CMS-TOP-15-015

CMS-TOP-15-015 ; CERN-EP-2017-018
Measurement of the jet mass in highly boosted $\mathrm{ t \bar{t} }$ events from pp collisions at $\sqrt{s}=$ 8 TeV
CMS Collaboration
18 March 2017
Eur. Phys. J. C 77 (2017) 467
Abstract: The first measurement of the jet mass $m_{\text{jet}}$ of top quark jets produced in $\mathrm{ t \bar{t} }$ events from pp collisions at $\sqrt{s}=$ 8 TeV is reported for the jet with the largest transverse momentum $p_{\mathrm{T}}$ in highly boosted hadronic top quark decays. The data sample, collected with the CMS detector, corresponds to an integrated luminosity of 19.7 fb$^{-1}$. The measurement is performed in the lepton+jets channel in which the products of the semileptonic decay $\mathrm{ t } \to \mathrm{ b }\mathrm{ W }$ with $\mathrm{ W }\to\ell \nu$ where $\ell$ is an electron or muon, are used to select $\mathrm{ t \bar{t} }$ events with large Lorentz boosts. The products of the fully hadronic decay $\mathrm{ t } \to \mathrm{ b }\mathrm{ W }$ with $\mathrm{ W }\to\mathrm{ q }\mathrm{ \bar{q} }'$ are reconstructed using a single Cambridge-Aachen jet with distance parameter $R=$ 1.2, and $p_{\mathrm{T}} >$ 400 GeV. The $\mathrm{ t \bar{t} }$ cross section as a function of $m_{\text{jet}}$ is unfolded at the particle level and is used to test the modelling of highly boosted top quark production. The peak position of the $m_{\text{jet}}$ distribution is sensitive to the top quark mass $m_{\mathrm{ t }}$, and the data are used to extract a value of $m_{\mathrm{ t }}$ to assess this sensitivity.
Links: e-print arXiv:1703.06330 [hep-ex] (PDF) ; CDS record ; inSPIRE record ; CADI line (restricted) ;

Figures & Tables	Summary	References	CMS Publications

Figures
png pdf	Figure 1: Simulated mass distributions of the leading jet in ${\mathrm{ t }\mathrm{ \bar{t} } }$ events for the $\ell $+jets channel at the particle level. The events are generated with POWHEG+PYTHIA, and normalised to the integrated luminosity of the data. The distribution for the total number of selected events (dark solid line) is compared to events where the leading jet originates from the fully hadronic top quark decay (light solid line, "fully merged''), and to events where the leading jet does not include all the remnants (dotted line, "not merged'') from the fully hadronic top quark decay.
png pdf	Figure 2: Distributions of $ {p_{\mathrm {T}}} $ (left ) and $\eta $ (right ) of the leading jet from data (points) and simulation (filled histograms). The vertical bars on the points show the statistical uncertainty and the horizontal bars show the bin widths. The electron and muon channels are shown combined. The ${\mathrm{ t }\mathrm{ \bar{t} } } $ sample is scaled such that the number of simulated events matches the number of selected events observed in data. The hatched region shows the total uncertainty in the simulation, including the statistical and experimental systematic uncertainties. The panels below show the ratio of the data to the simulation. The uncertainty bands include the statistical and experimental systematic uncertainties, where the statistical (light grey) and total (dark grey) uncertainties are shown separately in the ratio.
png pdf	Figure 2-a: Distributions of $ {p_{\mathrm {T}}} $ of the leading jet from data (points) and simulation (filled histograms). The vertical bars on the points show the statistical uncertainty and the horizontal bars show the bin widths. The electron and muon channels are shown combined. The ${\mathrm{ t }\mathrm{ \bar{t} } } $ sample is scaled such that the number of simulated events matches the number of selected events observed in data. The hatched region shows the total uncertainty in the simulation, including the statistical and experimental systematic uncertainties. The panel below shows the ratio of the data to the simulation. The uncertainty bands include the statistical and experimental systematic uncertainties, where the statistical (light grey) and total (dark grey) uncertainties are shown separately in the ratio.
