD 3968 20000 20800 4.93* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_quarks_1400.txt")
γγ -> qqee (first γ from EPA/noISR, second γ from BS) 1.4 TeV CLIC_ILD 3971 20000 23700 25.3* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_quarks_1400.txt")
γγ -> qqee (first γ from BS, second γ from EPA/noISR) 1.4 TeV CLIC_ILD 3974 20000 21250 25.2* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_quarks_1400.txt")
γγ -> qqee (both γ from BS) 1.4 TeV CLIC_ILD 3977 20000 198850 124.2* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_quarks_1400.txt")
eγ -> tautaue (γ from EPA/noISR) 1.4 TeV CLIC_ILD 3980 200000 199000 27807.2* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_taus_1400.txt")
eγ -> tautaue (γ from BS) 1.4 TeV CLIC_ILD 3983 200000 199300 67154.0* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_taus_1400.txt")
γe -> tautaue (γ from EPA/noISR) 1.4 TeV CLIC_ILD 3986 200000 202050
27807.5* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_taus_1400.txt")
γe -> tautaue (γ from BS) 1.4 TeV CLIC_ILD 3989 200000 201150
67214.6* WHIZARD V55, m(h) = 12 TeV, preselection cuts for the H->tautau analysis ("cuts_taus_1400.txt")
ee -> mumuvv 3 TeV CLIC_SiD 3995 30000 38300 3.69 WHIZARD V55, m(h) = 12 TeV, 100 GeV < m(mu,mu) < 150 GeV
ee -> mumuee 3 TeV CLIC_SiD 3992 350000 380600 29.6 WHIZARD V55, m(h) = 12 TeV, 100 GeV < m(mu,mu) < 150 GeV, 8 < θ(mu) < 172
ee -> mumu 3 TeV CLIC_SiD 3998 30000 32300 4.53 WHIZARD V55, m(h) = 12 TeV, 100 GeV < m(mu,mu) < 150 GeV, 8 < θ(mu) < 172
ee -> qqqq 350 GeV CLIC_ILD 4031 1500000 1477000 5527.3 WHIZARD V55, m(h) = 12 TeV, alpha_s = 1e-6
ee -> qqqq 1.4 TeV CLIC_ILD 4034 500000 591800 1245.1 WHIZARD V55, m(h) = 12 TeV, alpha_s = 1e-6
ee -> qqqq 420 GeV CLIC_ILD 4206 1500000 1980500 4664.0 WHIZARD V55, m(h) = 12 TeV, alpha_s = 1e-6, 500 GeV lumi spectrum scaled, 0.17 γγ -> had. / BX
ee -> qq 420 GeV CLIC_ILD 4209 2000000 2494500 18442.9 WHIZARD V55, m(h) = 12 TeV, 500 GeV lumi spectrum scaled, 0.17 γγ -> had. / BX
ee -> qqlv 420 GeV CLIC_ILD 4212 1500000 1991000 5291.3 WHIZARD V55, m(h) = 12 TeV, 500 GeV lumi spectrum scaled, 0.17 γγ -> had. / BX
ee -> qqll 420 GeV CLIC_ILD 4215 500000 748500 1823.2 WHIZARD V55, m(h) = 12 TeV, 500 GeV lumi spectrum scaled, 0.17 γγ -> had. / BX
ee -> qqvv 420 GeV CLIC_ILD 4218 300000 497000 329.1 WHIZARD V55, m(h) = 12 TeV, 500 GeV lumi spectrum scaled, 0.17 γγ -> had. / BX
γγ -> qqll (both γ from EPA/noISR) 1.4 TeV CLIC_ILD 4266 100000 115000 567.9 WHIZARD V55, m(h) = 12 TeV, q=u,d,s,c,b, l=e,mu,tau, m(q,q,l,l) > 50 GeV
