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CMS-PAS-EXO-16-052

Search for dark matter, invisible Higgs boson decays, and large extra dimensions in the $\ell\ell+E_\mathrm{T}^\mathrm{miss}$ final state using 2016 data

CMS Collaboration

May 2017

Abstract: A search for new physics in events with a Z boson produced in association with large missing transverse momentum with the CMS experiment at the LHC is presented. The search is based on the 2016 data sample of proton-proton collisions at $\sqrt{s} = $ 13 TeV corresponding to an integrated luminosity of 35.9 fb$^{-1}$. The results of this search are interpreted in terms of a simplified model of dark matter production with spin-0 or spin-1 mediators, a standard model Higgs boson decaying invisibly and produced in association with the Z boson, as well as a model with large extra spatial dimensions. For all models, no significant deviation from the background expectation is found, and limits are set with respect to relevant model parameters.

Links: CDS record (PDF) ; inSPIRE record ; CADI line (restricted) ; These preliminary results are superseded in this paper, EPJC 78 (2018) 291. The superseded preliminary plots can be found here.

Figures
png pdf	Figure 1: Feynman diagrams illustrative of the beyond the standard model processes considered in this paper: (a) dark matter production in a simplified model with a spin-1 mediator $\cal {A}$; (b) dark matter production in a simplified model with a spin-0 mediator $\phi $; (c) production of a Higgs boson in association with Z boson with subsequent decay of the Higgs boson into invisible particles; (d) graviton production in the scenario of large extra dimensions.
png pdf	Figure 1-a: Feynman diagram illustrative of one of the beyond the standard model processes considered in this paper: dark matter production in a simplified model with a spin-1 mediator $\cal {A}$.
png pdf	Figure 1-b: Feynman diagram illustrative of one of the beyond the standard model processes considered in this paper: dark matter production in a simplified model with a spin-0 mediator $\phi $.
png pdf	Figure 1-c: Feynman diagram illustrative of one of the beyond the standard model processes considered in this paper: production of a Higgs boson in association with Z boson with subsequent decay of the Higgs boson into invisible particles.
png pdf	Figure 1-d: Feynman diagram illustrative of one of the beyond the standard model processes considered in this paper: graviton production in the scenario of large extra dimensions.
png pdf	Figure 2: Emulated $ { {E_\mathrm {T}}^{\mathrm {miss}}}$ distribution for the $ {\mathrm {W}}{\mathrm{ Z } } \to 3 {\ell }\nu $ (top left) and ${\mathrm{ Z } } {\mathrm{ Z } } \to 4 {\ell }$ (top right) control regions, and the ratio between both distributions in data and simulation (bottom). Uncertainty bands correspond to the combined statistical and systematic components.
png pdf	Figure 2-a: Emulated $ { {E_\mathrm {T}}^{\mathrm {miss}}}$ distribution for the $ {\mathrm {W}}{\mathrm{ Z } } \to 3 {\ell }\nu $ control region. Uncertainty bands correspond to the combined statistical and systematic components.
png pdf	Figure 2-b: Emulated $ { {E_\mathrm {T}}^{\mathrm {miss}}}$ distribution for the ${\mathrm{ Z } } {\mathrm{ Z } } \to 4 {\ell }$ control region. Uncertainty bands correspond to the combined statistical and systematic components.
png pdf	Figure 2-c: Ratio between distributions in Fig.2-a and Fig.2-b, in data and simulation. Uncertainty bands correspond to the combined statistical and systematic components.
png pdf	Figure 3: Post-fit distribution of the BDT classifier in the diboson control regions: (left) WZ three-lepton region; (right) ZZ four-lepton region.
png pdf	Figure 3-a: Post-fit distribution of the BDT classifier in the WZ three-lepton control region.
png pdf	Figure 3-b: Post-fit distribution of the BDT classifier in the ZZ four-lepton control region.
png pdf	Figure 4: Distribution of the $ { {E_\mathrm {T}}^{\mathrm {miss}}}$ in the ${\mathrm ee}+\mu \mu $ channel after the full selection, including the region between 50 and 100 GeV. The last bin also includes any events with $ { {E_\mathrm {T}}^{\mathrm {miss}}}> $ 600 GeV. The uncertainty band includes both statistical and systematic components. The $ {{\mathrm{ Z } } {\mathrm {H}}(\mathrm {inv.})}$ signal normalization assumes SM production rates and $\mathcal {B}( {\mathrm {H}}\to {\rm inv.}) = 1$.
