CLIC Web>Detector>MonteCarloSamplesForTopPhysics (2017-11-28, PhilippRoloff)

Monte Carlo samples for top reconstruction studies

The numbers of produced events were last updated on 28/11/2017 at 13:20
All samples were generated using WHIZARD 1.95 unless explicitly stated otherwise.

Signal sample (6-fermion production compatible with ttbar) at 380 GeV assuming unpolarised beams

WHIZARD V57
m(h) = 12 TeV
alpha_s = 1e-6
m(u) = m(d) = m(s) = m(c) = m(b) = m(e) = m(mu) = 0, m(tau) = 1.777 GeV
"l" = mu, tau
"v" = nu_e, nu_mu, nu_tau
"y" = d, s, b
"x" = u, c
All subsamples in the following table need to be scaled to the same luminosity and then added
CLIC_ILD, 350 GeV luminosity spectrum scaled to 380 GeV, 0.0464 γγ -> had. / BX

Type	ProdID	Events planned	Events produced	σ [fb]
ee -> yyveev	4517	10000	10500	5.1
ee -> yyveyx	4523	30000	32000	29.7
ee -> yyxyev	4535	30000	32000	29.7
ee -> yyuyyc	4541	40000	41500	41.8
ee -> yycyyu	4544	40000	45000	41.8
ee -> dduyyu	4547	40000	66000	37.6
ee -> ssussu	4550	10000	9500	0.0064
ee -> ssubbu	4553	10000	10000	0.12
ee -> bbubbu	4556	10000	10000	0.0058
ee -> ddcyyc	4559	10000	15500	0.38
ee -> sscssc	4562	10000	10000	0.22
ee -> sscbbc	4565	40000	39500	36.9
ee -> bbcbbc	4568	10000	10000	0.0059
ee -> yyvelv	4571	10000	10000	10.1
ee -> yyvlev	4574	10000	10000	10.1
ee -> yyvllv	4577	20000	19500	20.2
ee -> yyvlyx	4580	60000	67000	59.3
ee -> yyxylv	4583	60000	66000	59.3

Signal sample (6-fermion production compatible with ttbar) at 380 GeV assuming P(e-) = -80%

WHIZARD V57
m(h) = 12 TeV
alpha_s = 1e-6
m(u) = m(d) = m(s) = m(c) = m(b) = m(e) = m(mu) = 0, m(tau) = 1.777 GeV
"l" = mu, tau
"v" = nu_e, nu_mu, nu_tau
"y" = d, s, b
"x" = u, c
All subsamples in the following table need to be scaled to the same luminosity and then added
CLIC_ILD, 350 GeV luminosity spectrum scaled to 380 GeV, 0.0464 γγ -> had. / BX

Type	ProdID	Events planned	Events produced	σ [fb]
ee -> yyveev	5813	10000	48500	6.94
ee -> yyveyx	5816	40000	51500	40.4
ee -> yyxyev	5819	40000	42500	40.4
ee -> yyuyyc	5822	60000	76500	56.7
ee -> yycyyu	5825	60000	76500	56.7
ee -> dduyyu	5828	50000	80500	51.0
ee -> ssussu	5831	10000	48000	0.009
ee -> ssubbu	5834	10000	50000	0.164
ee -> bbubbu	5837	10000	49500	0.008
ee -> ddcyyc	5840	10000	29500	0.619
ee -> sscssc	5843	10000	48000	0.392
ee -> sscbbc	5846	50000	54500	49.8
ee -> bbcbbc	5849	10000	49500	0.008
ee -> yyvelv	5852	20000	49000	13.7
ee -> yyvlev	5855	20000	46500	13.7
ee -> yyvllv	5858	30000	40000	27.5
ee -> yyvlyx	5861	80000	96000	80.5
ee -> yyxylv	5864	80000	80500	80.5

Signal sample (6-fermion production compatible with ttbar) at 380 GeV assuming P(e-) = +80%

WHIZARD V57
m(h) = 12 TeV
alpha_s = 1e-6
m(u) = m(d) = m(s) = m(c) = m(b) = m(e) = m(mu) = 0, m(tau) = 1.777 GeV
"l" = mu, tau
"v" = nu_e, nu_mu, nu_tau
"y" = d, s, b
"x" = u, c
All subsamples in the following table need to be scaled to the same luminosity and then added
CLIC_ILD, 350 GeV luminosity spectrum scaled to 380 GeV, 0.0464 γγ -> had. / BX

