Compact Muon Solenoid
LHC, CERN

Visit us: CMS Public Website, CMS Physics ; Contact us: CMS Publications Committee

CMS-PAS-B2G-17-013

Search for new heavy resonances decaying into a Z boson and a massive vector boson in the $ 2 \ell 2 \mathrm{q} $ final state at $ \sqrt{s}= $ 13 TeV

CMS Collaboration

December 2017

Abstract: This paper describes a search for new heavy diboson resonances decaying to the $ 2 \ell 2 \mathrm{q} $ final state, with two charged leptons ($\ell=e,\mu$) produced by the decay of a Z boson, and two quarks produced by the hadronic decay of a W or Z boson. The search is performed for resonance masses from 400 to 4500 GeV. Two categories are defined based on the merged or resolved reconstruction of the hadronically decaying vector boson, optimized for high- and low-mass resonances respectively. The search is based on data collected during 2016 by the CMS experiment at the LHC in proton-proton collisions with a center-of-mass energy of $ \sqrt{s}= $ 13 TeV, corresponding to an integrated luminosity of 35.9 fb$^{-1}$. Upper limits on the production cross section of heavy spin-1 and spin-2 resonances are derived as a function of the resonance mass, and exclusion limits of W' and bulk graviton particles are produced in the framework of the heavy vector triplet model and warped extra dimensions, respectively.

Links: CDS record (PDF) ; inSPIRE record ; CADI line (restricted) ; These preliminary results are superseded in this paper, JHEP 09 (2018) 101. The superseded preliminary plots can be found here.