png pdf	Figure 5: The 95%CL expected and observed limits on $\sigma _{\rm obs}/\sigma _{\rm theo}$ for the vector (left) and axial-vector (right) mediated DM scenario with $g_{\rm q}= $ 0.25. Limits are not shown for far off-shell ($2m_{\rm DM} > 1.5 m_{\rm med}$) regions of the parameter space.
png pdf	Figure 5-a: The 95%CL expected and observed limits on $\sigma _{\rm obs}/\sigma _{\rm theo}$ for the vector mediated DM scenario with $g_{\rm q}= $ 0.25. Limits are not shown for far off-shell ($2m_{\rm DM} > 1.5 m_{\rm med}$) regions of the parameter space.
png pdf	Figure 5-b: The 95%CL expected and observed limits on $\sigma _{\rm obs}/\sigma _{\rm theo}$ for the axial-vector mediated DM scenario with $g_{\rm q}= $ 0.25. Limits are not shown for far off-shell ($2m_{\rm DM} > 1.5 m_{\rm med}$) regions of the parameter space.
png pdf	Figure 6: The 95%CL expected and observed limits on $\sigma _{\rm obs}/\sigma _{\rm theo}$ for the scalar (left) and pseudoscalar (right) mediated DM scenario with $g_{\rm q}= $ 1. The limits are parameterized as a function of mediator mass $m_{\rm med}$ for fixed dark matter mass $m_{\rm DM}= $ 1 GeV.
png pdf	Figure 6-a: The 95%CL expected and observed limits on $\sigma _{\rm obs}/\sigma _{\rm theo}$ for the scalar mediated DM scenario with $g_{\rm q}= $ 1. The limits are parameterized as a function of mediator mass $m_{\rm med}$ for fixed dark matter mass $m_{\rm DM}= $ 1 GeV.
png pdf	Figure 6-b: The 95%CL expected and observed limits on $\sigma _{\rm obs}/\sigma _{\rm theo}$ for the pseudoscalar mediated DM scenario with $g_{\rm q}= $ 1. The limits are parameterized as a function of mediator mass $m_{\rm med}$ for fixed dark matter mass $m_{\rm DM}= $ 1 GeV.
png pdf	Figure 7: Observed 90% CL limits on the DM-nucleon scattering cross sections in both spin-independent (left) and spin-dependent (right) cases, assuming a mediator-quark coupling constant $g_{\rm q} = $ 0.25 and mediator-DM coupling constant $g_{\rm DM} = $ 1. Limits from the LUX [75], CDMSLite [76], PandaX-II [77], and CRESST-II [78] experiments are shown for the spin-independent case. Limits from the Super-Kamiokande [79], PICO-60 [80], and IceCube [81,82] experiments are shown for the spin-dependent case.
png pdf	Figure 7-a: Observed 90% CL limits on the DM-nucleon scattering cross sections in the spin-independent case, assuming a mediator-quark coupling constant $g_{\rm q} = $ 0.25 and mediator-DM coupling constant $g_{\rm DM} = $ 1. Limits from the LUX [75], CDMSLite [76], PandaX-II [77], and CRESST-II [78] experiments are shown.
png pdf	Figure 7-b: Observed 90% CL limits on the DM-nucleon scattering cross sections in the spin-dependent case, assuming a mediator-quark coupling constant $g_{\rm q} = $ 0.25 and mediator-DM coupling constant $g_{\rm DM} = $ 1. Limits from the Super-Kamiokande [79], PICO-60 [80], and IceCube [81,82] experiments are shown.
png pdf	Figure 8: Expected and observed 95% CL cross section exclusion limits for the example case $n= $ 4 in the ADD scenario (left) and exclusion limits on $M_{D}$ for different values of $n$ (right). In both plots, the markers for expected exclusion are obscured by the close overlap with the observed curves. The red solid line shows the theoretical cross section for given values of $n$. Cross sections are calculated for the fiducial phase space of $ {p_{\mathrm {T}}} (\rm Graviton) > $ 50 GeV. Gray lines show the projection of the intersection between theory and expected as well as observed exclusion onto the $M_{D}$ axis.
png pdf	Figure 8-a: Expected and observed 95% CL cross section exclusion limits for the example case $n= $ 4 in the ADD scenario. The markers for expected exclusion are obscured by the close overlap with the observed curves. The red solid line shows the theoretical cross section for given values of $n$. Cross sections are calculated for the fiducial phase space of $ {p_{\mathrm {T}}} (\rm Graviton) > $ 50 GeV. Gray lines show the projection of the intersection between theory and expected as well as observed exclusion onto the $M_{D}$ axis.
png pdf	Figure 8-b: Exclusion limits on $M_{D}$ for different values of $n$. The markers for expected exclusion are obscured by the close overlap with the observed curves. The red solid line shows the theoretical cross section for given values of $n$.
png pdf	Figure 9: Post-fit distribution of the BDT classifier in the multivariate analysis signal region for the SM H(inv.) decay hypothesis.
png pdf	Figure 10: Expected and observed 95% CL upper limits on the production cross section times branching fraction, $\sigma _{ {{\mathrm{ Z } } {\mathrm {H}}}} \times \mathcal {B}( {\mathrm {H}}\to {\rm inv.})$ as a function of the Higgs boson mass.