γγ -> qqll (first γ from EPA/noISR, second γ from BS) 1.4 TeV CLIC_ILD 4269 100000 112400 2900.8 WHIZARD V55, m(h) = 12 TeV, q=u,d,s,c,b, l=e,mu,tau, m(q,q,l,l) > 50 GeV
γγ -> qqll (first γ from BS, second γ from EPA/noISR) 1.4 TeV CLIC_ILD 4272 100000 112400 2894.5 WHIZARD V55, m(h) = 12 TeV, q=u,d,s,c,b, l=e,mu,tau, m(q,q,l,l) > 50 GeV
γγ -> qqll (both γ from BS) 1.4 TeV CLIC_ILD 4275 100000 212900 13930.2 WHIZARD V55, m(h) = 12 TeV, q=u,d,s,c,b, l=e,mu,tau, m(q,q,l,l) > 50 GeV
ee -> qq 250 GeV CLIC_ILD 4284 2000000 2499000 50994.5 WHIZARD V55, m(h) = 126 GeV, 350 GeV lumi spectrum scaled, no overlay
ee -> qqlv 250 GeV CLIC_ILD 4299 1500000 1747500 7417.8 WHIZARD V55, m(h) = 126 GeV, 350 GeV lumi spectrum scaled, no overlay
ee -> qqqq 250 GeV CLIC_ILD 4290 2000000 2483500 7405.8 WHIZARD V55, alpha_s = 1e-6, m(h) = 126 GeV, 350 GeV lumi spectrum scaled, no overlay
ee -> qqll 250 GeV CLIC_ILD 4293 500000 598500 1483.2 WHIZARD V55, m(h) = 126 GeV, 350 GeV lumi spectrum scaled, no overlay
ee -> qqvv 250 GeV CLIC_ILD 4296 300000 398500 363.9 WHIZARD V55, m(h) = 126 GeV, 350 GeV lumi spectrum scaled, no overlay
ee -> bb 350 GeV CLIC_ILD 4388 2000000 1974000 4861.1 WHIZARD V55, m(b,b) > 50 GeV, m(h) = 12 TeV
ee -> cc 350 GeV CLIC_ILD 4391 2000000 1999500 4886.8 WHIZARD V55, m(c,c) > 50 GeV, m(h) = 12 TeV
ee -> eeff 380 GeV CLIC_ILD 4412 500000 586500 4720.9 WHIZARD V55, f=u,d,s,c,b,e,mu,tau,nu_e,nu_mu,nu_tau, m(e,e) > 20 GeV, m(h) = 12 TeV
ee -> mumuff 380 GeV CLIC_ILD 4415 500000 593000 684.6 WHIZARD V55, f=u,d,s,c,b,e,mu,tau,nu_e,nu_mu,nu_tau, m(mu,mu) > 20 GeV, m(h) = 12 TeV
ee -> qq 3 TeV CLIC_ILD 4586 200000 196400 2948.9 WHIZARD V57, q=u,d,s,c,b, m(h) = 12 TeV
ee -> qqll 350 GeV CLIC_ILD 4625 2000000 1991500 1704.1 WHIZARD V57, m(h) = 12 TeV
ee -> qq 350 GeV CLIC_ILD 4698 2000000 1996000 24405.4 WHIZARD V57, q = u,d,s,c,b, m(q,q) > 50 GeV, m(h) = 12 TeV
ee -> qq 350 GeV CLIC_ILD 4701 500000 500000 24516.4 WHIZARD V57, no beam recoil, q = u,d,s,c,b, m(q,q) > 50 GeV, m(h) = 12 TeV
ee -> mumuvv 1.4 TeV CLIC_ILD 4732 500000 500000 129.2 WHIZARD V57, v = nu_e, nu_mu, nu_tau, (h) = 12 TeV
ee -> qq 350 GeV CLIC_ILD 4743 2000000 1992500 24406.6 like 4698, WHIZARD V57, q = u,d,s,c,b, m(q,q) > 50 GeV, m(h) = 12 TeV
ee -> qqqqvv 1.4 TeV CLIC_ILD 5527 300000 335300 23.2 WHIZARD V57, q = u,d,s,c,b, m(q,q,q,q) > 50 GeV, m(h) = 12 TeV, alpha_s = 1e-6
ee -> qqqqll 1.4 TeV CLIC_ILD 5572 1000000 1101100 62.1 WHIZARD V57, q = u,d,s,c,b, m(q,q,q,q) > 50 GeV, m(h) = 12 TeV, alpha_s = 1e-6