png pdf	Figure 2-b: Distributions of $\eta $ of the leading jet from data (points) and simulation (filled histograms). The vertical bars on the points show the statistical uncertainty and the horizontal bars show the bin widths. The electron and muon channels are shown combined. The ${\mathrm{ t }\mathrm{ \bar{t} } } $ sample is scaled such that the number of simulated events matches the number of selected events observed in data. The hatched region shows the total uncertainty in the simulation, including the statistical and experimental systematic uncertainties. The panel below shows the ratio of the data to the simulation. The uncertainty bands include the statistical and experimental systematic uncertainties, where the statistical (light grey) and total (dark grey) uncertainties are shown separately in the ratio.
png pdf	Figure 3: Distributions of the leading-jet invariant mass from data (points) and simulation (filled histograms). The vertical bars on the points show the statistical uncertainty and the horizontal bars show the bin widths for the combined electron and muon channels. The distributions for $ {p_{\mathrm {T}}} $ bins of 400 $ < {p_{\mathrm {T}}} < $ 500 GeV (left ) and $ {p_{\mathrm {T}}} > $ 500 GeV (right ) are given. The ${\mathrm{ t }\mathrm{ \bar{t} } } $ simulation is scaled such that the number of simulated events matches the number of selected events observed in data. The hatched region shows the total uncertainty in the simulation, including the statistical and experimental systematic uncertainties. The panels below show the ratio of the data to the simulation. The uncertainty bands include the statistical and experimental systematic uncertainties, where the statistical (light grey) and total (dark grey) uncertainties are shown separately in the ratio.
png pdf	Figure 3-a: Distributions of the leading-jet invariant mass from data (points) and simulation (filled histograms). The vertical bars on the points show the statistical uncertainty and the horizontal bars show the bin widths for the combined electron and muon channels. The distribution for ${p_{\mathrm {T}}} $ bins of 400 $ < {p_{\mathrm {T}}} < $ 500 GeV is given. The ${\mathrm{ t }\mathrm{ \bar{t} } } $ simulation is scaled such that the number of simulated events matches the number of selected events observed in data. The hatched region shows the total uncertainty in the simulation, including the statistical and experimental systematic uncertainties. The panel below shows the ratio of the data to the simulation. The uncertainty bands include the statistical and experimental systematic uncertainties, where the statistical (light grey) and total (dark grey) uncertainties are shown separately in the ratio.
png pdf	Figure 3-b: Distributions of the leading-jet invariant mass from data (points) and simulation (filled histograms). The vertical bars on the points show the statistical uncertainty and the horizontal bars show the bin widths for the combined electron and muon channels. The distribution for $ {p_{\mathrm {T}}} $ bins of $ {p_{\mathrm {T}}} > $ 500 GeV is given. The ${\mathrm{ t }\mathrm{ \bar{t} } } $ simulation is scaled such that the number of simulated events matches the number of selected events observed in data. The hatched region shows the total uncertainty in the simulation, including the statistical and experimental systematic uncertainties. The panel below shows the ratio of the data to the simulation. The uncertainty bands include the statistical and experimental systematic uncertainties, where the statistical (light grey) and total (dark grey) uncertainties are shown separately in the ratio.
png pdf	Figure 4: Statistical uncertainties compared to the individual experimental systematic uncertainties (left ), and statistical uncertainties compared to the systematic uncertainties originating from the modelling of ${\mathrm{ t }\mathrm{ \bar{t} } }$ production (right ), as a function of the leading-jet mass. The total uncertainties are indicated by the grey cross-hatched regions. The statistical and total uncertainties in the last bin are around 300% and exceed the vertical scale. The size of the horizontal bars represents the bin widths.
png pdf	Figure 4-a: Statistical uncertainties compared to the individual experimental systematic uncertainties, as a function of the leading-jet mass. The total uncertainties are indicated by the grey cross-hatched regions. The statistical and total uncertainties in the last bin are around 300% and exceed the vertical scale. The size of the horizontal bars represents the bin widths.
png pdf	Figure 4-b: Statistical uncertainties compared to the systematic uncertainties originating from the modelling of ${\mathrm{ t }\mathrm{ \bar{t} } }$ production, as a function of the leading-jet mass. The total uncertainties are indicated by the grey cross-hatched regions. The statistical and total uncertainties in the last bin are around 300% and exceed the vertical scale. The size of the horizontal bars represents the bin widths.
png pdf	Figure 5: Fiducial-region particle-level differential ${\mathrm{ t }\mathrm{ \bar{t} } }$ cross sections as a function of the leading-jet mass. The cross sections from the combined electron and muon channels (points) are compared to predictions from the MadGraph+PYTHIA, POWHEG+PYTHIA, and MC@NLO+HERWIG generators (lines). The vertical bars represent the statistical (inner) and the total (outer) uncertainties. The horizontal bars show the bin widths.
png pdf	Figure 6: The normalised particle-level ${\mathrm{ t }\mathrm{ \bar{t} } }$ differential cross section in the fiducial region as a function of the leading-jet mass. The measurement is compared to predictions from MadGraph+PYTHIA for three values of ${m_{\mathrm{ t } }} $. The vertical bars represent the statistical (inner) and the total (outer) uncertainties. The horizontal bars show the bin widths.