Tables
png pdf	Table 1: Summary of the kinematic selection requirements for the $ { {E_\mathrm {T}}^{\mathrm {miss}}}$-based analysis.
png pdf	Table 2: Summary of systematic uncertainties. Each uncertainty represents the variation of the relative yields of the processes in the signal region. A particular uncertainty is fully correlated across processes to which it contributes, including those processes that are also present in control regions. The symbol "-" indicates that the systematic uncertainty does not contribute or is deemed negligible. For minor backgrounds, systematic uncertainties are omitted due to the smallness of their contribution. For shape uncertainties (indicated with a *), the numbers correspond to the overall effect of the shape variation on the yield or acceptance. The impact on the expected upper limit on the signal strength, i.e.\ the relative decrease in the median expected upper limit on signal strength upon removing the nuisance, is also evaluated with respect to the SM Higgs boson signal.
png pdf	Table 3: Summary of the training preselection for the multivariate analysis.
png pdf	Table 4: Observed number of events, post-fit background estimates, and signal predictions. The combined statistical and systematic uncertainties are reported.
png pdf	Table 5: Expected event yields in each $ { {E_\mathrm {T}}^{\mathrm {miss}}}$ bin for the sum of background processes in the signal region. The background yields and their corresponding uncertainties are obtained after performing a combined fit to data in all control regions, but excluding data in the signal region. The observed events in each bin are also included.

Summary

A search for new physics in events with a Z boson produced in association with large missing transverse momentum with the CMS experiment at the LHC has been presented. This search is interpreted in simplified models with both spin-0 and spin-1 dark matter mediators, a large extra-dimensional model, and in a model with a standard model Higgs-like scalar particle, each produced in association with the Z boson and decaying invisibly. The search is based on a 2016 data sample of proton-proton collisions at $\sqrt{s} = $ 13 TeV corresponding to an integrated luminosity of 35.9 fb$^{-1}$ and sets stringent limits on the parameter space of these models.

Additional Figures
png pdf	Additional Figure 1: Expected and observed 95% CL upper limits on $\mathcal {B}(\mathrm {H} \to {\rm inv.})$, assuming SM Higgs production cross sections, as a function of the Higgs boson mass.
png pdf	Additional Figure 2: Correlations between the estimated background yields in the signal region $E_\mathrm {T}^\mathrm {miss}$ bins. The correlations are obtained after performing a combined fit to data in all control regions, but excluding data in the signal region.