Figures
png pdf	Figure 1: Top row: distribution of the merged V candidate $ {\tau _{21}} $ (left) and jet $ {p_{\mathrm {T}}} $ (right) after applying the $ {\tau _{21}} < $ 0.4 cut in data and simulation for events in the signal region of the low-mass search. Bottom row: V candidate $ {m_\mathrm {j}} $ (left) and $ {m_\mathrm {jj}} $ (right) in data and simulation for events in the signal regions of the low-mass search. Backgrounds are shown separately for the dominant Z+jets contribution (green), the ZV SM diboson contribution (red), and the lepton flavor symmetric backgrounds derived from e$\mu$ data (cyan). The gray band shows the statistical and systematic uncertainties in the background, while the dashed vertical region (Higgs) shows the expected SM Higgs mass range, which is excluded from the analysis. A 600 GeV bulk graviton signal prediction is represented by the black dashed histogram. The background normalization is derived from a fit to the $ {m_{{\mathrm {V}\mathrm {Z}}}} $ observable in the signal and sideband regions.
png pdf	Figure 1-a: Distribution of the merged V candidate $ {\tau _{21}} $ after applying the $ {\tau _{21}} < $ 0.4 cut in data and simulation for events in the signal region of the low-mass search. Backgrounds are shown separately for the dominant Z+jets contribution (green), the ZV SM diboson contribution (red), and the lepton flavor symmetric backgrounds derived from e$\mu$ data (cyan). The gray band shows the statistical and systematic uncertainties in the background, while the dashed vertical region (Higgs) shows the expected SM Higgs mass range, which is excluded from the analysis. A 600 GeV bulk graviton signal prediction is represented by the black dashed histogram. The background normalization is derived from a fit to the $ {m_{{\mathrm {V}\mathrm {Z}}}} $ observable in the signal and sideband regions.
png pdf	Figure 1-b: Distribution of the merged V candidate jet $ {p_{\mathrm {T}}} $ after applying the $ {\tau _{21}} < $ 0.4 cut in data and simulation for events in the signal region of the low-mass search. Backgrounds are shown separately for the dominant Z+jets contribution (green), the ZV SM diboson contribution (red), and the lepton flavor symmetric backgrounds derived from e$\mu$ data (cyan). The gray band shows the statistical and systematic uncertainties in the background, while the dashed vertical region (Higgs) shows the expected SM Higgs mass range, which is excluded from the analysis. A 600 GeV bulk graviton signal prediction is represented by the black dashed histogram. The background normalization is derived from a fit to the $ {m_{{\mathrm {V}\mathrm {Z}}}} $ observable in the signal and sideband regions.
png pdf	Figure 1-c: V candidate $ {m_\mathrm {j}} $ in data and simulation for events in the signal regions of the low-mass search. Backgrounds are shown separately for the dominant Z+jets contribution (green), the ZV SM diboson contribution (red), and the lepton flavor symmetric backgrounds derived from e$\mu$ data (cyan). The gray band shows the statistical and systematic uncertainties in the background, while the dashed vertical region (Higgs) shows the expected SM Higgs mass range, which is excluded from the analysis. A 600 GeV bulk graviton signal prediction is represented by the black dashed histogram. The background normalization is derived from a fit to the $ {m_{{\mathrm {V}\mathrm {Z}}}} $ observable in the signal and sideband regions.
png pdf	Figure 1-d: V candidate $ {m_\mathrm {jj}} $ in data and simulation for events in the signal regions of the low-mass search. Backgrounds are shown separately for the dominant Z+jets contribution (green), the ZV SM diboson contribution (red), and the lepton flavor symmetric backgrounds derived from e$\mu$ data (cyan). The gray band shows the statistical and systematic uncertainties in the background, while the dashed vertical region (Higgs) shows the expected SM Higgs mass range, which is excluded from the analysis. A 600 GeV bulk graviton signal prediction is represented by the black dashed histogram. The background normalization is derived from a fit to the $ {m_{{\mathrm {V}\mathrm {Z}}}} $ observable in the signal and sideband regions.
png pdf	Figure 2: The $ {m_\mathrm {j}} $ distributions of the data events, compared to the expected background shape, for the high-mass analysis in the electron (top) and muon (bottom) channels, for the high (left) and low (right) purity categories. The expected background shape is extracted from a fit to the data sidebands (Z+jets) or derived from simulation (Top and VV). The shaded area represents the uncertainty in the Z+jets distribution, while the dashed vertical region (Higgs) refers to the expected SM Higgs mass range, excluded from the analysis. The bottom panels show the pull distribution between data and SM background expectation from the fit, where $\sigma _\text {data}$ is the Poisson uncertainty in the data.
