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CMS-PAS-EXO-23-014
Search for long-lived particles decaying to a pair of muons in pp collisions at $ \sqrt{s}= $ 13.6 TeV with 2022 data
CMS Collaboration
23 August 2023
Abstract: An inclusive search for long-lived exotic particles decaying to a pair of muons is presented. The search uses data collected by the CMS experiment at the CERN LHC in proton-proton collisions at $ \sqrt{s}= $ 13.6 TeV in 2022 and corresponding to an integrated luminosity of 36.7 fb$ ^{-1} $. The experimental signature is a pair of oppositely charged muons originating from a common secondary vertex spatially separated from the pp interaction point by distances ranging from several hundred $ \mu $m to several meters. The results are interpreted in the frameworks of the hidden Abelian Higgs model, in which the Higgs boson decays to a pair of long-lived dark photons; and of an $ R $-parity violating supersymmetry model, in which long-lived neutralinos decay to a pair of muons and a neutrino. The results show substantial improvements as compared to the analysis performed using data taken at $ \sqrt{s}= $ 13 TeV, particularly at low masses and long lifetimes, mainly because of improved triggers for displaced muons and offline analysis refinements.
Links: CDS record (PDF) ; Physics Briefing ; CADI line (restricted) ;

These preliminary results are superseded in this paper, Accepted by JHEP.

The superseded preliminary plots can be found here.
Figures Summary Additional Figures References CMS Publications
Figures

png pdf 		Figure 1:
Feynman diagrams for (left) the HAHM model, showing the production of long-lived dark photons $ \mathrm{Z}\mathrm{_{D}} $ via the Higgs portal, through $\mathrm{H}$-$ \mathrm{H}\mathrm{_{D}} $ mixing with the parameter $ \kappa $, with subsequent decays to pairs of muons or other fermions via the vector portal; and (right) pair production of squarks followed by $ \tilde{\mathrm{q}} \to \mathrm{q} \tilde{\chi}_{1}^{0} $ decay, where the RPV neutralino is assumed to be a long-lived particle that decays into a neutrino and two charged leptons.

png pdf 		Figure 1-a:
Feynman diagrams for (left) the HAHM model, showing the production of long-lived dark photons $ \mathrm{Z}\mathrm{_{D}} $ via the Higgs portal, through $\mathrm{H}$-$ \mathrm{H}\mathrm{_{D}} $ mixing with the parameter $ \kappa $, with subsequent decays to pairs of muons or other fermions via the vector portal; and (right) pair production of squarks followed by $ \tilde{\mathrm{q}} \to \mathrm{q} \tilde{\chi}_{1}^{0} $ decay, where the RPV neutralino is assumed to be a long-lived particle that decays into a neutrino and two charged leptons.

png pdf 		Figure 1-b:
Feynman diagrams for (left) the HAHM model, showing the production of long-lived dark photons $ \mathrm{Z}\mathrm{_{D}} $ via the Higgs portal, through $\mathrm{H}$-$ \mathrm{H}\mathrm{_{D}} $ mixing with the parameter $ \kappa $, with subsequent decays to pairs of muons or other fermions via the vector portal; and (right) pair production of squarks followed by $ \tilde{\mathrm{q}} \to \mathrm{q} \tilde{\chi}_{1}^{0} $ decay, where the RPV neutralino is assumed to be a long-lived particle that decays into a neutrino and two charged leptons.

png pdf 		Figure 2:
The $ p_{\mathrm{T}} $ and $ d_{\mathrm{0}} $ coverage of the 2016 Run 2 triggers (light blue), 2018 Run 2 triggers (blue), and 2022 Run 3 triggers (red).

png pdf 		Figure 3:
Efficiencies of the Run 2 and Run 3 triggers as a function of $ c\tau $. The efficiency is defined as the fraction of simulated HAHM events with $ m(\mathrm{Z}\mathrm{_{D}}) = $ 20 GeV that satisfy the requirements of the following sets of trigger paths: the Run 2 (2018) triggers (dashed black); the Run 3 (2022, L3) triggers (blue); the Run 3 (2022, L2) triggers (red); and the OR of all Run 3 (2022) triggers (black). The lower panel shows the ratio of the overall Run 3 (2022) efficiency to the Run 2 (2018) efficiency.

png pdf 		Figure 4:
Distribution of $ |\Delta\Phi| $ for (left) TMS-TMS and (right) STA-STA dimuons passing the full selection except for a requirement on $ |\Delta\Phi| $ in all HAHM (blue) and RPV SUSY (orange) signal samples combined. All distributions are normalized to a unit area.