ee -> qqqqlv 1.4 TeV CLIC_ILD 5594 500000 715200 110.4 WHIZARD V57, q = u,d,s,c,b, m(q,q,q,q) > 50 GeV, m(h) = 12 TeV, alpha_s = 1e-6
ee -> qqqqvv 1.4 TeV CLIC_ILD 6183 1000000 1103700 23.2 WHIZARD V57, q = u,d,s,c,b, m(q,q,q,q) > 50 GeV, m(h) = 12 TeV, alpha_s = 1e-6
ee -> qqqqlv 1.4 TeV CLIC_ILD 6191 1000000 1164100 110.4 WHIZARD V57, q = u,d,s,c,b, m(q,q,q,q) > 50 GeV, m(h) = 12 TeV, alpha_s = 1e-6
eγ -> qqqqv (γ from EPA/noISR) 1.4 TeV CLIC_ILD 6497 150000 166000 17.3 WHIZARD V57, q = u,d,s,c,b, m(h) = 12 TeV, m(qqqq) > 50 GeV, alpha_s = 1e-6
eγ -> qqqqv (γ from BS) 1.4 TeV CLIC_ILD 6500 400000 413900 80.0 WHIZARD V57, q = u,d,s,c,b, m(h) = 12 TeV, m(qqqq) > 50 GeV, alpha_s = 1e-6
γe -> qqqqv (γ from EPA/noISR) 1.4 TeV CLIC_ILD 6503 150000 166600 17.5 WHIZARD V57, q = u,d,s,c,b, m(h) = 12 TeV, m(qqqq) > 50 GeV, alpha_s = 1e-6
γe -> qqqqv (γ from BS) 1.4 TeV CLIC_ILD 6506 400000 407300 79.5 WHIZARD V57, q = u,d,s,c,b, m(h) = 12 TeV, m(qqqq) > 50 GeV, alpha_s = 1e-6
ee -> qqqqlv 3 TeV CLIC_ILD 6540 250000 990000   WHIZARD V57, q = u,d,s,c,b, m(q,q,q,q) > 50 GeV, m(h) = 12 TeV, alpha_s = 1e-6 extended
ee -> qqqqlv 3 TeV CLIC_SiD 6546 250000 151450   WHIZARD V57, q = u,d,s,c,b, m(q,q,q,q) > 50 GeV, m(h) = 12 TeV, alpha_s = 1e-6
eγ -> qqqqv (γ from EPA/noISR) 3 TeV CLIC_ILD 6571 125000 138900 54.2 WHIZARD V57, q = u,d,s,c,b, m(h) = 12 TeV, m(qqqq) > 50 GeV, alpha_s = 1e-6
eγ -> qqqqv (γ from BS) 3 TeV CLIC_ILD 6574 500000 567000 262.5 WHIZARD V57, q = u,d,s,c,b, m(h) = 12 TeV, m(qqqq) > 50 GeV, alpha_s = 1e-6
γe -> qqqqv (γ from EPA/noISR) 3 TeV CLIC_ILD 6577 125000 138000 54.2 WHIZARD V57, q = u,d,s,c,b, m(h) = 12 TeV, m(qqqq) > 50 GeV, alpha_s = 1e-6
γe -> qqqqv (γ from BS) 3 TeV CLIC_ILD 6580 500000 571600 262.3 WHIZARD V57, q = u,d,s,c,b, m(h) = 12 TeV, m(qqqq) > 50 GeV, alpha_s = 1e-6
ee -> qqvv 3 TeV CLIC_ILD 6583 500000 575200 1317.5 WHIZARD V57, m(h) = 12 TeV
ee -> qqvv 1.4 TeV CLIC_SiD 6700 2000000 2391000 787.7 WHIZARD V57, m(h) = 12 TeV
γγ -> qqqq (both γ from EPA/noISR) 3 TeV CLIC_ILD 6721 100000 134700 402.7 WHIZARD V57, q = u,d,s,c,b, m(h) = 12 TeV, m(qqqq) > 50 GeV, alpha_s = 1e-6
γγ -> qqqq (first γ from EPA/noISR, second γ from BS) 3 TeV CLIC_ILD 6724 200000 268100 2423.1 WHIZARD V57, q = u,d,s,c,b, m(h) = 12 TeV, m(qqqq) > 50 GeV, alpha_s = 1e-6
γγ -> qqqq (first γ from BS, second γ from EPA/noISR) 3 TeV CLIC_ILD 6727 200000 273300 2420.6 WHIZARD V57, q = u,d,s,c,b, m(h) = 12 TeV, m(qqqq) > 50 GeV, alpha_s = 1e-6