Type	ProdID	Events planned	Events produced	σ [fb]
ee -> yyveev	5904	10000	12000	3.27
ee -> yyveyx	5907	10000	10000	19.0
ee -> yyxyev	5910	10000	13000	19.1
ee -> yyuyyc	5913	15000	18000	26.9
ee -> yycyyu	5916	15000	21000	26.9
ee -> dduyyu	5919	15000	19500	24.2
ee -> ssussu	5922	10000	11000	0.0036
ee -> ssubbu	5925	10000	11000	0.078
ee -> bbubbu	5928	10000	10500	0.0034
ee -> ddcyyc	5931	10000	13000	0.142
ee -> sscssc	5934	10000	11000	0.051
ee -> sscbbc	5937	15000	29000	23.9
ee -> bbcbbc	5940	10000	11000	0.0035
ee -> yyvelv	5943	10000	11000	6.47
ee -> yyvlev	5946	10000	13000	6.49
ee -> yyvllv	5949	10000	16000	13.0
ee -> yyvlyx	5952	40000	74500	38.1
ee -> yyxylv	5955	40000	62000	38.1

Samples to train the flavour tagging at 380 GeV

Type	ProdID	Detector	Events planned	Events produced	Comments
ee -> bbbbbb	5456	CLIC_ILD	20000	24900
ee -> cccccc	5459	CLIC_ILD	20000	24100
ee -> qqqqqq	5462	CLIC_ILD	20000	23500	q = u,d,s

WHIZARD background samples at 380 GeV

WHIZARD V57
m(u) = m(d) = m(s) = m(c) = m(b) = m(e) = m(mu) = 0, m(tau) = 1.777 GeV
CLIC_ILD, 350 GeV luminosity spectrum scaled to 380 GeV, 0.0464 γγ -> had. / BX

Type	ProdID	Events planned	Events produced	σ [fb]	Comments
ee -> qqqq	8793	2500000	2693500	5074.8	m(H) = 12 TeV; alpha_s = 1e-6; q=u,d,s,c,b
ee -> qqlv	8799	2500000	2730000	5578.7	m(H) = 12 TeV; q=u,d,s,c,b; l=e,mu,tau; v=nu_e,nu_mu,nu_tau
ee -> qqvv	8819	500000	593500	324	m(H) = 12 TeV; q=u,d,s,c,b; v=nu_e,nu_mu,nu_tau
ee -> qqll	8827	1000000	1079500	1763.8	m(H) = 12 TeV; q=u,d,s,c,b; l=e,mu,tau
ee -> qq	8837	2500000	2749000	21231	m(H) = 12 TeV; q=u,d,s,c,b
ee -> qqqq	8879	2500000	2501500	8912.0	P(e-) = -80%; m(H) = 12 TeV; alpha_s = 1e-6; q=u,d,s,c,b NEW
ee -> qqqq	8899	1000000	1334500	1237.4	P(e-) = +80%; m(H) = 12 TeV; alpha_s = 1e-6; q=u,d,s,c,b NEW
ee -> qqlv	8907	2500000	2752000	9797.8	P(e-) = -80%; m(H) = 12 TeV; q=u,d,s,c,b; l=e,mu,tau; v=nu_e,nu_mu,nu_tau NEW
ee -> qqlv	8910	1000000	1256000	1359.6	P(e-) = +80%; m(H) = 12 TeV; q=u,d,s,c,b; l=e,mu,tau; v=nu_e,nu_mu,nu_tau NEW
ee -> qqvv	8919	500000	515000	485.5	P(e-) = -80%; m(H) = 12 TeV; q=u,d,s,c,b; v=nu_e,nu_mu,nu_tau NEW
ee -> qqvv	8922	200000	212000	162.6	P(e-) = +80%; m(H) = 12 TeV; q=u,d,s,c,b; v=nu_e,nu_mu,nu_tau NEW
ee -> qqll	8925	1000000	1266500	1841.2	P(e-) = -80%; m(H) = 12 TeV; q=u,d,s,c,b; l=e,mu,tau NEW
ee -> qqll	8928	1000000	1280500	1686.3	P(e-) = +80%; m(H) = 12 TeV; q=u,d,s,c,b; l=e,mu,tau NEW
ee -> qq	8943	2500000	2730500	26092	P(e-) = -80%; m(H) = 12 TeV; q=u,d,s,c,b NEW
ee -> qq	8946	2500000	2795000	16368	P(e-) = +80%; m(H) = 12 TeV; q=u,d,s,c,b NEW