png pdf 		Figure 4-a:
Distribution of $ |\Delta\Phi| $ for (left) TMS-TMS and (right) STA-STA dimuons passing the full selection except for a requirement on $ |\Delta\Phi| $ in all HAHM (blue) and RPV SUSY (orange) signal samples combined. All distributions are normalized to a unit area.

png pdf 		Figure 4-b:
Distribution of $ |\Delta\Phi| $ for (left) TMS-TMS and (right) STA-STA dimuons passing the full selection except for a requirement on $ |\Delta\Phi| $ in all HAHM (blue) and RPV SUSY (orange) signal samples combined. All distributions are normalized to a unit area.

png pdf 		Figure 5:
Signal efficiencies in the TMS-TMS (red) and STA-STA (green) dimuon categories as well as their combination (black) as a function of $ c\tau $ for the HAHM signal with $ m(\mathrm{Z}\mathrm{_{D}})= $ 20 GeV. Solid curves show efficiencies achieved with the Run 3 triggers, whereas dashed curves show efficiencies for the subset of events selected by the triggers used in the 2018 Run 2 search. The efficiency is defined as the fraction of signal events that passed the criteria of the indicated trigger as well as the full set of offline selection criteria. The lower panel shows the relative improvement of the overall signal efficiency brought in by improvements in the trigger.

png pdf 		Figure 6:
Example of background prediction checks for STA-STA dimuons: (left) $ |\Delta\Phi| $ and (right) $ L_{\mathrm{xy}}/\sigma_{L_{\mathrm{xy}}} $ distributions for events with $ m_{\mu\mu} > $ 15 GeV in the $ L_{\mathrm{xy}}/\sigma_{L_{\mathrm{xy}}} < $ 6 VR in data (black circles), compared to the background predictions (histograms). The lower panels show the ratio of the observed to predicted number of events. Hatched histograms show the statistical uncertainty in the background prediction.

png pdf 		Figure 6-a:
Example of background prediction checks for STA-STA dimuons: (left) $ |\Delta\Phi| $ and (right) $ L_{\mathrm{xy}}/\sigma_{L_{\mathrm{xy}}} $ distributions for events with $ m_{\mu\mu} > $ 15 GeV in the $ L_{\mathrm{xy}}/\sigma_{L_{\mathrm{xy}}} < $ 6 VR in data (black circles), compared to the background predictions (histograms). The lower panels show the ratio of the observed to predicted number of events. Hatched histograms show the statistical uncertainty in the background prediction.

png pdf 		Figure 6-b:
Example of background prediction checks for STA-STA dimuons: (left) $ |\Delta\Phi| $ and (right) $ L_{\mathrm{xy}}/\sigma_{L_{\mathrm{xy}}} $ distributions for events with $ m_{\mu\mu} > $ 15 GeV in the $ L_{\mathrm{xy}}/\sigma_{L_{\mathrm{xy}}} < $ 6 VR in data (black circles), compared to the background predictions (histograms). The lower panels show the ratio of the observed to predicted number of events. Hatched histograms show the statistical uncertainty in the background prediction.

png pdf 		Figure 7:
Example of background prediction checks for TMS-TMS dimuons: $ L_{\mathrm{xy}}/\sigma_{L_{\mathrm{xy}}} $ distributions for events with (left) $ |\Delta\Phi| < \pi/ $ 4 and (right) $ |\Delta\Phi| < \pi/ $ 30 in the 2 $ < \text{min}(d_{\mathrm{0}}/\sigma_{d_{\mathrm{0}}}) < $ 6 VR, compared with the outcome of the background prediction method. The number of observed events (black circles) is overlaid with stacked histograms showing the expected numbers of QCD (yellow) and DY (green) background events. The last bin contains the overflow. The lower panels show the ratio of the observed to predicted number of events. Hatched histograms show the statistical uncertainty in the background prediction.

png pdf 		Figure 7-a:
Example of background prediction checks for TMS-TMS dimuons: $ L_{\mathrm{xy}}/\sigma_{L_{\mathrm{xy}}} $ distributions for events with (left) $ |\Delta\Phi| < \pi/ $ 4 and (right) $ |\Delta\Phi| < \pi/ $ 30 in the 2 $ < \text{min}(d_{\mathrm{0}}/\sigma_{d_{\mathrm{0}}}) < $ 6 VR, compared with the outcome of the background prediction method. The number of observed events (black circles) is overlaid with stacked histograms showing the expected numbers of QCD (yellow) and DY (green) background events. The last bin contains the overflow. The lower panels show the ratio of the observed to predicted number of events. Hatched histograms show the statistical uncertainty in the background prediction.