γγ -> qqqq (both γ from BS) 3 TeV CLIC_ILD 6730 400000 509800 13050.3 WHIZARD V57, q = u,d,s,c,b, m(h) = 12 TeV, m(qqqq) > 50 GeV, alpha_s = 1e-6
eγ -> qqqqe (γ from EPA/noISR) 3 TeV CLIC_ILD 6733 60000 70300 287.8 WHIZARD V57, q = u,d,s,c,b, m(h) = 12 TeV, m(qqqq) > 50 GeV, alpha_s = 1e-6
eγ -> qqqqe (γ BS) 3 TeV CLIC_ILD 6736 100000 111800 1268.6 WHIZARD V57, q = u,d,s,c,b, m(h) = 12 TeV, m(qqqq) > 50 GeV, alpha_s = 1e-6
eγ -> qqqqe (γ from EPA/noISR) 3 TeV CLIC_ILD 6739 60000 70800 287.8 WHIZARD V57, q = u,d,s,c,b, m(h) = 12 TeV, m(qqqq) > 50 GeV, alpha_s = 1e-6
eγ -> qqqqe (γ BS) 3 TeV CLIC_ILD 6742 100000 114100 1267.3 WHIZARD V57, q = u,d,s,c,b, m(h) = 12 TeV, m(qqqq) > 50 GeV, alpha_s = 1e-6
ee -> qqlv 3 TeV CLIC_ILD 6747 2000000 2115000 5560.9 WHIZARD V57, q = u,d,s,c,b, m(h) = 12 TeV
ee -> qqqqll 3 TeV CLIC_ILD 6754 500000 728900 169.3 WHIZARD V57, q = u,d,s,c,b, m(h) = 12 TeV, m(qqqq) > 50 GeV, alpha_s = 1e-6
ee -> qqqqvv 3 TeV CLIC_ILD 6751 500000 2091900 71.5 WHIZARD V57, q = u,d,s,c,b, m(h) = 12 TeV, m(qqqq) > 50 GeV, alpha_s = 1e-6 extended
ee -> qqqq 3 TeV CLIC_ILD 6776 500000 3084200 546.5 WHIZARD V57, q = u,d,s,c,b, m(h) = 12 TeV, m(qqqq) > 50 GeV, alpha_s = 1e-6 extended
ee -> qqhvv 3 TeV CLIC_ILD 6779 10000 14600 3.06 WHIZARD V57, q = u,d,s, m(h) = 126 GeV
ee -> cchvv 3 TeV CLIC_ILD 6782 10000 14800 1.15 WHIZARD V57, m(h) = 126 GeV
ee -> bbhvv 3 TeV CLIC_ILD 6785 10000 14900 1.78 WHIZARD V57, m(h) = 126 GeV
ee -> qqhvv 1.4 TeV CLIC_ILD 6788 10000 15000 0.87 WHIZARD V57, q = u,d,s, m(h) = 126 GeV
ee -> cchvv 1.4 TeV CLIC_ILD 6791 10000 15000 0.37 WHIZARD V57, m(h) = 126 GeV
ee -> bbhvv 1.4 TeV CLIC_ILD 6794 10000 15000 0.48 WHIZARD V57, m(h) = 126 GeV
eγ -> qqqqv (γ from EPA/noISR) 1.4 TeV CLIC_ILD 6799 500000 587200 17.4 WHIZARD V57, q = u,d,s,c,b, m(h) = 12 TeV, m(qqqq) > 120 GeV, alpha_s = 1e-6
eγ -> qqqqv (γ from BS) 1.4 TeV CLIC_ILD 6802 500000 590000 79.8 WHIZARD V57, q = u,d,s,c,b, m(h) = 12 TeV, m(qqqq) > 120 GeV, alpha_s = 1e-6
γe -> qqqqv (γ from EPA/noISR) 1.4 TeV CLIC_ILD 6805 500000 589300 17.3 WHIZARD V57, q = u,d,s,c,b, m(h) = 12 TeV, m(qqqq) > 120 GeV, alpha_s = 1e-6
γe -> qqqqv (γ from BS) 1.4 TeV CLIC_ILD 6808 500000 590000 79.3 WHIZARD V57, q = u,d,s,c,b, m(h) = 12 TeV, m(qqqq) > 120 GeV, alpha_s = 1e-6
ee -> qqhvv 3 TeV CLIC_ILD 6901 150000 197700 3.06 WHIZARD V57, q = u,d,s, m(h) = 126 GeV
ee -> cchvv 3 TeV CLIC_ILD 6904 150000 197600 1.15 WHIZARD V57, m(h) = 126 GeV
ee -> bbhvv 3 TeV CLIC_ILD 6907 150000 198000 1.78 WHIZARD V57, m(h) = 126 GeV
ee -> qqhvv 1.4 TeV CLIC_ILD 6910 150000 197600 0.87 WHIZARD V57, q = u,d,s, m(h) = 126 GeV