Signal sample (6-fermion production compatible with ttbar) at 500 GeV assuming P(e-) = -100%, P(e+) = + 100%

WHIZARD V57
m(h) = 12 TeV
alpha_s = 1e-6
m(u) = m(d) = m(s) = m(c) = m(b) = m(e) = m(mu) = 0, m(tau) = 1.777 GeV
"l" = mu, tau
"v" = nu_e, nu_mu, nu_tau
"y" = d, s, b
"x" = u, c
All subsamples in the following table need to be scaled to the same luminosity and then added
CLIC_ILD, 500 GeV, 0.3 γγ -> had. / BX

Type	ProdID	Events planned	Events produced	σ [fb]
ee -> yyveev	6296	20000	25000	19.9
ee -> yyveyx	6326	120000	124500	115.4
ee -> yyxyev	6335	120000	131000	115.4
ee -> yyuyyc	6344	170000	223000	162.7
ee -> yycyyu	6353	170000	227000	162.7
ee -> dduyyu	6362	150000	397000	146.7
ee -> ssussu	6371	10000	11500	0.032
ee -> ssubbu	6380	10000	14500	0.47
ee -> bbubbu	6389	10000	10000	0.026
ee -> ddcyyc	6398	10000	13500	2.64
ee -> sscssc	6407	10000	16500	1.90
ee -> sscbbc	6416	150000	270000	141.6
ee -> bbcbbc	6425	10000	12000	0.027
ee -> yyvelv	6434	40000	72500	39.1
ee -> yyvlev	6443	40000	82000	39.1
ee -> yyvllv	6452	80000	122500	77.7
ee -> yyvlyx	6461	230000	487000	228.8
ee -> yyxylv	6470	230000	325000	228.8

Signal sample (6-fermion production compatible with ttbar) at 500 GeV assuming P(e-) = +100%, P(e-) = -100%

WHIZARD V57
m(h) = 12 TeV
alpha_s = 1e-6
m(u) = m(d) = m(s) = m(c) = m(b) = m(e) = m(mu) = 0, m(tau) = 1.777 GeV
"l" = mu, tau
"v" = nu_e, nu_mu, nu_tau
"y" = d, s, b
"x" = u, c
All subsamples in the following table need to be scaled to the same luminosity and then added
CLIC_ILD, 500 GeV, 0.3 γγ -> had. / BX

Type	ProdID	Events planned	Events produced	σ [fb]
ee -> yyveev	6293	10000	12000	7.47
ee -> yyveyx	6329	50000	77500	43.9
ee -> yyxyev	6338	50000	70500	43.9
ee -> yyuyyc	6347	70000	80500	63.3
ee -> yycyyu	6356	70000	85500	63.3
ee -> dduyyu	6365	60000	140500	57.0
ee -> ssussu	6374	10000	11500	0.0078
ee -> ssubbu	6383	10000	13000	0.18
ee -> bbubbu	6392	10000	16000	0.0077
ee -> ddcyyc	6401	10000	14500	0.23
ee -> sscssc	6410	10000	12000	0.026
ee -> sscbbc	6419	60000	91000	56.5
ee -> bbcbbc	6428	10000	10500	0.0079
ee -> yyvelv	6437	20000	36000	14.8
ee -> yyvlev	6446	20000	34500	14.9
ee -> yyvllv	6455	30000	52500	29.8
ee -> yyvlyx	6464	90000	172000	87.8
ee -> yyxylv	6473	90000	107000	87.8

Signal sample (6-fermion production compatible with ttbar) at 500 GeV assuming unpolarised beams

WHIZARD V57
m(h) = 12 TeV
alpha_s = 1e-6
m(u) = m(d) = m(s) = m(c) = m(b) = m(e) = m(mu) = 0, m(tau) = 1.777 GeV
"l" = mu, tau
"v" = nu_e, nu_mu, nu_tau
"y" = d, s, b
"x" = u, c
All subsamples in the following table need to be scaled to the same luminosity and then added
CLIC_ILD, 500 GeV, 0.3 γγ -> had. / BX