png pdf	Figure 2-a: The $ {m_\mathrm {j}} $ distribution of the data events, compared to the expected background shape, for the high-mass analysis in the electron channel, for the high purity category. The expected background shape is extracted from a fit to the data sidebands (Z+jets) or derived from simulation (Top and VV). The shaded area represents the uncertainty in the Z+jets distribution, while the dashed vertical region (Higgs) refers to the expected SM Higgs mass range, excluded from the analysis. The bottom panel shows the pull distribution between data and SM background expectation from the fit, where $\sigma _\text {data}$ is the Poisson uncertainty in the data.
png pdf	Figure 2-b: The $ {m_\mathrm {j}} $ distribution of the data events, compared to the expected background shape, for the high-mass analysis in the electron channel, for the low purity category. The expected background shape is extracted from a fit to the data sidebands (Z+jets) or derived from simulation (Top and VV). The shaded area represents the uncertainty in the Z+jets distribution, while the dashed vertical region (Higgs) refers to the expected SM Higgs mass range, excluded from the analysis. The bottom panel shows the pull distribution between data and SM background expectation from the fit, where $\sigma _\text {data}$ is the Poisson uncertainty in the data.
png pdf	Figure 2-c: The $ {m_\mathrm {j}} $ distribution of the data events, compared to the expected background shape, for the high-mass analysis in the muon channel, for the high purity category. The expected background shape is extracted from a fit to the data sidebands (Z+jets) or derived from simulation (Top and VV). The shaded area represents the uncertainty in the Z+jets distribution, while the dashed vertical region (Higgs) refers to the expected SM Higgs mass range, excluded from the analysis. The bottom panel shows the pull distribution between data and SM background expectation from the fit, where $\sigma _\text {data}$ is the Poisson uncertainty in the data.
png pdf	Figure 2-d: The $ {m_\mathrm {j}} $ distribution of the data events, compared to the expected background shape, for the high-mass analysis in the muon channel, for the low purity category. The expected background shape is extracted from a fit to the data sidebands (Z+jets) or derived from simulation (Top and VV). The shaded area represents the uncertainty in the Z+jets distribution, while the dashed vertical region (Higgs) refers to the expected SM Higgs mass range, excluded from the analysis. The bottom panel shows the pull distribution between data and SM background expectation from the fit, where $\sigma _\text {data}$ is the Poisson uncertainty in the data.
png pdf	Figure 3: Expected and observed distributions of the resonance candidate mass $ {m_{{\mathrm {V}\mathrm {Z}}}} $ in the high-mass analysis, in the electron (top) and muon (bottom) channels, and separately for the high (left) and low purity (right) categories. The shaded area represents the post-fit uncertainty in the background. The bottom panels show the pull distribution between data and post-fit SM background fit, where $\sigma _\text {data}$ is the Poisson uncertainty in the data. The expected contribution from W' signal candidates with mass $ {m_{{\mathrm {X}}}} = $ 2000 GeV, normalized to a cross section of 100 fb, is also shown (red line).
png pdf	Figure 3-a: Expected and observed distributions of the resonance candidate mass $ {m_{{\mathrm {V}\mathrm {Z}}}} $ in the high-mass analysis, in the electron channel, for the high purity category. The shaded area represents the post-fit uncertainty in the background. The bottom panels show the pull distribution between data and post-fit SM background fit, where $\sigma _\text {data}$ is the Poisson uncertainty in the data. The expected contribution from W' signal candidates with mass $ {m_{{\mathrm {X}}}} = $ 2000 GeV, normalized to a cross section of 100 fb, is also shown (red line).
png pdf	Figure 3-b: Expected and observed distributions of the resonance candidate mass $ {m_{{\mathrm {V}\mathrm {Z}}}} $ in the high-mass analysis, in the electron channel, for the low purity category. The shaded area represents the post-fit uncertainty in the background. The bottom panels show the pull distribution between data and post-fit SM background fit, where $\sigma _\text {data}$ is the Poisson uncertainty in the data. The expected contribution from W' signal candidates with mass $ {m_{{\mathrm {X}}}} = $ 2000 GeV, normalized to a cross section of 100 fb, is also shown (red line).