References
1	G. Hinshaw et al.	Nine-year Wilkinson Microwave Anisotropy Probe (WMAP) Observations: Cosmological Parameter Results	Astrophys. J. Suppl. 208 (2013) 19	1212.5226
2	P. Cushman et al.	Snowmass CF1 Summary: WIMP Dark Matter Direct Detection		1310.8327
3	J. Buckley et al.	Indirect Dark Matter Detection CF2 Working Group Summary		1310.7040
4	CMS Collaboration	Search for dark matter, extra dimensions, and unparticles in monojet events in proton-proton collisions at $ \sqrt{s} = $ 8 TeV	EPJC 75 (2015) 235	CMS-EXO-12-048 1408.3583
5	ATLAS Collaboration	Search for new phenomena in final states with an energetic jet and large missing transverse momentum in pp collisions at $ \sqrt{s} = $ 8 TeV with the ATLAS detector	EPJC 75 (2015) 299	1502.01518
6	CMS Collaboration	Search for new phenomena in monophoton final states in proton-proton collisions at $ \sqrt{s} = $ 8 TeV	PLB 755 (2016) 102	CMS-EXO-12-047 1410.8812
7	ATLAS Collaboration	Search for new phenomena in events with a photon and missing transverse momentum in pp collisions at $ \sqrt{s} = $ 8 TeV with the ATLAS detector	PRD 91 (2015) 012008	1411.1559
8	CMS Collaboration	Search for physics beyond the standard model in final states with a lepton and missing transverse energy in proton-proton collisions at $ \sqrt{s} = $ 8 TeV	PRD 91 (2015) 092005	CMS-EXO-12-060 1408.2745
9	ATLAS Collaboration	Search for dark matter in events with heavy quarks and missing transverse momentum in pp collisions with the ATLAS detector	EPJC 75 (2015) 92	1410.4031
10	ATLAS Collaboration	Search for dark matter in events with a hadronically decaying W or Z boson and missing transverse momentum in pp collisions at $ \sqrt{s} = $ 8 TeV with the ATLAS detector	PRL 112 (2014) 041802	1309.4017
11	ATLAS Collaboration	Search for new particles in events with one lepton and missing transverse momentum in pp collisions at $ \sqrt{s} = $ 8 TeV with the ATLAS detector	JHEP 09 (2014) 037	1407.7494
12	ATLAS Collaboration	Search for invisible particles produced in association with single-top-quarks in proton-proton collisions at $ \sqrt{s} = $ 8 TeV with the ATLAS detector	EPJC 75 (2015) 79	1410.5404
13	ATLAS Collaboration	Search for Dark Matter in Events with Missing Transverse Momentum and a Higgs Boson Decaying to Two Photons in pp Collisions at $ \sqrt{s} = $ 8 TeV with the ATLAS Detector	PRL 115 (2015) 131801	1506.01081
14	CMS Collaboration	Search for Monotop Signatures in Proton-Proton Collisions at $ \sqrt{s} = $ 8 TeV	PRL 114 (2015) 101801	CMS-B2G-12-022 1410.1149
15	CMS Collaboration	Search for the production of dark matter in association with top-quark pairs in the single-lepton final state in proton-proton collisions at $ \sqrt{s} = $ 8 TeV	JHEP 06 (2015) 121	CMS-B2G-14-004 1504.03198
16	ATLAS Collaboration	Search for dark matter in events with a Z boson and missing transverse momentum in pp collisions at $ \sqrt{s} = $ 8 TeV with the ATLAS detector	PRD 90 (2014) 012004	1404.0051
17	CMS Collaboration	Search for dark matter and unparticles produced in association with a Z boson in proton-proton collisions at $ \sqrt{s} = $ 8 TeV	PRD 93 (2015) 052011	CMS-EXO-12-054 1511.09375
18	D. Abercrombie et al.	Dark Matter Benchmark Models for Early LHC Run-2 Searches: Report of the ATLAS/CMS Dark Matter Forum		1507.00966
19	ATLAS Collaboration	Observation of a new particle in the search for the Standard Model Higgs boson with the ATLAS detector at the LHC	PLB 716 (2012) 1	1207.7214
20	CMS Collaboration	Observation of a new boson at a mass of 125 GeV with the CMS experiment at the LHC	PLB 716 (2012) 30	CMS-HIG-12-028 1207.7235
21	CMS Collaboration	Observation of a new boson with mass near 125 GeV in pp collisions at $ \sqrt{s} = $ 7 and 8 TeV	JHEP 06 (2013) 081	CMS-HIG-12-036 1303.4571
22	D. Ghosh et al.	Looking for an Invisible Higgs Signal at the LHC	PLB 725 (2013) 344	1211.7015