png pdf 		Figure 7-b:
Example of background prediction checks for TMS-TMS dimuons: $ L_{\mathrm{xy}}/\sigma_{L_{\mathrm{xy}}} $ distributions for events with (left) $ |\Delta\Phi| < \pi/ $ 4 and (right) $ |\Delta\Phi| < \pi/ $ 30 in the 2 $ < \text{min}(d_{\mathrm{0}}/\sigma_{d_{\mathrm{0}}}) < $ 6 VR, compared with the outcome of the background prediction method. The number of observed events (black circles) is overlaid with stacked histograms showing the expected numbers of QCD (yellow) and DY (green) background events. The last bin contains the overflow. The lower panels show the ratio of the observed to predicted number of events. Hatched histograms show the statistical uncertainty in the background prediction.

png pdf 		Figure 8:
Distributions of (left) $ |\Delta\Phi| $ and (right) dimuon invariant mass for STA-STA dimuons in the low-mass validation region (6 GeV $ < m_{\mu\mu} < $ 10 GeV) in data (black circles) compared to the background prediction (histograms). The lower panels show the ratio of the observed to predicted number of events. All uncertainties are statistical only.

png pdf 		Figure 8-a:
Distributions of (left) $ |\Delta\Phi| $ and (right) dimuon invariant mass for STA-STA dimuons in the low-mass validation region (6 GeV $ < m_{\mu\mu} < $ 10 GeV) in data (black circles) compared to the background prediction (histograms). The lower panels show the ratio of the observed to predicted number of events. All uncertainties are statistical only.

png pdf 		Figure 8-b:
Distributions of (left) $ |\Delta\Phi| $ and (right) dimuon invariant mass for STA-STA dimuons in the low-mass validation region (6 GeV $ < m_{\mu\mu} < $ 10 GeV) in data (black circles) compared to the background prediction (histograms). The lower panels show the ratio of the observed to predicted number of events. All uncertainties are statistical only.

png pdf 		Figure 9:
(left) Comparison of the number of TMS-TMS dimuons in data with the results of the background prediction method: (left) as a function of min($ d_{\mathrm{0}}/\sigma_{d_{\mathrm{0}}} $) for events in the $ \pi/4 < |\Delta\Phi| < \pi/ $ 2 VR; (right) as a function of $ m_{\mu\mu} $ for events in the 2 $ < \text{min}(d_{\mathrm{0}}/\sigma_{d_{\mathrm{0}}}) < $ 6 VR. The number of observed events (black circles) is overlaid with stacked histograms showing the expected numbers of QCD (yellow) and DY (green) background events. The last bin includes events in the overflow. The lower panels show the ratios of the observed to predicted number of events. Hatched histograms show the statistical uncertainty in the background prediction.

png pdf 		Figure 9-a:
(left) Comparison of the number of TMS-TMS dimuons in data with the results of the background prediction method: (left) as a function of min($ d_{\mathrm{0}}/\sigma_{d_{\mathrm{0}}} $) for events in the $ \pi/4 < |\Delta\Phi| < \pi/ $ 2 VR; (right) as a function of $ m_{\mu\mu} $ for events in the 2 $ < \text{min}(d_{\mathrm{0}}/\sigma_{d_{\mathrm{0}}}) < $ 6 VR. The number of observed events (black circles) is overlaid with stacked histograms showing the expected numbers of QCD (yellow) and DY (green) background events. The last bin includes events in the overflow. The lower panels show the ratios of the observed to predicted number of events. Hatched histograms show the statistical uncertainty in the background prediction.

png pdf 		Figure 9-b:
(left) Comparison of the number of TMS-TMS dimuons in data with the results of the background prediction method: (left) as a function of min($ d_{\mathrm{0}}/\sigma_{d_{\mathrm{0}}} $) for events in the $ \pi/4 < |\Delta\Phi| < \pi/ $ 2 VR; (right) as a function of $ m_{\mu\mu} $ for events in the 2 $ < \text{min}(d_{\mathrm{0}}/\sigma_{d_{\mathrm{0}}}) < $ 6 VR. The number of observed events (black circles) is overlaid with stacked histograms showing the expected numbers of QCD (yellow) and DY (green) background events. The last bin includes events in the overflow. The lower panels show the ratios of the observed to predicted number of events. Hatched histograms show the statistical uncertainty in the background prediction.