Tables
png pdf	Table 1: Summary of the selection criteria used to define the fiducial region of the measurement.
png pdf	Table 2: Measured particle-level ${\mathrm{ t }\mathrm{ \bar{t} } }$ differential cross sections in the fiducial region as a function of ${m_{\text {jet}}} $, with the individual and total uncertainties in percent.
png pdf	Table 3: Values of the particle-level ${\mathrm{ t }\mathrm{ \bar{t} } }$ differential cross section in the fiducial region, normalized to unity, as a function of the leading-jet mass. The individual and total uncertainties are given in percent.
png pdf	Table 4: Covariance matrix for the statistical uncertainties in the differential cross section. All entries are given in units of [fb$^2$].
png pdf	Table 5: Covariance matrix for the total uncertainties in the differential cross section, including all systematic and modelling uncertainties. All entries are given in units of [fb$^2$].
png pdf	Table 6: Covariance matrix for the statistical uncertainties in the normalised differential cross section. All entries are given in units of [10$^{-4}$].
png pdf	Table 7: Covariance matrix for the total uncertainties in the normalised differential cross section, including all systematic and modelling uncertainties. All entries are given in units of [10$^{-4}$].

Summary

The first measurement of the differential $\mathrm{ t \bar{t} }$ cross section has been performed in the $\ell$+jets channel as a function of the leading-jet mass ${m_{\text{jet}}} $ in the highly boosted top quark regime. The measurement is carried out in a fiducial region with fully merged top quark decays in hadronic final states, corrected to the particle level. The normalised differential cross section as a function of ${m_{\text{jet}}} $ agrees with predictions from simulations, indicating the good quality of modelling the jet mass in highly boosted top quark decays. The total fiducial-region cross section for ${m_{\text{jet}}} $ between 140 and 350 GeV is measured to be 101 $\pm$ 19 fb, which is below the predicted value. This difference is consistent with earlier measurements of a softer top quark $p_{\mathrm{T}}$ spectrum observed in data than in simulation [10,11].

The peak position in the ${m_{\text{jet}}} $ distribution is sensitive to the top quark mass ${m_{\mathrm{ t }}} $. This can be used for an independent determination of ${m_{\mathrm{ t }}} $ in the boosted regime, with the prospect of reaching a more reliable correspondence between the top quark mass in any well-defined renormalisation scheme and the top quark mass parameter in general-purpose event generators.

The normalised particle-level $\mathrm{ t \bar{t} }$ differential cross section measurement as a function of ${m_{\text{jet}}} $ is used to extract a value of ${m_{\mathrm{ t }}} $ in order to estimate the current sensitivity of the data. The value obtained, ${m_{\mathrm{ t }}} =$ 170.8 $\pm$ 9.0 GeV, is consistent with the current LHC and Tevatron average of 173.34 $\pm$ 0.27 (stat) $\pm$ 0.71 (syst) GeV [111], albeit with a much larger uncertainty.

New data at higher centre-of-mass energies and with larger integrated luminosities will lead to an improvement in the statistical uncertainty. More data can also lead to reductions in the experimental systematic uncertainties, most notably that from the jet mass scale, which is expected to improve with smaller jet distance parameters. In addition, improvements in the modelling uncertainty are expected because of stronger constraints on the simulation in the highly boosted regime. A reduction in the theoretical uncertainty is also foreseen with the emergence of higher-order calculations. The results obtained in this analysis show the feasibility of the method to obtain the top quark mass in the highly boosted regime. This can provide an important ingredient for studies of the relation between the value of the top quark mass obtained from MC event generators and the one obtained from first-principle calculations.