23	S. P. Martin and J. D. Wells	Motivation and detectability of an invisibly decaying Higgs boson at the Fermilab Tevatron	PRD 60 (1999) 035006	hep-ph/9903259
24	Y. Bai, P. Draper, and J. Shelton	Measuring the Invisible Higgs Width at the 7 and 8 TeV LHC	JHEP 07 (2012) 192	1112.4496
25	G. Belanger et al.	The MSSM invisible Higgs in the light of dark matter and g-2	PLB 519 (2001) 93	hep-ph/0106275
26	G. F. Giudice, R. Rattazzi, and J. D. Wells	Graviscalars from higher dimensional metrics and curvature Higgs mixing	Nucl. Phys. B 595 (2001) 250	hep-ph/0002178
27	M. Battaglia, D. Dominici, J. Gunion, and J. Wells	The Invisible Higgs decay width in the add model at the LHC		hep-ph/0402062
28	N. Arkani-Hamed, S. Dimopoulos, and G. R. Dvali	The Hierarchy problem and new dimensions at a millimeter	PLB 429 (1998) 263	hep-ph/9803315
29	N. Arkani-Hamed, S. Dimopoulos, and G. R. Dvali	Phenomenology, astrophysics and cosmology of theories with submillimeter dimensions and TeV scale quantum gravity	PRD 59 (1999) 086004	hep-ph/9807344
30	T. Han, J. D. Lykken, and R.-J. Zhang	On Kaluza-Klein states from large extra dimensions	PRD 59 (1999) 105006	hep-ph/9811350
31	CMS Collaboration	The CMS experiment at the CERN LHC	JINST 3 (2008) S08004	CMS-00-001
32	S. Alioli, P. Nason, C. Oleari, and E. Re	NLO vector-boson production matched with shower in POWHEG	JHEP 07 (2008) 060	0805.4802
33	P. Nason	A New method for combining NLO QCD with shower Monte Carlo algorithms	JHEP 11 (2004) 040	hep-ph/0409146
34	S. Frixione, P. Nason, and C. Oleari	Matching NLO QCD computations with Parton Shower simulations: the POWHEG method	JHEP 11 (2007) 070	0709.2092
35	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
36	J. M. Campbell and R. K. Ellis	MCFM for the Tevatron and the LHC	NPPS 205-206 (2010) 10	1007.3492
37	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
38	O. Mattelaer and E. Vryonidou	Dark matter production through loop-induced processes at the LHC: the s-channel mediator case	EPJC 75 (2015) 436	1508.00564
39	M. Backovi\'c, M. Kr\"amer, F. Maltoni, A. Martini, K. Mawatari, and M. Pellen	Higher-order QCD predictions for dark matter production at the LHC in simplified models with s-channel mediators	EPJC 75 (2015) 482	1508.05327
40	M. Neubert, J. Wang, and C. Zhang	Higher-Order QCD Predictions for Dark Matter Production in Mono-$ Z $ Searches at the LHC	JHEP 02 (2016) 082	1509.05785
41	T. Sj\"ostrand, S. Mrenna, and P. Z. Skands	A brief introduction to PYTHIA 8.1	CPC 178 (2008) 852	0710.3820
42	S. Ask	Simulation of $ Z $ plus graviton/unparticle production at the LHC	EPJC 60 (2009) 509	0809.4750
43	S. Ask et al.	Real emission and virtual exchange of gravitons and unparticles in PYTHIA8	CPC 181 (2010) 1593	0912.4233
44	CMS Collaboration	Event generator tunes obtained from underlying event and multiparton scattering measurements	EPJC 76 (2016) 155	CMS-GEN-14-001 1512.00815
45	NNPDF Collaboration	Parton distributions for the LHC Run II	JHEP 04 (2015) 040	1410.8849
46	GEANT4 Collaboration	GEANT4---a simulation toolkit	NIMA 506 (2003) 250
47	CMS Collaboration	Performance of electron reconstruction and selection with the CMS detector in proton-proton collisions at $ \sqrt{s} = $ 8 TeV	JINST 10 (2015) 06005	CMS-EGM-13-001 1502.02701
48	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
49	CMS Collaboration	Particle-flow event reconstruction in CMS and performance for jets, taus, and $ E_{\mathrm{T}}^{\text{miss}} $	CDS
50	CMS Collaboration	Commissioning of the particle-flow event with the first LHC collisions recorded in the CMS detector	CDS
51	M. Cacciari and G. P. Salam	Pileup subtraction using jet areas	PLB 659 (2008) 119	0707.1378
52	M. Cacciari, G. P. Salam, and G. Soyez	The anti-$ k_t $ jet clustering algorithm	JHEP 04 (2008) 063	0802.1189
53	M. Cacciari, G. P. Salam, and G. Soyez	FastJet user manual	EPJC 72 (2012) 1896	1111.6097