png pdf 		Figure 10:
Comparison of observed (black points) and expected (histograms) numbers of events in non-overlapping (left) $ m_{\mu\mu} $ and (right) $ m^\text{corr}_{\mu\mu} $ intervals in the STA-STA dimuon category, in the signal regions optimized for the (left) HAHM and (right) RPV SUSY model. Yellow and green stacked histograms represent mean expected background contributions from QCD and DY, respectively, while statistical uncertainties in the total expected background are shown as hatched histograms. Signal contributions expected from simulated signals indicated in the legends are shown in red and blue. Their yields are set to the corresponding median expected 95% CL exclusion limits obtained from the ensemble of both dimuon categories, scaled up as indicated in the legend to improve visibility. The last bin includes events in the overflow.

png pdf 		Figure 10-a:
Comparison of observed (black points) and expected (histograms) numbers of events in non-overlapping (left) $ m_{\mu\mu} $ and (right) $ m^\text{corr}_{\mu\mu} $ intervals in the STA-STA dimuon category, in the signal regions optimized for the (left) HAHM and (right) RPV SUSY model. Yellow and green stacked histograms represent mean expected background contributions from QCD and DY, respectively, while statistical uncertainties in the total expected background are shown as hatched histograms. Signal contributions expected from simulated signals indicated in the legends are shown in red and blue. Their yields are set to the corresponding median expected 95% CL exclusion limits obtained from the ensemble of both dimuon categories, scaled up as indicated in the legend to improve visibility. The last bin includes events in the overflow.

png pdf 		Figure 10-b:
Comparison of observed (black points) and expected (histograms) numbers of events in non-overlapping (left) $ m_{\mu\mu} $ and (right) $ m^\text{corr}_{\mu\mu} $ intervals in the STA-STA dimuon category, in the signal regions optimized for the (left) HAHM and (right) RPV SUSY model. Yellow and green stacked histograms represent mean expected background contributions from QCD and DY, respectively, while statistical uncertainties in the total expected background are shown as hatched histograms. Signal contributions expected from simulated signals indicated in the legends are shown in red and blue. Their yields are set to the corresponding median expected 95% CL exclusion limits obtained from the ensemble of both dimuon categories, scaled up as indicated in the legend to improve visibility. The last bin includes events in the overflow.

png pdf 		Figure 11:
Distributions of $ \text{min}(d_{\mathrm{0}}/\sigma_{d_{\mathrm{0}}}) $ for TMS-TMS dimuons with (left) $ |\Delta\Phi| < \pi/ $ 30 and (right) $ |\Delta\Phi| < \pi/ $ 4, for events in all mass intervals combined. The number of observed events (black circles) is overlaid with the stacked histograms showing the expected numbers of QCD (yellow) and DY (green) background events. Signal contributions expected from simulated signals indicated in the legends are shown in red and blue. Their yields are set to the corresponding median expected 95% CL exclusion limits obtained from the ensemble of both dimuon categories, scaled up as indicated in the legend to improve visibility. Events are required to satisfy all nominal selection criteria with the exception of the $ d_{\mathrm{0}}/\sigma_{d_{\mathrm{0}}} $ requirement. The last bin includes events in the overflow. All uncertainties shown are statistical only.

png pdf 		Figure 11-a:
Distributions of $ \text{min}(d_{\mathrm{0}}/\sigma_{d_{\mathrm{0}}}) $ for TMS-TMS dimuons with (left) $ |\Delta\Phi| < \pi/ $ 30 and (right) $ |\Delta\Phi| < \pi/ $ 4, for events in all mass intervals combined. The number of observed events (black circles) is overlaid with the stacked histograms showing the expected numbers of QCD (yellow) and DY (green) background events. Signal contributions expected from simulated signals indicated in the legends are shown in red and blue. Their yields are set to the corresponding median expected 95% CL exclusion limits obtained from the ensemble of both dimuon categories, scaled up as indicated in the legend to improve visibility. Events are required to satisfy all nominal selection criteria with the exception of the $ d_{\mathrm{0}}/\sigma_{d_{\mathrm{0}}} $ requirement. The last bin includes events in the overflow. All uncertainties shown are statistical only.