References
1	D0 Collaboration	Dependence of the $ \mathrm{t}\bar{\mathrm{t}} $ production cross section on the transverse momentum of the top quark	PLB 693 (2010) 515	1001.1900
2	CMS Collaboration	Measurement of differential top-quark-pair production cross sections in pp colisions at $ \sqrt{s}= $ 7 TeV	EPJC 73 (2013) 2339	CMS-TOP-11-013 1211.2220
3	CDF Collaboration	Measurement of the differential cross section $ d{\sigma}/d(\cos{\theta}_t) $ for top-quark pair production in $ \mathrm{p}\overline{\mathrm{p}} $ collisions at $ \sqrt{s}= $ 1.96 TeV	PRL 111 (2013) 182002	1306.2357
4	D0 Collaboration	Measurement of differential $ \mathrm{t}\bar{\mathrm{t}} $ production cross sections in $ \mathrm{p}\overline{\mathrm{p}} $ collisions	PRD 90 (2014) 092006	1401.5785
5	ATLAS Collaboration	Measurements of normalized differential cross sections for $ \mathrm{t}\bar{\mathrm{t}} $ production in pp collisions at $ \sqrt{s}= $ 7 TeV using the ATLAS detector	PRD 90 (2014) 072004	1407.0371
6	ATLAS Collaboration	Differential top-antitop cross-section measurements as a function of observables constructed from final-state particles using pp collisions at $ \sqrt{s}= $ 7 TeV in the ATLAS detector	JHEP 06 (2015) 100	1502.05923
7	CMS Collaboration	Measurement of the differential cross section for top quark pair production in pp collisions at $ \sqrt{s}= $ 8 TeV	EPJC 75 (2015) 542	CMS-TOP-12-028 1505.04480
8	CMS Collaboration	Measurement of the $ \mathrm{t}\overline{{\mathrm{t}}} $ production cross section in the all-jets final state in pp collisions at $ \sqrt{s}= $ 8 TeV	EPJC 76 (2016) 128	CMS-TOP-14-018 1509.06076
9	ATLAS Collaboration	Measurement of top quark pair differential cross-sections in the dilepton channel in pp collisions at $ \sqrt{s} $ = 7 and 8 TeV with ATLAS	PRD 94 (2016), no. 9, 092003	1607.07281
10	ATLAS Collaboration	Measurement of the differential cross-section of highly boosted top quarks as a function of their transverse momentum in $ \sqrt{s}= $ 8 TeV proton-proton collisions using the ATLAS detector	PRD 93 (2016) 032009	1510.03818
11	CMS Collaboration	Measurement of the integrated and differential $ \mathrm{ t \bar{t} } $ production cross sections for high-$ p_\mathrm{T} $ top quarks in pp collisions at $ \sqrt{s}= $ 8 TeV	PRD 94 (2016) 072002	CMS-TOP-14-012 1605.00116
12	CMS Collaboration	Search for anomalous $ \mathrm{ t \bar{t} } $ production in the highly-boosted all-hadronic final state	JHEP 09 (2012) 029	CMS-EXO-11-006 1204.2488
13	ATLAS Collaboration	A search for $ \mathrm{ t \bar{t} } $ resonances in lepton+jets events with highly boosted top quarks collected in pp collisions at $ \sqrt{s}= $ 7 TeV with the ATLAS detector	JHEP 09 (2012) 041	1207.2409
14	ATLAS Collaboration	Search for resonances decaying into top-quark pairs using fully hadronic decays in pp collisions with ATLAS at $ \sqrt{s}= $ 7 TeV	JHEP 01 (2013) 116	1211.2202
15	ATLAS Collaboration	Search for $ \mathrm{ t \bar{t} } $ resonances in the lepton plus jets final state with ATLAS using 4.7 fb$ ^{-1} $ of $ pp $ collisions at $ \sqrt{s}= $ 7 TeV	PRD 88 (2013) 012004	1305.2756
16	CMS Collaboration	Searches for New Physics Using the $ t\overline{t} $ Invariant Mass Distribution in $ pp $ Collisions at $ \sqrt{s}= $ 8 TeV	PRL 111 (2013) 211804	CMS-B2G-13-001 1309.2030
17	ATLAS Collaboration	Search for $ {W}' \rightarrow {tb} \rightarrow {qqbb} $ decays in $ pp $ collisions at $ \sqrt{s}= $ 8 TeV with the ATLAS detector	EPJC 75 (2015) 165	1408.0886