png pdf	Figure 3-c: Expected and observed distributions of the resonance candidate mass $ {m_{{\mathrm {V}\mathrm {Z}}}} $ in the high-mass analysis, in the muon channel, for the high purity category. The shaded area represents the post-fit uncertainty in the background. The bottom panels show the pull distribution between data and post-fit SM background fit, where $\sigma _\text {data}$ is the Poisson uncertainty in the data. The expected contribution from W' signal candidates with mass $ {m_{{\mathrm {X}}}} = $ 2000 GeV, normalized to a cross section of 100 fb, is also shown (red line).
png pdf	Figure 3-d: Expected and observed distributions of the resonance candidate mass $ {m_{{\mathrm {V}\mathrm {Z}}}} $ in the high-mass analysis, in the muon channel, for the low purity category. The shaded area represents the post-fit uncertainty in the background. The bottom panels show the pull distribution between data and post-fit SM background fit, where $\sigma _\text {data}$ is the Poisson uncertainty in the data. The expected contribution from W' signal candidates with mass $ {m_{{\mathrm {X}}}} = $ 2000 GeV, normalized to a cross section of 100 fb, is also shown (red line).
png pdf	Figure 4: Sideband $ {m_{{\mathrm {V}\mathrm {Z}}}} $ distributions for the low-mass search in the merged V (top), resolved V (bottom), untagged (left) and tagged (right) categories, after fitting the sideband data alone. The points show the data while the filled histograms show the background contributions. Electron and muon events are shown combined. The gray band indicates the statistical and post-fit systematic uncertainties in the normalization and shape of the background.
png pdf	Figure 4-a: Sideband $ {m_{{\mathrm {V}\mathrm {Z}}}} $ distribution for the low-mass search in the merged V, untagged category, after fitting the sideband data alone. The points show the data while the filled histograms show the background contributions. Electron and muon events are shown combined. The gray band indicates the statistical and post-fit systematic uncertainties in the normalization and shape of the background.
png pdf	Figure 4-b: Sideband $ {m_{{\mathrm {V}\mathrm {Z}}}} $ distribution for the low-mass search in the merged V, tagged category, after fitting the sideband data alone. The points show the data while the filled histograms show the background contributions. Electron and muon events are shown combined. The gray band indicates the statistical and post-fit systematic uncertainties in the normalization and shape of the background.
png pdf	Figure 4-c: Sideband $ {m_{{\mathrm {V}\mathrm {Z}}}} $ distribution for the low-mass search in the resolved V, untagged category, after fitting the sideband data alone. The points show the data while the filled histograms show the background contributions. Electron and muon events are shown combined. The gray band indicates the statistical and post-fit systematic uncertainties in the normalization and shape of the background.
png pdf	Figure 4-d: Sideband $ {m_{{\mathrm {V}\mathrm {Z}}}} $ distribution for the low-mass search in the resolved V, tagged category, after fitting the sideband data alone. The points show the data while the filled histograms show the background contributions. Electron and muon events are shown combined. The gray band indicates the statistical and post-fit systematic uncertainties in the normalization and shape of the background.
png pdf	Figure 5: The signal region $ {m_{{\mathrm {V}\mathrm {Z}}}} $ distributions for the low-mass search, in the the merged V (top), resolved V (bottom), untagged (left) and tagged (right) categories, after fitting the signal and sideband regions. Electron and muon events are shown combined. A 600 GeV bulk graviton signal prediction is represented by the black dashed histogram. The gray band indicates the statistical and post-fit systematic uncertainties in the normalization and shape of the background.
png pdf	Figure 5-a: The signal region $ {m_{{\mathrm {V}\mathrm {Z}}}} $ distribution for the low-mass search, in the the merged V, untagged category, after fitting the signal and sideband regions. Electron and muon events are shown combined. A 600 GeV bulk graviton signal prediction is represented by the black dashed histogram. The gray band indicates the statistical and post-fit systematic uncertainties in the normalization and shape of the background.