png pdf 		Figure 11-b:
Distributions of $ \text{min}(d_{\mathrm{0}}/\sigma_{d_{\mathrm{0}}}) $ for TMS-TMS dimuons with (left) $ |\Delta\Phi| < \pi/ $ 30 and (right) $ |\Delta\Phi| < \pi/ $ 4, for events in all mass intervals combined. The number of observed events (black circles) is overlaid with the stacked histograms showing the expected numbers of QCD (yellow) and DY (green) background events. Signal contributions expected from simulated signals indicated in the legends are shown in red and blue. Their yields are set to the corresponding median expected 95% CL exclusion limits obtained from the ensemble of both dimuon categories, scaled up as indicated in the legend to improve visibility. Events are required to satisfy all nominal selection criteria with the exception of the $ d_{\mathrm{0}}/\sigma_{d_{\mathrm{0}}} $ requirement. The last bin includes events in the overflow. All uncertainties shown are statistical only.

png pdf 		Figure 12:
Comparison of observed and expected numbers of events in the TMS-TMS dimuon category, in the RPV SUSY study that requires $ |\Delta\Phi| < \pi/ $ 4, in bins of $ m^\text{corr}_{\mu\mu} $. The number of observed events (black circles) is overlaid with the stacked histograms showing the expected numbers of QCD (yellow) and DY (green) background events in bins of $ m^\text{corr}_{\mu\mu} $ in three min($ d_{\mathrm{0}}/\sigma_{d_{\mathrm{0}}} $) bins: (left) 6-10, (center) 10-20, and (right) $ > $ 20. Contributions expected from signal events predicted by the RPV SUSY model with the parameters indicated in the legends are shown as red and blue histograms. Their yields are set to the corresponding median expected 95% CL exclusion limits obtained from the ensemble of both dimuon categories, scaled up as indicated in the legend to improve visibility. The last bin includes events in the overflow. All uncertainties shown are statistical only.

png pdf 		Figure 13:
Comparison of observed and expected numbers of events in the TMS-TMS dimuon category, in the HAHM study that requires $ |\Delta\Phi| < \pi/ $ 30, in bins of $ m_{\mu\mu} $. The number of observed events (black circles) is overlaid with the stacked histograms showing the expected numbers of QCD (yellow) and DY (green) background events in bins of $ m_{\mu\mu} $ in three min($ d_{\mathrm{0}}/\sigma_{d_{\mathrm{0}}} $) bins: (left) 6-10, (center) 10-20, and (right) $ > $ 20. Signal contributions expected from simulated $ \mathrm{H} \to \mathrm{Z}\mathrm{_{D}} \mathrm{Z}\mathrm{_{D}} $ events with the parameters indicated in the legends are shown as red and blue histograms. Their yields are set to the corresponding median expected 95% CL exclusion limits obtained from the ensemble of both dimuon categories, scaled up as indicated in the legend to improve visibility. The last bin includes events in the overflow. All uncertainties shown are statistical only.

png pdf 		Figure 14:
The 95% CL upper limits on $ \mathcal{B}(\mathrm{H} \to \mathrm{Z}\mathrm{_{D}} \mathrm{Z}\mathrm{_{D}}) $ as a function of $ c\tau(\mathrm{Z}\mathrm{_{D}}) $ in the HAHM model, for $ m(\mathrm{Z}\mathrm{_{D}}) $ ranging from (upper left) 10 GeV to (lower right) 60 GeV, in the STA-STA and TMS-TMS dimuon categories in 2022 data and their combination. The median expected limits obtained from the STA-STA and TMS-TMS dimuon categories are shown as dashed blue and red curves, respectively; the combined median expected limits are shown as dashed black curves; and the combined observed limits are shown as solid black curves. The green and yellow bands correspond, respectively, to the 68 and 95% quantiles for the combined expected limits.

png pdf 		Figure 14-a:
The 95% CL upper limits on $ \mathcal{B}(\mathrm{H} \to \mathrm{Z}\mathrm{_{D}} \mathrm{Z}\mathrm{_{D}}) $ as a function of $ c\tau(\mathrm{Z}\mathrm{_{D}}) $ in the HAHM model, for $ m(\mathrm{Z}\mathrm{_{D}}) $ ranging from (upper left) 10 GeV to (lower right) 60 GeV, in the STA-STA and TMS-TMS dimuon categories in 2022 data and their combination. The median expected limits obtained from the STA-STA and TMS-TMS dimuon categories are shown as dashed blue and red curves, respectively; the combined median expected limits are shown as dashed black curves; and the combined observed limits are shown as solid black curves. The green and yellow bands correspond, respectively, to the 68 and 95% quantiles for the combined expected limits.