18	CMS Collaboration	Search for vector-like T quarks decaying to top quarks and Higgs bosons in the all-hadronic channel using jet substructure	JHEP 06 (2015) 080	CMS-B2G-14-002 1503.01952
19	ATLAS Collaboration	A search for $ t\overline{t} $ resonances using lepton-plus-jets events in proton-proton collisions at $ \sqrt{s}= $ 8 TeV with the ATLAS detector	JHEP 08 (2015) 148	1505.07018
20	CMS Collaboration	Search for resonant $ t\bar{t} $ production in proton-proton collisions at $ \sqrt{s}= $ 8 TeV	PRD 93 (2016) 012001	CMS-B2G-13-008 1506.03062
21	CMS Collaboration	Search for the production of an excited bottom quark decaying to tW in proton-proton collisions at $ \sqrt{s}= $ 8 TeV	JHEP 01 (2016) 166	CMS-B2G-14-005 1509.08141
22	ATLAS Collaboration	Search for the production of single vector-like and excited quarks in the $ Wt $ final state in $ pp $ collisions at $ \sqrt{s}= $ 8 TeV with the ATLAS detector	JHEP 02 (2016) 110	1510.02664
23	ATLAS Collaboration	Jet mass and substructure of inclusive jets in $ \sqrt{s}= $ 7 TeV $ pp $ collisions with the ATLAS experiment	JHEP 05 (2012) 128	1203.4606
24	CMS Collaboration	Studies of jet mass in dijet and W/Z + jet events	JHEP 05 (2013) 090	CMS-SMP-12-019 1303.4811
25	A. H. Hoang and I. W. Stewart	Top mass measurements from jets and the Tevatron top-quark mass	NPPS 185 (2008) 220	0808.0222
26	CDF and D0 Collaborations	Combination of the top-quark mass measurements from the Tevatron collider	PRD 86 (2012) 092003	1207.1069
27	ATLAS Collaboration	Measurement of the top quark mass in the $ t\bar{t}\rightarrow \text{ lepton+jets } $ and $ t\bar{t}\rightarrow \text{ dilepton } $ channels using $ \sqrt{s}= $ 7 TeV ATLAS data	EPJC 75 (2015) 330	1503.05427
28	ATLAS Collaboration	Determination of the top-quark pole mass using $ \mathrm{ t \bar{t} } $+1-jet events collected with the ATLAS experiment in 7 TeV pp collisions	JHEP 10 (2015) 121	1507.01769
29	CMS Collaboration	Measurement of the top quark mass using proton-proton data at $ {\sqrt{s}} = $ 7 and 8 TeV	PRD 93 (2016) 072004	CMS-TOP-14-022 1509.04044
30	CMS Collaboration	Measurement of the top quark mass using charged particles in $ pp $ collisions at $ \sqrt{s}= $ 8 TeV	PRD 93 (2016) 092006	CMS-TOP-12-030 1603.06536
31	ATLAS Collaboration	Measurement of the top quark mass in the $ t\bar{t}\to \text{dilepton} $ channel from $ \sqrt{s}= $ 8 TeV ATLAS data	PLB 761 (2016) 350	1606.02179
32	C. W. Bauer, S. Fleming, and M. E. Luke	Summing Sudakov logarithms in $ B \to X_s + \gamma $ in effective field theory	PRD 63 (2000) 014006	hep-ph/0005275
33	C. W. Bauer, S. Fleming, D. Pirjol, and I. W. Stewart	An effective field theory for collinear and soft gluons: Heavy to light decays	PRD 63 (2001) 114020	hep-ph/0011336
34	C. W. Bauer and I. W. Stewart	Invariant operators in collinear effective theory	PLB 516 (2001) 134	hep-ph/0107001
35	C. W. Bauer, D. Pirjol, and I. W. Stewart	Soft-collinear factorization in effective field theory	PRD 65 (2002) 054022	hep-ph/0109045
36	S. Fleming, A. H. Hoang, S. Mantry, and I. W. Stewart	Jets from massive unstable particles: Top-mass determination	PRD 77 (2008) 074010	hep-ph/0703207
37	S. Fleming, A. H. Hoang, S. Mantry, and I. W. Stewart	Top jets in the peak region: Factorization analysis with next-to-leading-log resummation	PRD 77 (2008) 114003	0711.2079
38	A. H. Hoang, A. Pathak, P. Pietrulewicz, and I. W. Stewart	Hard matching for boosted tops at two loops	JHEP 12 (2015) 059	1508.04137
39	M. Butenschoen et al.	Top quark mass calibration for Monte Carlo event generators	PRL 117 (2016) 232001	1608.01318