png pdf	Figure 5-b: The signal region $ {m_{{\mathrm {V}\mathrm {Z}}}} $ distribution for the low-mass search, in the the merged V, tagged category, after fitting the signal and sideband regions. Electron and muon events are shown combined. A 600 GeV bulk graviton signal prediction is represented by the black dashed histogram. The gray band indicates the statistical and post-fit systematic uncertainties in the normalization and shape of the background.
png pdf	Figure 5-c: The signal region $ {m_{{\mathrm {V}\mathrm {Z}}}} $ distribution for the low-mass search, in the the resolved V, untagged category, after fitting the signal and sideband regions. Electron and muon events are shown combined. A 600 GeV bulk graviton signal prediction is represented by the black dashed histogram. The gray band indicates the statistical and post-fit systematic uncertainties in the normalization and shape of the background.
png pdf	Figure 5-d: The signal region $ {m_{{\mathrm {V}\mathrm {Z}}}} $ distribution for the low-mass search, in the the resolved V, tagged category, after fitting the signal and sideband regions. Electron and muon events are shown combined. A 600 GeV bulk graviton signal prediction is represented by the black dashed histogram. The gray band indicates the statistical and post-fit systematic uncertainties in the normalization and shape of the background.
png pdf	Figure 6: Observed and expected 95% CL upper limit on $\sigma _{{\mathrm {W}} '} {\mathcal {B}} ({\mathrm {W}} '\to {\mathrm {Z}\mathrm {W}})$ (left) and $\sigma _{{\mathrm {G}}} {\mathcal {B}} ({\mathrm {G}} \to {\mathrm {Z}\mathrm {Z}})$ (right) as a function of the resonance mass, including all statistical and systematic uncertainties. The electron and muon channels and the various categories used in the analysis are combined together. The green and yellow bands represent the 68% and 95% coverage of the expected limit in the background-only hypothesis. The dashed vertical line represents the separation between the low- and the high-mass analysis strategy. Theoretical predictions for the signal production cross section are also shown: (left) W' produced in the framework of HVT model A with $g_\text {v}= $ 1 and model B with $g_\text {v}= $ 3; (right) G produced in the WED bulk graviton model with $ \tilde{\kappa} = $ 0.5.
png pdf	Figure 6-a: Observed and expected 95% CL upper limit on $\sigma _{{\mathrm {W}} '} {\mathcal {B}} ({\mathrm {W}} '\to {\mathrm {Z}\mathrm {W}})$ as a function of the resonance mass, including all statistical and systematic uncertainties. The electron and muon channels and the various categories used in the analysis are combined together. The green and yellow bands represent the 68% and 95% coverage of the expected limit in the background-only hypothesis. The dashed vertical line represents the separation between the low- and the high-mass analysis strategy. Theoretical predictions for the signal production cross section are also shown: (left) W' produced in the framework of HVT model A with $g_\text {v}= $ 1 and model B with $g_\text {v}= $ 3; (right) G produced in the WED bulk graviton model with $ \tilde{\kappa} = $ 0.5.
png pdf	Figure 6-b: Observed and expected 95% CL upper limit on $\sigma _{{\mathrm {G}}} {\mathcal {B}} ({\mathrm {G}} \to {\mathrm {Z}\mathrm {Z}})$ as a function of the resonance mass, including all statistical and systematic uncertainties. The electron and muon channels and the various categories used in the analysis are combined together. The green and yellow bands represent the 68% and 95% coverage of the expected limit in the background-only hypothesis. The dashed vertical line represents the separation between the low- and the high-mass analysis strategy. Theoretical predictions for the signal production cross section are also shown: (left) W' produced in the framework of HVT model A with $g_\text {v}= $ 1 and model B with $g_\text {v}= $ 3; (right) G produced in the WED bulk graviton model with $ \tilde{\kappa} = $ 0.5.
png pdf	Figure 7: Observed local p-values for W' (left) and G (right) narrow resonances as a function of the resonance mass. The dashed vertical line represents the separation between the low- and the high-mass analysis strategy.
png pdf	Figure 7-a: Observed local p-values for W' narrow resonance as a function of the resonance mass. The dashed vertical line represents the separation between the low- and the high-mass analysis strategy.
png pdf	Figure 7-b: Observed local p-values for G narrow resonance as a function of the resonance mass. The dashed vertical line represents the separation between the low- and the high-mass analysis strategy.