Type	ProdID	Events planned	Events produced	σ [fb]
ee -> yyveev	6299	10000	11500	6.90
ee -> yyveyx	6332	40000	77500	40.0
ee -> yyxyev	6341	40000	84000	40.0
ee -> yyuyyc	6350	60000	67000	56.5
ee -> yycyyu	6359	60000	76500	56.5
ee -> dduyyu	6368	60000	98500	50.9
ee -> ssussu	6377	10000	12000	0.0098
ee -> ssubbu	6386	10000	12000	0.16
ee -> bbubbu	6395	10000	10000	0.0084
ee -> ddcyyc	6404	10000	17500	0.72
ee -> sscssc	6413	10000	13500	0.48
ee -> sscbbc	6422	50000	68500	49.5
ee -> bbcbbc	6431	10000	11500	0.0086
ee -> yyvelv	6440	20000	35500	13.5
ee -> yyvlev	6449	20000	28000	13.5
ee -> yyvllv	6458	30000	53000	26.9
ee -> yyvlyx	6467	80000	159000	79.1
ee -> yyxylv	6476	80000	93000	79.1

Signal sample (6-fermion production compatible with ttbar) at 1.4 TeV assuming P(e-) = -80%

WHIZARD V57
m(h) = 12 TeV
alpha_s = 1e-6
m(u) = m(d) = m(s) = m(c) = m(b) = m(e) = m(mu) = 0, m(tau) = 1.777 GeV
"l" = mu, tau
"v" = nu_e, nu_mu, nu_tau
"y" = d, s, b
"x" = u, c
All subsamples in the following table need to be scaled to the same luminosity and then added
CLIC_ILD, 1.4 TeV luminosity spectrum, 1.3 γγ -> had. / BX

Type	ProdID	Events planned	Events produced	σ [fb]	Comments
ee -> yyveev	6586	15000	15600	7.91
ee -> yyveyx	6589	500000	791000	31.9	extended
ee -> yyxyev	6592	500000	802600	29.0	extended
ee -> yyuyyc	6595	50000	50400	29.7
ee -> yycyyu	6598	50000	52200	29.7
ee -> dduyyu	6601	50000	76600	30.0
ee -> ssussu	6604	10000	11600	0.018
ee -> ssubbu	6610	10000	11400	0.096
ee -> bbubbu	6607	10000	12800	0.013
ee -> ddcyyc	6613	10000	14400	1.82
ee -> sscssc	6616	10000	11800	1.52
ee -> sscbbc	6619	40000	58400	23.5
ee -> bbcbbc	6622	10000	12000	0.013
ee -> yyvelv	6625	20000	23800	10.8
ee -> yyvlev	6628	20000	23600	9.82
ee -> yyvllv	6631	30000	36400	15.6
ee -> yyvlyx	6634	700000	1141400	40.7	extended
ee -> yyxylv	6637	700000	1131400	40.7	extended

Signal sample (6-fermion production compatible with ttbar) at 1.4 TeV assuming P(e-) = +80%

WHIZARD V57
m(h) = 12 TeV
alpha_s = 1e-6
m(u) = m(d) = m(s) = m(c) = m(b) = m(e) = m(mu) = 0, m(tau) = 1.777 GeV
"l" = mu, tau
"v" = nu_e, nu_mu, nu_tau
"y" = d, s, b
"x" = u, c
All subsamples in the following table need to be scaled to the same luminosity and then added
CLIC_ILD, 1.4 TeV luminosity spectrum, 1.3 γγ -> had. / BX

Type	ProdID	Events planned	Events produced	σ [fb]
ee -> yyveev	6643	10000	11200	2.47
ee -> yyveyx	6646	15000	26400	9.27
ee -> yyxyev	6697	20000	48600	12.2
ee -> yyuyyc	6652	20000	36000	11.8
ee -> yycyyu	6655	20000	37800	11.8
ee -> dduyyu	6658	20000	21000	10.6
ee -> ssussu	6661	10000	11400	0.0051
ee -> ssubbu	6664	10000	11800	0.039
ee -> bbubbu	6667	10000	11400	0.0046
ee -> ddcyyc	6670	10000	15800	0.25
ee -> sscssc	6673	10000	11800	0.18
ee -> sscbbc	6676	20000	39400	10.2
ee -> bbcbbc	6679	10000	11600	0.0046
ee -> yyvelv	6682	10000	12000	3.13
ee -> yyvlev	6685	10000	12000	4.13
ee -> yyvllv	6688	10000	10400	5.61
ee -> yyvlyx	6691	25000	42200	16.0
ee -> yyxylv	6694	25000	43400	16.0