ee -> cchvv 1.4 TeV CLIC_ILD 6913 150000 198100 0.37 WHIZARD V57, m(h) = 126 GeV
ee -> bbhvv 1.4 TeV CLIC_ILD 6916 150000 197900 0.48 WHIZARD V57, m(h) = 126 GeV
eγ -> qqhv (γ from EPA/noISR) 3 TeV CLIC_ILD 6942 50000 58600 11.7 WHIZARD V57, m(qq) > 50 GeV, m(h) = 126 GeV
eγ -> qqhv (γ from BS) 3 TeV CLIC_ILD 6945 200000 207700 58.6 WHIZARD V57, m(qq) > 50 GeV, m(h) = 126 GeV
γe -> qqhv (γ from EPA/noISR) 3 TeV CLIC_ILD 6948 50000 58000 11.7 WHIZARD V57, m(qq) > 50 GeV, m(h) = 126 GeV
γe -> qqhv (γ from BS) 3 TeV CLIC_ILD 6951 200000 209500 58.5 WHIZARD V57, m(qq) > 50 GeV, m(h) = 126 GeV
eγ -> qqhv (γ from EPA/noISR) 1.4 TeV CLIC_ILD 6954 10000 15000 3.39 WHIZARD V57, m(qq) > 50 GeV, m(h) = 126 GeV
eγ -> qqhv (γ from BS) 1.4 TeV CLIC_ILD 6957 25000 30000 15.8 WHIZARD V57, m(qq) > 50 GeV, m(h) = 126 GeV
γe -> qqhv (γ from EPA/noISR) 1.4 TeV CLIC_ILD 6960 10000 15000 3.39 WHIZARD V57, m(qq) > 50 GeV, m(h) = 126 GeV
γe -> qqhv (γ from BS) 1.4 TeV CLIC_ILD 6963 25000 30000 15.7 WHIZARD V57, m(qq) > 50 GeV, m(h) = 126 GeV
ee -> qqγγ 3 TeV CLIC_ILD 6966 250000 299600 72.3 WHIZARD V57, m(h) = 12 TeV
ee -> qqγ 3 TeV CLIC_ILD 6969 1000000 1198600 583.6 WHIZARD V57, m(h) = 12 TeV
ee -> γvv 3 TeV CLIC_ILD 6981 150000 194900 16806.4* WHIZARD V57, m(h) = 12 TeV, preselection cuts for the H->gammagamma analysis ("cuts_h_gammagamma_3000.txt")
ee -> γγee 3 TeV CLIC_ILD 6984 120000 144900 4244.7* WHIZARD V57, m(h) = 12 TeV, preselection cuts for the H->gammagamma analysis ("cuts_h_gammagamma_3000.txt")
ee -> γγvv 3 TeV CLIC_ILD 7014 120000 155500 2616.6* WHIZARD V57, m(h) = 12 TeV, preselection cuts for the H->gammagamma analysis ("cuts_h_gammagamma_3000.txt")
ee -> γγ 3 TeV CLIC_ILD 7017 20000 29900 866.9* WHIZARD V57, m(h) = 12 TeV, preselection cuts for the H->gammagamma analysis ("cuts_h_gammagamma_3000.txt")
ee -> eeγ 3 TeV CLIC_ILD 7020 3000000 3039000 185392.3* WHIZARD V57, m(h) = 12 TeV, preselection cuts for the H->gammagamma analysis ("cuts_h_gammagamma_3000.txt")
eγ -> qqhv (γ from EPA/noISR) 1.4 TeV CLIC_ILD 6990 150000 199900 3.39 WHIZARD V57, m(qq) > 50 GeV, m(h) = 126 GeV
eγ -> qqhv (γ from BS) 1.4 TeV CLIC_ILD 6993 300000 399400 15.8 WHIZARD V57, m(qq) > 50 GeV, m(h) = 126 GeV
γe -> qqhv (γ from EPA/noISR) 1.4 TeV CLIC_ILD 6996 150000 199400 3.39 WHIZARD V57, m(qq) > 50 GeV, m(h) = 126 GeV
γe -> qqhv (γ from BS) 1.4 TeV CLIC_ILD 6999 300000 399400 15.7 WHIZARD V57, m(qq) > 50 GeV, m(h) = 126 GeV
γγ -> qqll (both γ from EPA/noISR) 3 TeV CLIC_ILD 7869 100000 119700 862.3 WHIZARD V57, m(h) = 12 TeV, q=u,d,s,c,b, l=e,mu,tau, m(q,q,l,l) > 50 GeV