png pdf 		Figure 14-b:
The 95% CL upper limits on $ \mathcal{B}(\mathrm{H} \to \mathrm{Z}\mathrm{_{D}} \mathrm{Z}\mathrm{_{D}}) $ as a function of $ c\tau(\mathrm{Z}\mathrm{_{D}}) $ in the HAHM model, for $ m(\mathrm{Z}\mathrm{_{D}}) $ ranging from (upper left) 10 GeV to (lower right) 60 GeV, in the STA-STA and TMS-TMS dimuon categories in 2022 data and their combination. The median expected limits obtained from the STA-STA and TMS-TMS dimuon categories are shown as dashed blue and red curves, respectively; the combined median expected limits are shown as dashed black curves; and the combined observed limits are shown as solid black curves. The green and yellow bands correspond, respectively, to the 68 and 95% quantiles for the combined expected limits.

png pdf 		Figure 14-c:
The 95% CL upper limits on $ \mathcal{B}(\mathrm{H} \to \mathrm{Z}\mathrm{_{D}} \mathrm{Z}\mathrm{_{D}}) $ as a function of $ c\tau(\mathrm{Z}\mathrm{_{D}}) $ in the HAHM model, for $ m(\mathrm{Z}\mathrm{_{D}}) $ ranging from (upper left) 10 GeV to (lower right) 60 GeV, in the STA-STA and TMS-TMS dimuon categories in 2022 data and their combination. The median expected limits obtained from the STA-STA and TMS-TMS dimuon categories are shown as dashed blue and red curves, respectively; the combined median expected limits are shown as dashed black curves; and the combined observed limits are shown as solid black curves. The green and yellow bands correspond, respectively, to the 68 and 95% quantiles for the combined expected limits.

png pdf 		Figure 14-d:
The 95% CL upper limits on $ \mathcal{B}(\mathrm{H} \to \mathrm{Z}\mathrm{_{D}} \mathrm{Z}\mathrm{_{D}}) $ as a function of $ c\tau(\mathrm{Z}\mathrm{_{D}}) $ in the HAHM model, for $ m(\mathrm{Z}\mathrm{_{D}}) $ ranging from (upper left) 10 GeV to (lower right) 60 GeV, in the STA-STA and TMS-TMS dimuon categories in 2022 data and their combination. The median expected limits obtained from the STA-STA and TMS-TMS dimuon categories are shown as dashed blue and red curves, respectively; the combined median expected limits are shown as dashed black curves; and the combined observed limits are shown as solid black curves. The green and yellow bands correspond, respectively, to the 68 and 95% quantiles for the combined expected limits.

png pdf 		Figure 14-e:
The 95% CL upper limits on $ \mathcal{B}(\mathrm{H} \to \mathrm{Z}\mathrm{_{D}} \mathrm{Z}\mathrm{_{D}}) $ as a function of $ c\tau(\mathrm{Z}\mathrm{_{D}}) $ in the HAHM model, for $ m(\mathrm{Z}\mathrm{_{D}}) $ ranging from (upper left) 10 GeV to (lower right) 60 GeV, in the STA-STA and TMS-TMS dimuon categories in 2022 data and their combination. The median expected limits obtained from the STA-STA and TMS-TMS dimuon categories are shown as dashed blue and red curves, respectively; the combined median expected limits are shown as dashed black curves; and the combined observed limits are shown as solid black curves. The green and yellow bands correspond, respectively, to the 68 and 95% quantiles for the combined expected limits.

png pdf 		Figure 14-f:
The 95% CL upper limits on $ \mathcal{B}(\mathrm{H} \to \mathrm{Z}\mathrm{_{D}} \mathrm{Z}\mathrm{_{D}}) $ as a function of $ c\tau(\mathrm{Z}\mathrm{_{D}}) $ in the HAHM model, for $ m(\mathrm{Z}\mathrm{_{D}}) $ ranging from (upper left) 10 GeV to (lower right) 60 GeV, in the STA-STA and TMS-TMS dimuon categories in 2022 data and their combination. The median expected limits obtained from the STA-STA and TMS-TMS dimuon categories are shown as dashed blue and red curves, respectively; the combined median expected limits are shown as dashed black curves; and the combined observed limits are shown as solid black curves. The green and yellow bands correspond, respectively, to the 68 and 95% quantiles for the combined expected limits.