54	M. Cacciari and G. P. Salam	Dispelling the $ N^{3} $ myth for the $ k_{t} $ jet-finder	PLB 641 (2006) 57	hep-ph/0512210
55	G. S. M. Cacciari, G. P. Salam	The catchment area of jets	JHEP 04 (2008) 005	0802.1188
56	CMS Collaboration	Determination of jet energy calibration and transverse momentum resolution in CMS	JINST 6 (2011) P11002	CMS-JME-10-011 1107.4277
57	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
58	CMS Collaboration	Identification of b-quark jets with the CMS experiment	JINST 8 (2013) 04013	CMS-BTV-12-001 1211.4462
59	CMS Collaboration	Identification of b quark jets at the CMS Experiment in the LHC Run 2	CMS-PAS-BTV-15-001	CMS-PAS-BTV-15-001
60	CMS Collaboration	Reconstruction and identification of $ \tau $ lepton decays to hadrons and $ \nu_\tau $ at CMS	JINST 11 (2016) P01019	CMS-TAU-14-001 1510.07488
61	Particle Data Group Collaboration	Review of Particle Physics	CPC 40 (2016), no. 10, 100001
62	M. Grazzini, S. Kallweit, and D. Rathlev	ZZ production at the LHC: fiducial cross sections and distributions in NNLO QCD	PLB 750 (2015) 407	1507.06257
63	M. Grazzini, S. Kallweit, D. Rathlev, and M. Wiesemann	$ W^{\pm}Z $ production at hadron colliders in NNLO QCD	PLB 761 (2016) 179	1604.08576
64	J. Baglio, L. D. Ninh, and M. M. Weber	Massive gauge boson pair production at the LHC: A next-to-leading order story	PRD 88 (2013) 113005	1307.4331
65	A. Bierweiler, T. Kasprzik, and J. H. Kahn	Vector-boson pair production at the LHC to $ \mathcal{O}(\alpha^3) $ accuracy	JHEP 12 (2013) 071	1305.5402
66	S. Gieseke, T. Kasprzik, and J. H. Kuhn	Vector-boson pair production and electroweak corrections in HERWIG++	EPJC 74 (2014) 2988	1401.3964
67	LHC Higgs Cross Section Working Group	Handbook of LHC Higgs Cross Sections	technical report	1101.0593
68	J. Butterworth et al.	PDF4LHC recommendations for LHC Run II	JPG 43 (2016) 023001	1510.03865
69	CMS Collaboration	Measurement of the inclusive $ W $ and $ Z $ production cross sections in pp collisions at $ \sqrt{s} = $ 7 TeV	JHEP 10 (2011) 132	CMS-EWK-10-005 1107.4789
70	CMS Collaboration	CMS Luminosity Measurements for the 2016 Data Taking Period	CMS-PAS-LUM-17-001	CMS-PAS-LUM-17-001
71	T. Junk	Confidence level computation for combining searches with small statistics	NIMA 434 (1999) 435	hep-ex/9902006
72	A. L. Read	Presentation of search results: the $ CL_{s} $ technique	JPG 28 (2002) 2693
73	G. Cowan, K. Cranmer, E. Gross, and O. Vitells	Asymptotic formulae for likelihood-based tests of new physics	EPJC 71 (2011) 1554	1007.1727
74	ATLAS and CMS Collaborations, LHC Higgs Combination Group	Procedure for the LHC Higgs boson search combination in Summer 2011	ATL-PHYS-PUB-2011-11, CMS NOTE 2011/005
75	LUX Collaboration	Improved Limits on Scattering of Weakly Interacting Massive Particles from Reanalysis of 2013 LUX Data	PRL 116 (2016) 161301	1512.03506
76	SuperCDMS Collaboration	New Results from the Search for Low-Mass Weakly Interacting Massive Particles with the CDMS Low Ionization Threshold Experiment	PRL 116 (2016) 071301	1509.02448
77	PandaX-II Collaboration	Dark Matter Results from First 98.7 Days of Data from the PandaX-II Experiment	PRL 117 (2016) 121303	1607.07400
78	CRESST Collaboration	Results on light dark matter particles with a low-threshold CRESST-II detector	EPJC 76 (2016) 25	1509.01515
79	Super-Kamiokande Collaboration	Search for neutrinos from annihilation of captured low-mass dark matter particles in the Sun by Super-Kamiokande	PRL 114 (2015) 141301	1503.04858
80	PICO Collaboration	Dark Matter Search Results from the PICO-60 C$ _3 $F$ _8 $ Bubble Chamber		1702.07666
81	IceCube Collaboration	Search for annihilating dark matter in the Sun with 3 years of IceCube data	EPJC 77 (2017) 146	1612.05949
82	IceCube Collaboration	Improved limits on dark matter annihilation in the Sun with the 79-string IceCube detector and implications for supersymmetry	JCAP 04 (2016) 022	1601.00653

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