γγ -> qqll (first γ from EPA/noISR, second γ from BS) 3 TeV CLIC_ILD 7872 200000 239500 4801.8 WHIZARD V57, m(h) = 12 TeV, q=u,d,s,c,b, l=e,mu,tau, m(q,q,l,l) > 50 GeV
γγ -> qqll (first γ from BS, second γ from EPA/noISR) 3 TeV CLIC_ILD 7875 200000 239200 4799.4 WHIZARD V57, m(h) = 12 TeV, q=u,d,s,c,b, l=e,mu,tau, m(q,q,l,l) > 50 GeV
γγ -> qqll (both γ from BS) 3 TeV CLIC_ILD 7878 400000 477500 21480.8 WHIZARD V57, m(h) = 12 TeV, q=u,d,s,c,b, l=e,mu,tau, m(q,q,l,l) > 50 GeV
γγ -> qq (both γ from EPA) 3 TeV CLIC_ILD 7893 100000 119900 4228.1 WHIZARD V57, m(h) = 12 TeV, m(qq) > 50 GeV
γγ -> qq (first γ from EPA, second γ from BS) 3 TeV CLIC_ILD 7896 200000 239800 21891.1 WHIZARD V57, m(h) = 12 TeV, m(qq) > 50 GeV
γγ -> qq (first γ from BS, second γ from EPA) 3 TeV CLIC_ILD 7899 200000 239900 21891.6 WHIZARD V57, m(h) = 12 TeV, m(qq) > 50 GeV
γγ -> qq (both γ from BS) 3 TeV CLIC_ILD 7902 400000 479800 77366.8 WHIZARD V57, m(h) = 12 TeV, m(qq) > 50 GeV
eγ -> qqe (γ from EPA/noISR) 3 TeV CLIC_ILD 7924 100000 119300 3525.5 WHIZARD V57, m(h) = 12 TeV, m(qq) > 50 GeV NEW
eγ -> qqe (γ from BS) 3 TeV CLIC_ILD 7927 100000 119200 8531.3 WHIZARD V57, m(h) = 12 TeV, m(qq) > 50 GeV NEW
γe -> qqe (γ from EPA/noISR) 3 TeV CLIC_ILD 7930 100000 119100 3523.8 WHIZARD V57, m(h) = 12 TeV, m(qq) > 50 GeV NEW
γe -> qqe (γ from BS) 3 TeV CLIC_ILD 7933 100000 119500 8534.5 WHIZARD V57, m(h) = 12 TeV, m(qq) > 50 GeV NEW
eγ -> qqv (γ from EPA/noISR) 3 TeV CLIC_ILD 7956 100000 119500 6417.3 WHIZARD V57, m(h) = 12 TeV, m(qq) > 50 GeV NEW
eγ -> qqv (γ from BS) 3 TeV CLIC_ILD 7959 200000 239400 21235.0 WHIZARD V57, m(h) = 12 TeV, m(qq) > 50 GeV NEW
γe -> qqv (γ from EPA/noISR) 3 TeV CLIC_ILD 7962 100000 119500 6414.6 WHIZARD V57, m(h) = 12 TeV, m(qq) > 50 GeV NEW
γe -> qqv (γ from BS) 3 TeV CLIC_ILD 7965 200000 239900 21231.3 WHIZARD V57, m(h) = 12 TeV, m(qq) > 50 GeV NEW
* = does not include the reduction factor due to the preselection cuts, but includes the effect of possible kinematic cuts in WHIZARD
** = preliminary number, will be updated

EPA = Equivalent-photon approximation

BS = Beamstrahlung

Existing background samples

An overview of all samples can be found here: https://twiki.cern.ch/twiki/bin/view/CLIC/ReconstructedData. Some of the older samples should not be used any more due to outdated values of the SM Higgs mass or other issues. The table below contains a selection of samples without any known problems that can be used for the ongoing analyses.