WHIZARD background samples at 1.4 TeV assuming polarised beams

WHIZARD V57
m(u) = m(d) = m(s) = m(c) = m(b) = m(e) = m(mu) = 0, m(tau) = 1.777 GeV
CLIC_ILD, 1.4 TeV luminosity spectrum, 1.3 γγ -> had. / BX

Type	ProdID	Events planned	Events produced	σ [fb]	Comments
ee -> qqlv	7477	3000000	3520600	6975	P(e-) = -80%; m(H) = 12 TeV; q=u,d,s,c,b; l=e,mu,tau; v=nu_e,nu_mu,nu_tau
ee -> qqlv	7480	1000000	1160000	1644	P(e-) = +80%; m(H) = 12 TeV; q=u,d,s,c,b; l=e,mu,tau; v=nu_e,nu_mu,nu_tau
ee -> qqll	8244	1000000	1193000	2681	P(e-) = -80%; m(H) = 12 TeV; q=u,d,s,c,b; l=e,mu,tau
ee -> qqll	8241	1000000	1192000	2529	P(e-) = +80%; m(H) = 12 TeV; q=u,d,s,c,b; l=e,mu,tau
ee -> qqqq	8254	1500000	1591800	2304	P(e-) = -80%; m(H) = 12 TeV; q=u,d,s,c,b
ee -> qqqq	8257	500000	595000	347	P(e-) = +80%; m(H) = 12 TeV; q=u,d,s,c,b
ee -> qqvv	8271	1000000	1118600	1395	P(e-) = -80%; m(H) = 12 TeV; q=u,d,s,c,b; v=nu_e,nu_mu,nu_tau
ee -> qqvv	8274	200000	283800	180	P(e-) = +80%; m(H) = 12 TeV; q=u,d,s,c,b; v=nu_e,nu_mu,nu_tau
ee -> qq	8283	2000000	2393200	4843	P(e-) = -80%; m(H) = 12 TeV; q=u,d,s,c,b
ee -> qq	8286	1500000	1597600	3169	P(e-) = +80%; m(H) = 12 TeV; q=u,d,s,c,b

Signal sample (6-fermion production compatible with ttbar) at 3 TeV assuming P(e-) = -80%

WHIZARD V57
m(h) = 12 TeV
alpha_s = 1e-6
m(u) = m(d) = m(s) = m(c) = m(b) = m(e) = m(mu) = 0, m(tau) = 1.777 GeV
"l" = mu, tau
"v" = nu_e, nu_mu, nu_tau
"y" = d, s, b
"x" = u, c
All subsamples in the following table need to be scaled to the same luminosity and then added
CLIC_ILD, 3 TeV luminosity spectrum, 3.2 γγ -> had. / BX

Type	ProdID	Events planned	Events produced	σ [fb]
ee -> yyveev	7278	40000	46400	16.8
ee -> yyveyx	7281	100000	159100	47.8
ee -> yyxyev	7284	80000	118500	39.1
ee -> yyuyyc	7287	30000	34500	14.1
ee -> yycyyu	7290	30000	35300	14.1
ee -> dduyyu	7293	30000	37000	12.9
ee -> ssussu	7296	10000	11900	0.013
ee -> ssubbu	7299	10000	17700	0.049
ee -> bbubbu	7302	10000	18400	0.0092
ee -> ddcyyc	7305	10000	16000	1.38
ee -> sscssc	7308	10000	18800	1.17
ee -> sscbbc	7311	30000	56000	10.3
ee -> bbcbbc	7314	10000	18700	0.0093
ee -> yyvelv	7320(!)	40000	113500	16.3
ee -> yyvlev	7317(!)	30000	57100	13.3
ee -> yyvllv	7323	30000	55000	13.3
ee -> yyvlyx	7326	40000	87900	19.2
ee -> yyxylv	7329	40000	176400	19.2

Signal sample (6-fermion production compatible with ttbar) at 3 TeV assuming P(e-) = +80%