40	S. Moch et al.	High precision fundamental constants at the TeV scale	in Proceedings of the Mainz Institute for Theoretical Physics (MITP) scientific program on high precision fundamental constants at the TeV scale, March 10-21 2014	1405.4781
41	A. H. Hoang	The top mass: Interpretation and theoretical uncertainties	in 7th International Workshop on Top Quark Physics (TOP2014) Cannes, France 2014	1412.3649
42	G. Corcella	Interpretation of the top-quark mass measurements: A theory overview	in 8th International Workshop on Top Quark Physics (TOP2015) Ischia, Italy 2015	1511.08429
43	Y. L. Dokshitzer, G. D. Leder, S. Moretti, and B. R. Webber	Better jet clustering algorithms	JHEP 08 (1997) 001	hep-ph/9707323
44	M. Wobisch and T. Wengler	Hadronization corrections to jet cross sections in deep-inelastic scattering	in Monte Carlo generators for HERA physics, Hamburg, Germany 1998	hep-ph/9907280
45	CMS Collaboration	The CMS trigger system	JINST 12 (2017) P01020	CMS-TRG-12-001 1609.02366
46	CMS Collaboration	The CMS experiment at the CERN LHC	JINST 3 (2008) S08004	CMS-00-001
47	CMS Collaboration	Particle-flow event reconstruction in CMS and performance for jets, taus, and $ E_{\mathrm{T}}^{\text{miss}} $	CDS
48	CMS Collaboration	Commissioning of the particle-flow event reconstruction with the first LHC collisions recorded in the CMS detector	CDS
49	CMS Collaboration	Description and performance of track and primary-vertex reconstruction with the CMS tracker	JINST 9 (2014) P10009	CMS-TRK-11-001 1405.6569
50	CMS Collaboration	Performance of CMS muon reconstruction in pp collision events at $ \sqrt{s}= $ 7 TeV	JINST 7 (2012) P10002	CMS-MUO-10-004 1206.4071
51	CMS Collaboration	The performance of the CMS muon detector in proton-proton collisions at $ \sqrt{s}= $ 7 TeV at the LHC	JINST 8 (2013) P11002	CMS-MUO-11-001 1306.6905
52	CMS Collaboration	Performance of electron reconstruction and selection with the CMS detector in proton-proton collisions at $ \sqrt{s}= $ 8 TeV	JINST 10 (2015) P06005	CMS-EGM-13-001 1502.02701
53	CMS Collaboration	Energy calibration and resolution of the CMS electromagnetic calorimeter in pp collisions at $ \sqrt{s}= $ 7 TeV	JINST 8 (2013) P09009	CMS-EGM-11-001 1306.2016
54	M. Cacciari, G. P. Salam, and G. Soyez	FastJet user manual	EPJC 72 (2012) 1896	1111.6097
55	M. Cacciari, G. P. Salam, and G. Soyez	The anti-$ k_t $ jet clustering algorithm	JHEP 04 (2008) 063	0802.1189
56	M. Cacciari, G. P. Salam, and G. Soyez	The catchment area of jets	JHEP 04 (2008) 005	0802.1188
57	CMS Collaboration	Determination of jet energy calibration and transverse momentum resolution in CMS	JINST 6 (2011) P11002	CMS-JME-10-011 1107.4277
58	CMS Collaboration	Jet energy scale and resolution in the CMS experiment in pp collisions at 8 TeV	Submitted to JINST	CMS-JME-13-004 1607.03663
59	CMS Collaboration	Identification of b-quark jets with the CMS experiment	JINST 8 (2013) P04013	CMS-BTV-12-001 1211.4462
60	CMS Collaboration	Jet performance in pp collisions at 7 TeV	CDS
61	CMS Collaboration	Missing transverse energy performance of the CMS detector	JINST 6 (2011) P09001	CMS-JME-10-009 1106.5048
62	P. Nason	A new method for combining NLO QCD with shower Monte Carlo algorithms	JHEP 11 (2004) 040	hep-ph/0409146
63	S. Frixione, P. Nason, and C. Oleari	Matching NLO QCD computations with parton shower simulations: The POWHEG method	JHEP 11 (2007) 070	0709.2092
64	S. Alioli, P. Nason, C. Oleari, and E. Re	A general framework for implementing NLO calculations in shower Monte Carlo programs: The POWHEG BOX	JHEP 06 (2010) 043	1002.2581