png pdf 		Figure 15:
The 95% CL upper limits on $ \mathcal{B}(\mathrm{H} \to \mathrm{Z}\mathrm{_{D}} \mathrm{Z}\mathrm{_{D}}) $ as a function of $ c\tau(\mathrm{Z}\mathrm{_{D}}) $ in the HAHM model, for $ m(\mathrm{Z}\mathrm{_{D}}) $ ranging from (upper left) 10 GeV to (lower right) 60 GeV, obtained in this analysis, the Run 2 analysis [6], and their combination. The observed limits in this analysis and in the Run 2 analysis [6] are shown as blue and red curves, respectively; the combined expected limits are shown as dashed black curves; and the combined observed limits are shown as solid black curves. The green and yellow bands correspond, respectively, to the 68 and 95% quantiles for the combined expected limits.

png pdf 		Figure 15-a:
The 95% CL upper limits on $ \mathcal{B}(\mathrm{H} \to \mathrm{Z}\mathrm{_{D}} \mathrm{Z}\mathrm{_{D}}) $ as a function of $ c\tau(\mathrm{Z}\mathrm{_{D}}) $ in the HAHM model, for $ m(\mathrm{Z}\mathrm{_{D}}) $ ranging from (upper left) 10 GeV to (lower right) 60 GeV, obtained in this analysis, the Run 2 analysis [6], and their combination. The observed limits in this analysis and in the Run 2 analysis [6] are shown as blue and red curves, respectively; the combined expected limits are shown as dashed black curves; and the combined observed limits are shown as solid black curves. The green and yellow bands correspond, respectively, to the 68 and 95% quantiles for the combined expected limits.

png pdf 		Figure 15-b:
The 95% CL upper limits on $ \mathcal{B}(\mathrm{H} \to \mathrm{Z}\mathrm{_{D}} \mathrm{Z}\mathrm{_{D}}) $ as a function of $ c\tau(\mathrm{Z}\mathrm{_{D}}) $ in the HAHM model, for $ m(\mathrm{Z}\mathrm{_{D}}) $ ranging from (upper left) 10 GeV to (lower right) 60 GeV, obtained in this analysis, the Run 2 analysis [6], and their combination. The observed limits in this analysis and in the Run 2 analysis [6] are shown as blue and red curves, respectively; the combined expected limits are shown as dashed black curves; and the combined observed limits are shown as solid black curves. The green and yellow bands correspond, respectively, to the 68 and 95% quantiles for the combined expected limits.

png pdf 		Figure 15-c:
The 95% CL upper limits on $ \mathcal{B}(\mathrm{H} \to \mathrm{Z}\mathrm{_{D}} \mathrm{Z}\mathrm{_{D}}) $ as a function of $ c\tau(\mathrm{Z}\mathrm{_{D}}) $ in the HAHM model, for $ m(\mathrm{Z}\mathrm{_{D}}) $ ranging from (upper left) 10 GeV to (lower right) 60 GeV, obtained in this analysis, the Run 2 analysis [6], and their combination. The observed limits in this analysis and in the Run 2 analysis [6] are shown as blue and red curves, respectively; the combined expected limits are shown as dashed black curves; and the combined observed limits are shown as solid black curves. The green and yellow bands correspond, respectively, to the 68 and 95% quantiles for the combined expected limits.

png pdf 		Figure 15-d:
The 95% CL upper limits on $ \mathcal{B}(\mathrm{H} \to \mathrm{Z}\mathrm{_{D}} \mathrm{Z}\mathrm{_{D}}) $ as a function of $ c\tau(\mathrm{Z}\mathrm{_{D}}) $ in the HAHM model, for $ m(\mathrm{Z}\mathrm{_{D}}) $ ranging from (upper left) 10 GeV to (lower right) 60 GeV, obtained in this analysis, the Run 2 analysis [6], and their combination. The observed limits in this analysis and in the Run 2 analysis [6] are shown as blue and red curves, respectively; the combined expected limits are shown as dashed black curves; and the combined observed limits are shown as solid black curves. The green and yellow bands correspond, respectively, to the 68 and 95% quantiles for the combined expected limits.