Tables

png pdf

Table 1: Summary of systematic uncertainties affecting the normalization of background and signal samples. In the case a systematic uncertainty depends on the resonance mass (for signal) or on the category (for background), the smallest and largest values are reported in the table. A dash (-) represents uncertainties either estimated to be negligible (below 0.1%), or not applicable in the specific analysis category.

Summary

A search for heavy resonances decaying into a Z boson and a Z or a W boson in the 2$\ell$2q final state has been presented. The data analyzed was collected by the CMS experiment from proton-proton collisions at $\sqrt{s} = $ 13 TeV during 2016 operations at the LHC, corresponding to an integrated luminosity of 35.9 fb$^{-1}$. The final state searched for consists of a Z boson decaying leptonically into an electron or muon pair, and the decay of an additional W or Z boson into a pair of quarks. Two analysis strategies, dedicated to the low- and high-mass regimes, have been used to set limits in the range of resonance mass from 400 GeV to 4.5 TeV. Depending on the resonance mass, upper expected limits of 3-3000 fb and 1.5-400 fb have been set on the product of the cross section of a spin-1 W' signal and the ZW branching fraction, and on a spin-2 graviton signal and the ZZ branching fraction, respectively. The results of the present analysis extend the ones previously obtained by the ATLAS and CMS collaborations in the analogous final state [46,10].