65	S. Alioli, P. Nason, C. Oleari, and E. Re	NLO single-top production matched with shower in POWHEG: $ s $- and $ t $-channel contributions	JHEP 09 (2009) 111	0907.4076
66	E. Re	Single-top Wt-channel production matched with parton showers using the POWHEG method	EPJC 71 (2011) 1547	1009.2450
67	J. Alwall et al.	The automated computation of tree-level and next-to-leading order differential cross sections, and their matching to parton shower simulations	JHEP 07 (2014) 079	1405.0301
68	P. Artoisenet, R. Frederix, O. Mattelaer, and R. Rietkerk	Automatic spin-entangled decays of heavy resonances in Monte Carlo simulations	JHEP 03 (2013) 015	1212.3460
69	T. Sjostrand, S. Mrenna, and P. Skands	PYTHIA 6.4 physics and manual	JHEP 05 (2006) 026	hep-ph/0603175
70	S. Frixione and B. R. Webber	Matching NLO QCD computations and parton shower simulations	JHEP 06 (2002) 029	hep-ph/0204244
71	M. L. Mangano, M. Moretti, F. Piccinini, and M. Treccani	Matching matrix elements and shower evolution for top-quark production in hadronic collisions	JHEP 01 (2007) 013	hep-ph/0611129
72	P. M. Nadolsky et al.	Implications of CTEQ global analysis for collider observables	PRD 78 (2008) 013004	0802.0007
73	H.-L. Lai et al.	New parton distributions for collider physics	PRD 82 (2010) 074024	1007.2241
74	J. Pumplin et al.	New generation of parton distributions with uncertainties from global QCD analysis	JHEP 07 (2002) 012	hep-ph/0201195
75	CMS Collaboration	Study of the underlying event at forward rapidity in pp collisions at $ \sqrt{s} = $ 0.9, 2.76, and 7 TeV	JHEP 04 (2013) 072	CMS-FWD-11-003 1302.2394
76	CMS Collaboration	Event generator tunes obtained from underlying event and multiparton scattering measurements	EPJC 76 (2016) 155	CMS-GEN-14-001 1512.00815
77	G. Corcella et al.	HERWIG 6: An event generator for hadron emission reactions with interfering gluons (including supersymmetric processes)	JHEP 01 (2001) 010	hep-ph/0011363
78	N. Kidonakis	NNLL threshold resummation for top-pair and single-top production	Phys. Part. Nucl. 45 (2014) 714	1210.7813
79	R. Gavin, Y. Li, F. Petriello, and S. Quackenbush	FEWZ 2.0: A code for hadronic Z production at next-to-next-to-leading order	CPC 182 (2011) 2388	1011.3540
80	R. Gavin, Y. Li, F. Petriello, and S. Quackenbush	W physics at the LHC with FEWZ 2.1	CPC 184 (2013) 208	1201.5896
81	Y. Li and F. Petriello	Combining QCD and electroweak corrections to dilepton production in the framework of the FEWZ simulation code	PRD 86 (2012) 094034	1208.5967
82	J. M. Campbell, R. K. Ellis, and K. Williams	Vector boson pair production at the LHC	JHEP 07 (2011) 018	1105.0020
83	M. Beneke, P. Falgari, S. Klein, and C. Schwinn	Hadronic top-quark pair production with NNLL threshold resummation	Nucl. Phys. B 855 (2012) 695	1109.1536
84	M. Cacciari et al.	Top-pair production at hadron colliders with next-to-next-to-leading logarithmic soft-gluon resummation	PLB 710 (2012) 612	1111.5869
85	P. Barnreuther, M. Czakon, and A. Mitov	Percent-level-precision physics at the Tevatron: Next-to-leading order QCD corrections to $ \mathrm{q} \bar{\mathrm{q}} \to \mathrm{ t \bar{t} }$+X	PRL 109 (2012) 132001	1204.5201
86	M. Czakon and A. Mitov	NNLO corrections to top-pair production at hadron colliders: The all-fermionic scattering channels	JHEP 12 (2012) 054	1207.0236
87	M. Czakon and A. Mitov	NNLO corrections to top pair production at hadron colliders: The quark-gluon reaction	JHEP 01 (2013) 080	1210.6832