WHIZARD V57
m(h) = 12 TeV
alpha_s = 1e-6
m(u) = m(d) = m(s) = m(c) = m(b) = m(e) = m(mu) = 0, m(tau) = 1.777 GeV
"l" = mu, tau
"v" = nu_e, nu_mu, nu_tau
"y" = d, s, b
"x" = u, c
All subsamples in the following table need to be scaled to the same luminosity and then added
CLIC_ILD, 3 TeV luminosity spectrum, 3.2 γγ -> had. / BX

Type	ProdID	Events planned	Events produced	σ [fb]
ee -> yyveev	7422	10000	11800	3.96
ee -> yyveyx	7425	20000	23400	7.44
ee -> yyxyev	7428	40000	49700	16.0
ee -> yyuyyc	7431	10000	12300	4.71
ee -> yycyyu	7434	10000	12600	4.71
ee -> dduyyu	7437	10000	14900	4.27
ee -> ssussu	7440	10000	11800	0.0034
ee -> ssubbu	7443	10000	11900	0.018
ee -> bbubbu	7446	10000	11700	0.0030
ee -> ddcyyc	7449	10000	18500	0.178
ee -> sscssc	7452	10000	11800	0.138
ee -> sscbbc	7473(!)	10000	11800	3.94
ee -> bbcbbc	7455	10000	11700	0.0030
ee -> yyvelv	7458	10000	11700	2.52
ee -> yyvlev	7461	20000	29400	5.47
ee -> yyvllv	7464	10000	18500	2.93
ee -> yyvlyx	7467	20000	28200	6.39
ee -> yyxylv	7470	20000	71000	6.39

WHIZARD background samples at 3 TeV assuming polarised beams

WHIZARD V57
m(u) = m(d) = m(s) = m(c) = m(b) = m(e) = m(mu) = 0, m(tau) = 1.777 GeV
CLIC_ILD, 3 TeV luminosity spectrum, 3.2 γγ -> had. / BX

Type	ProdID	Events planned	Events produced	σ [fb]	Comments
ee -> qqlv	8590	4000000	4163400	8809.0	P(e-) = -80%; m(H) = 12 TeV; q=u,d,s,c,b; l=e,mu,tau; v=nu_e,nu_mu,nu_tau
ee -> qqlv	8593	1500000	1786400	2312.5	P(e-) = +80%; m(H) = 12 TeV; q=u,d,s,c,b; l=e,mu,tau; v=nu_e,nu_mu,nu_tau
ee -> qqll	8608	2000000	2383200	3230.2	P(e-) = -80%; m(H) = 12 TeV; q=u,d,s,c,b; l=e,mu,tau
ee -> qqll	8611	2000000	2384200	3057.1	P(e-) = +80%; m(H) = 12 TeV; q=u,d,s,c,b; l=e,mu,tau
ee -> qqqq	8658	1000000	1093650	963.3	P(e-) = -80%; m(H) = 12 TeV; alpha_s = 1e-6; q=u,d,s,c,b
ee -> qqqq	8661	250000	296500	129.7	P(e-) = +80%; m(H) = 12 TeV; alpha_s = 1e-6; q=u,d,s,c,b
ee -> qqvv	8728	1500000	1588800	2361.5	P(e-) = -80%; m(H) = 12 TeV; q=u,d,s,c,b; v=nu_e,nu_mu,nu_tau
ee -> qqvv	8731	500000	599100	273.5	P(e-) = +80%; m(H) = 12 TeV; q=u,d,s,c,b; v=nu_e,nu_mu,nu_tau
ee -> qq	8740	2000000	2198600	3508.5	P(e-) = -80%; m(H) = 12 TeV; q=u,d,s,c,b
ee -> qq	8743	1500000	1599100	2390.7	P(e-) = +80%; m(H) = 12 TeV; q=u,d,s,c,b

Signal sample (6-fermion production compatible with ttbar) at 365 GeV assuming unpolarised beams

WHIZARD V57
m(h) = 12 TeV
alpha_s = 1e-6
m(u) = m(d) = m(s) = m(c) = m(b) = m(e) = m(mu) = 0, m(tau) = 1.777 GeV
"l" = mu, tau
"v" = nu_e, nu_mu, nu_tau
"y" = d, s, b
"x" = u, c
All subsamples in the following table need to be scaled to the same luminosity and then added
CLIC_ILD, no Beamstrahlung, no γγ -> had. background