References
1	K. Agashe, H. Davoudiasl, G. Perez, and A. Soni	Warped gravitons at the LHC and beyond	PRD 76 (2007) 036006	hep-ph/0701186
2	L. Randall and R. Sundrum	A large mass hierarchy from a small extra dimension	PRL 83 (1999) 3370	hep-ph/9905221
3	L. Randall and R. Sundrum	An alternative to compactification	PRL 83 (1999) 4690	hep-th/9906064
4	A. L. Fitzpatrick, J. Kaplan, L. Randall, and L.-T. Wang	Searching for the Kaluza-Klein graviton in bulk RS models	JHEP 09 (2007) 013	hep-ph/0701150
5	W. D. Goldberger and M. B. Wise	Modulus stabilization with bulk fields	PRL 83 (1999) 4922	hep-ph/9907447
6	D. Pappadopulo, A. Thamm, R. Torre, and A. Wulzer	Heavy vector triplets: Bridging theory and data	JHEP 09 (2014) 060	1402.4431
7	CMS Collaboration	Search for heavy resonances decaying into a vector boson and a Higgs boson in final states with charged leptons, neutrinos, and b quarks	PLB 768 (2017) 137	CMS-B2G-16-003 1610.08066
8	CMS Collaboration	Search for massive resonances decaying into WW, WZ or ZZ bosons in proton-proton collisions at $ \sqrt{s} = $ 13 TeV	JHEP 03 (2017) 162	CMS-B2G-16-004 1612.09159
9	CMS Collaboration	Combination of searches for heavy resonances decaying to WW, WZ, ZZ, WH, and ZH boson pairs in proton-proton collisions at $ \sqrt{s} = $ 8 and 13 TeV	Submitted to \it PLB	CMS-B2G-16-007 1705.09171
10	ATLAS Collaboration	Search for heavy resonances decaying to a $ W $ or $ Z $ boson and a Higgs boson in the $ q\bar{q}^{(\prime)}b\bar{b} $ final state in $ pp $ collisions at $ \sqrt{s} = $ 13 TeV with the ATLAS detector	PLB 774 (2017) 494	1707.06958
11	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
12	A. Oliveira	Gravity particles from Warped Extra Dimensions, predictions for LHC		1404.0102
13	R. Frederix and S. Frixione	Merging meets matching in MC@NLO	JHEP 12 (2012) 061	1209.6215
14	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
15	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
16	E. Re	Single-top Wt-channel production matched with parton showers using the POWHEG method	EPJC 71 (2011) 1547	1009.2450
17	T. Sjostrand et al.	An introduction to PYTHIA 8.2	CPC 191 (2015) 159	1410.3012
18	CMS Collaboration	Event generator tunes obtained from underlying event and multiparton scattering measurements	EPJC (2016) 155	CMS-GEN-14-001 1512.00815
19	NNPDF Collaboration	Parton distributions from high-precision collider data		1706.00428
20	GEANT4 Collaboration	GEANT4: A simulation toolkit	NIMA 506 (2003) 250
21	CMS Collaboration	The CMS experiment at the CERN LHC	JINST 3 (2008) S08004	CMS-00-001
22	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
23	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
24	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
25	CMS Collaboration	Particle-flow reconstruction and global event description with the CMS detector	JINST 12 (2017) P10003	CMS-PRF-14-001 1706.04965
26	M. Cacciari, G. P. Salam, and G. Soyez	The anti-$ k_t $ jet clustering algorithm	JHEP 04 (2008) 063	0802.1189
27	M. Cacciari, G. P. Salam, and G. Soyez	FastJet user manual	EPJC 72 (2012) 1896	1111.6097
28	CMS Collaboration	Jet energy scale and resolution in the CMS experiment in pp collisions at 8 TeV	JINST 12 (2017) P02014	CMS-JME-13-004 1607.03663
29	M. Dasgupta, A. Fregoso, S. Marzani, and G. P. Salam	Towards an understanding of jet substructure	JHEP 09 (2013) 029	1307.0007
30	A. J. Larkoski, S. Marzani, G. Soyez, and J. Thaler	Soft Drop	JHEP 05 (2014) 146	1402.2657
31	D. Bertolini, P. Harris, M. Low, and N. Tran	Pileup Per Particle Identification	JHEP 10 (2014) 059	1407.6013
32	J. Thaler and K. Van Tilburg	Identifying Boosted Objects with N-subjettiness	JHEP 03 (2011) 015	1011.2268
33	CMS Collaboration	Identification of b-quark jets with the CMS experiment	JINST 8 (2013) P04013	CMS-BTV-12-001 1211.4462
34	M. J. Oreglia	A study of the reactions $\psi' \to \gamma\gamma \psi$	PhD thesis, Stanford University, 1980 SLAC Report SLAC-R-236, see Appendix D
35	CMS Collaboration	Measurement of the ZZ production cross section and Z $ \to \ell^+\ell^-\ell'^+\ell'^- $ branching fraction in pp collisions at $ \sqrt s = $ 13 TeV	PLB 763 (2016) 280	CMS-SMP-16-001 1607.08834
36	CMS Collaboration	Measurement of the WZ production cross section in pp collisions at $ \sqrt{s} = $ 13 TeV	PLB 766 (2017) 268	CMS-SMP-16-002 1607.06943
37	CMS Collaboration	Measurement of the $ t\bar{t} $ production cross section using events in the e$ \mu $ final state in pp collisions at $ \sqrt{s} = $ 13 TeV	EPJC 77 (2017) 172	CMS-TOP-16-005 1611.04040
38	CMS Collaboration	Jet algorithms performance in 13 TeV data	CMS-PAS-JME-16-003	CMS-PAS-JME-16-003
39	CMS Collaboration	Identification techniques for highly boosted W bosons that decay into hadrons	JHEP 12 (2014) 017	CMS-JME-13-006 1410.4227
40	M. Bahr et al.	Herwig++ physics and manual	EPJC 58 (2008) 639	0803.0883
41	CMS Collaboration	Cms luminosity measurements for the 2016 data taking period	CMS-PAS-LUM-17-001	CMS-PAS-LUM-17-001
42	A. L. Read	Presentation of search results: The CL(s) technique	JPG 28 (2002) 2693
43	T. Junk	Confidence level computation for combining searches with small statistics	NIMA 434 (1999) 435	hep-ex/9902006
44	G. Cowan, K. Cranmer, E. Gross, and O. Vitells	Asymptotic formulae for likelihood-based tests of new physics	EPJC 71 (2011) 1554	1007.1727
45	The ATLAS Collaboration, The CMS Collaboration, The LHC Higgs Combination Group Collaboration	Procedure for the LHC Higgs boson search combination in Summer 2011	CMS-NOTE-2011-005
46	CMS Collaboration	Search for heavy resonances decaying into a $ \mathrm{Z} $ boson and a $ \mathrm{W} $ boson in the $ \ell^+\ell^-\mathrm{q}\bar{\mathrm{q}} $ final state	CMS-PAS-B2G-16-022	CMS-PAS-B2G-16-022

Compact Muon Solenoid LHC, CERN

© Copyright CERN 2018 for the benefit of the CMS Collaboration