Type Energy Detector ProdID Events Comments
ee -> qqqqvv 1.4 TeV CLIC_SiD 1081 446800 no beam recoil
ee -> qqqq 1.4 TeV CLIC_SiD 1097 507600 no beam recoil, q = u,d,s,c,b
ee -> qqqqll 1.4 TeV CLIC_SiD 1089 330000 no beam recoil
ee -> qqqqlv 1.4 TeV CLIC_SiD 1085 292800 no beam recoil
ee -> qqqq 350 GeV CLIC_ILD 1551 1212800 no beam recoil, m(h) = 126 GeV
ee -> qqqqvv 3 TeV CLIC_SiD 1460 423200 no beam recoil
ee -> qqqqll 3 TeV CLIC_SiD 1458 101600 no beam recoil
ee -> WWZ 350 GeV CLIC_ILD 1439 40000 no beam recoil
ee -> qq 350 GeV CLIC_ILD 1419 1005000 no beam recoil
ee -> ZZ 350 GeV CLIC_ILD 1373 301000 no beam recoil
ee -> WW 350 GeV CLIC_ILD 1371 599000 no beam recoil
ee -> ttbar 350 GeV CLIC_ILD 1369+1434 21000+220000 no beam recoil
ee -> qqvv 3 TeV CLIC_SiD 1315 115860 no beam recoil
ee -> qqqq 3 TeV CLIC_SiD 1112 70000 no beam recoil, q = u,d,s,c,b
ee -> qqqqvv 3 TeV CLIC_SiD 1460 423200 no beam recoil, m(h) = 12 TeV
ee -> qqqqll 3 TeV CLIC_SiD 1458 101600 no beam recoil
ee -> qqvv 3 TeV CLIC_SiD 636 290000 no beam recoil, no Higgs
ee -> qqev 3 TeV CLIC_SiD 598 95430 no beam recoil
ee -> qqee 3 TeV CLIC_SiD 600 80340 no beam recoil
ee -> qq 3 TeV CLIC_SiD 599 99720 no beam recoil
ee -> tau+tau- 1.4 TeV CLIC_ILD 866 60000 no beam recoil, preselection cuts as described in LCD-Note-2012-004
ee -> tau+tau-vv 1.4 TeV CLIC_ILD 868 356000 no beam recoil, preselection cuts as described in LCD-Note-2012-004
ee -> mu+mu-tau+tau- 1.4 TeV CLIC_ILD 877 44000 no beam recoil, preselection cuts as described in LCD-Note-2012-004
ee -> e+e-tau+tau- 1.4 TeV CLIC_ILD 887 177600 no beam recoil, preselection cuts as described in LCD-Note-2012-004

How to find the files

The locations of the produced files can be found using the web interface available in the data menu on the DIRAC monitoring webpage. A Grid certificate is needed for this purpose. More information are available at this location: https://twiki.cern.ch/twiki/bin/view/CLIC/DiracForUsers.

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Topic revision: r294 - 2018-03-23 - PhilippRoloff
 
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