Type	ProdID	Events planned	Events produced	σ [fb]
ee -> yyveev	5254	11000	14700	4.2
ee -> yyveyx	5251	65000	66800	24.2
ee -> yyxyev	5248	65000	65500	24.2
ee -> yyvelv	5242	22000	24200	8.2
ee -> yyvlev	5239	22000	24500	8.2
ee -> yyvllv	5245	43000	46300	16.5
ee -> yyvlyx	5233	130000	140800	48.2
ee -> yyxylv	5352	130000	140100	48.2
ee -> yyuyyc	5426	90000	105700	33.9
ee -> yycyyu	5429	90000	103400	33.9
ee -> dduyyu	5432	80000	119000	30.5
ee -> ssussu	5435	10000	17600	0.0059
ee -> ssubbu	5438	10000	23600	0.10
ee -> bbubbu	5441	10000	23300	0.0053
ee -> ddcyyc	5444	10000	9500	0.33
ee -> sscssc	5447	10000	23500	0.19
ee -> sscbbc	5450	80000	192400	29.9
ee -> bbcbbc	5453	10000	21000	0.0054

WHIZARD background samples at 365 GeV assuming unpolarised beams

WHIZARD V57
m(u) = m(d) = m(s) = m(c) = m(b) = m(e) = m(mu) = 0, m(tau) = 1.777 GeV
CLIC_ILD, no Beamstrahlung, no γγ -> had. background

Type	ProdID	Events planned	Events produced	σ [fb]	Comments
ee -> qqqq	5628	2000000	2263600	5227.8	m(H) = 12 TeV; alpha_s = 1e-6; q=u,d,s,c,b
ee -> qqlv	5679	2000000	1904100	5690.1	m(H) = 12 TeV; q=u,d,s,c,b; l=e,mu,tau; v=nu_e,nu_mu,nu_tau
ee -> qqll	5682	1000000	991300	1692.5	m(H) = 12 TeV; q=u,d,s,c,b; l=e,mu,tau
ee -> qqvv	5691	500000	476300	323.4	m(H) = 12 TeV; q=u,d,s,c,b; v=nu_e,nu_mu,nu_tau
ee -> qqH	5697	500000	497600	84.9	m(H) = 125 GeV; q=u,d,s,c,b
ee -> eeH	5700	100000	97900	4.2	m(H) = 125 GeV
ee -> mumuH	5703	100000	97800	4.2	m(H) = 125 GeV
ee -> tautauH	5706	100000	99000	4.2	m(H) = 125 GeV

Samples to train the flavour tagging at 365 GeV

Type	ProdID	Detector	Events planned	Events produced
ee -> bbbbbb	5735	CLIC_ILD	150000	195400
ee -> cccccc	5738	CLIC_ILD	150000	197200
ee -> ssssss	5741	CLIC_ILD	150000	195300
ee -> dddddd	5744	CLIC_ILD	150000	198200
ee -> uuuuuu	5747	CLIC_ILD	150000	198800

PYTHIA sample at 365 GeV assuming unpolarised beams

CLIC_ILD, no Beamstrahlung, no γγ -> had. background

Type	ProdID	Events planned	Events produced	σ [fb]	Comments
ee -> tt	5485	100000	99700	385

WHIZARD samples at 1.4 TeV

Type	ProdID	Events planned	Events produced	σ [fb]	Comments
ee -> tt	5221	25000	24950	143.7	unpolarised beams
ee -> tt	5224	25000	25000	99.7	P(e) = +80%
ee -> tt	5227	25000	24950	187.7	P(e) = -80%
ee -> tt	5559	250000	237400	143.7	unpolarised beams
ee -> tt	5562	250000	243100	99.7	P(e) = +80%
ee -> tt	5565	250000	239900	187.7	P(e) = -80%

WHIZARD samples at 3 TeV

Type	ProdID	Events planned	Events produced	σ [fb]	Comments
ee -> tt	5536	25000	24950	52.6	unpolarised beams
ee -> tt	5539	25000	24950	68.6	P(e) = -80%
ee -> tt	5542	25000	24950	36.5	P(e) = +80%

Topic revision: r128 - 2017-11-28 - PhilippRoloff

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