88	M. Czakon, P. Fiedler, and A. Mitov	Total top-quark pair-production cross section at hadron colliders through $ \mathcal{O}(\alpha^4_{S}) $	PRL 110 (2013) 252004	1303.6254
89	M. Czakon and A. Mitov	Top++: A program for the calculation of the top-pair cross-section at hadron colliders	CPC 185 (2014) 2930	1112.5675
90	GEANT4 Collaboration	GEANT4 -- a simulation toolkit	NIMA 506 (2003) 250
91	CMS Collaboration	Performance of the CMS missing transverse momentum reconstruction in pp data at $ \sqrt{s}= $ 8 TeV	JINST 10 (2015) P02006	CMS-JME-13-003 1411.0511
92	J. Thaler and K. Van Tilburg	Identifying boosted objects with $ N $-subjettiness	JHEP 03 (2011) 015	1011.2268
93	J. Thaler and K. Van Tilburg	Maximizing boosted top identification by minimizing $ N $-subjettiness	JHEP 02 (2012) 093	1108.2701
94	D. E. Kaplan, K. Rehermann, M. D. Schwartz, and B. Tweedie	Top tagging: A method for identifying boosted hadronically decaying top quarks	PRL 101 (2008) 142001	0806.0848
95	CMS Collaboration	A Cambridge-Aachen (C-A) based jet algorithm for boosted top-jet tagging	CDS
96	T. Plehn, G. P. Salam, and M. Spannowsky	Fat jets for a light Higgs boson	PRL 104 (2010) 111801	0910.5472
97	T. Plehn, M. Spannowsky, M. Takeuchi, and D. Zerwas	Stop reconstruction with tagged tops	JHEP 10 (2010) 078	1006.2833
98	T. Lapsien, R. Kogler, and J. Haller	A new tagger for hadronically decaying heavy particles at the LHC	EPJC 76 (2016) 600	1606.04961
99	Y.-T. Chien, R. Kelley, M. D. Schwartz, and H. X. Zhu	Resummation of jet mass at hadron colliders	PRD 87 (2013) 014010	1208.0010
100	M. Dasgupta and G. P. Salam	Resummation of non-global QCD observables	PLB 512 (2001) 323	hep-ph/0104277
101	S. Schmitt	TUnfold: An algorithm for correcting migration effects in high energy physics	JINST 7 (2012) T10003	1205.6201
102	S. Schmitt	Data unfolding methods in high energy physics	in 12th Conference on Quark Confinement and the Hadron Spectrum (Confinement XII) Thessaloniki, Greece 2016	1611.01927
103	G. Antchev et al.	First measurement of the total proton-proton cross section at the LHC energy of $ \sqrt{s} = $ 7 TeV	Europhys. Lett. 96 (2011) 21002	1110.1395
104	CMS Collaboration	Measurement of the production cross section of the W boson in association with two b jets in pp collisions at $ \sqrt{s}= $ 8 TeV	Submitted to EPJC	CMS-SMP-14-020 1608.07561
105	CMS Collaboration	Observation of the associated production of a single top quark and a W boson in pp collisions at $ \sqrt{s}= $ 8 TeV	PRL 112 (2014) 231802	CMS-TOP-12-040 1401.2942
106	CMS Collaboration	CMS luminosity based on pixel cluster counting - summer 2013 update	CMS-PAS-LUM-13-001	CMS-PAS-LUM-13-001
107	M. Czakon, D. Heymes, and A. Mitov	High-precision differential predictions for top-quark pairs at the LHC	PRL 116 (2016) 082003	1511.00549
108	ATLAS Collaboration	Measurement of the $ \mathrm{ t \bar{t} } $ production cross-section using e$ \mu $ events with b-tagged jets in pp collisions at $ \sqrt{s}= $ 7 and 8 TeV with the ATLAS detector	EPJC 74 (2014) 3109	1406.5375
109	CMS Collaboration	Measurement of the $ \mathrm{t}\overline{{\mathrm{t}}} $ production cross section in the e$ \mu $ channel in proton-proton collisions at $ \sqrt{s} = $ 7 and 8 TeV	JHEP 08 (2016) 029	CMS-TOP-13-004 1603.02303
110	Gfitter Group	The global electroweak fit at NNLO and prospects for the LHC and ILC	EPJC 74 (2014) 3046	1407.3792
111	ATLAS, CDF, CMS and D0 Collaborations	First combination of Tevatron and LHC measurements of the top-quark mass		1403.4427