png pdf 		Figure 15-e:
The 95% CL upper limits on $ \mathcal{B}(\mathrm{H} \to \mathrm{Z}\mathrm{_{D}} \mathrm{Z}\mathrm{_{D}}) $ as a function of $ c\tau(\mathrm{Z}\mathrm{_{D}}) $ in the HAHM model, for $ m(\mathrm{Z}\mathrm{_{D}}) $ ranging from (upper left) 10 GeV to (lower right) 60 GeV, obtained in this analysis, the Run 2 analysis [6], and their combination. The observed limits in this analysis and in the Run 2 analysis [6] are shown as blue and red curves, respectively; the combined expected limits are shown as dashed black curves; and the combined observed limits are shown as solid black curves. The green and yellow bands correspond, respectively, to the 68 and 95% quantiles for the combined expected limits.

png pdf 		Figure 15-f:
The 95% CL upper limits on $ \mathcal{B}(\mathrm{H} \to \mathrm{Z}\mathrm{_{D}} \mathrm{Z}\mathrm{_{D}}) $ as a function of $ c\tau(\mathrm{Z}\mathrm{_{D}}) $ in the HAHM model, for $ m(\mathrm{Z}\mathrm{_{D}}) $ ranging from (upper left) 10 GeV to (lower right) 60 GeV, obtained in this analysis, the Run 2 analysis [6], and their combination. The observed limits in this analysis and in the Run 2 analysis [6] are shown as blue and red curves, respectively; the combined expected limits are shown as dashed black curves; and the combined observed limits are shown as solid black curves. The green and yellow bands correspond, respectively, to the 68 and 95% quantiles for the combined expected limits.

png pdf 		Figure 16:
The 95% CL upper limits on $ \sigma({ \tilde{\mathrm{q}} \to \mathrm{q} \tilde{\chi}_{1}^{0} } ) $ as a function of $ c\tau(\tilde{\chi}_{1}^{0}) $ in the RPV SUSY model, for $ \mathcal{B}({ \tilde{\chi}_{1}^{0} $\to$ \mu \mu \nu } ) = $ 0.5 and various combinations of $ m(\tilde{\mathrm{q}}) $ and $ m(\tilde{\chi}_{1}^{0}) $ indicated in the legends. The median expected limits obtained from the STA-STA and TMS-TMS dimuon categories are shown as dashed blue and red curves, respectively; the median expected limits in the ensemble of both categories are shown as dashed black curves; and the observed limits in the ensemble of both categories are shown as solid black curves. The green and yellow bands correspond, respectively, to the 68 and 95% quantiles for the expected limits in the ensemble of both categories.

png pdf 		Figure 16-a:
The 95% CL upper limits on $ \sigma({ \tilde{\mathrm{q}} \to \mathrm{q} \tilde{\chi}_{1}^{0} } ) $ as a function of $ c\tau(\tilde{\chi}_{1}^{0}) $ in the RPV SUSY model, for $ \mathcal{B}({ \tilde{\chi}_{1}^{0} $\to$ \mu \mu \nu } ) = $ 0.5 and various combinations of $ m(\tilde{\mathrm{q}}) $ and $ m(\tilde{\chi}_{1}^{0}) $ indicated in the legends. The median expected limits obtained from the STA-STA and TMS-TMS dimuon categories are shown as dashed blue and red curves, respectively; the median expected limits in the ensemble of both categories are shown as dashed black curves; and the observed limits in the ensemble of both categories are shown as solid black curves. The green and yellow bands correspond, respectively, to the 68 and 95% quantiles for the expected limits in the ensemble of both categories.

png pdf 		Figure 16-b:
The 95% CL upper limits on $ \sigma({ \tilde{\mathrm{q}} \to \mathrm{q} \tilde{\chi}_{1}^{0} } ) $ as a function of $ c\tau(\tilde{\chi}_{1}^{0}) $ in the RPV SUSY model, for $ \mathcal{B}({ \tilde{\chi}_{1}^{0} $\to$ \mu \mu \nu } ) = $ 0.5 and various combinations of $ m(\tilde{\mathrm{q}}) $ and $ m(\tilde{\chi}_{1}^{0}) $ indicated in the legends. The median expected limits obtained from the STA-STA and TMS-TMS dimuon categories are shown as dashed blue and red curves, respectively; the median expected limits in the ensemble of both categories are shown as dashed black curves; and the observed limits in the ensemble of both categories are shown as solid black curves. The green and yellow bands correspond, respectively, to the 68 and 95% quantiles for the expected limits in the ensemble of both categories.

png pdf 		Figure 16-c:
The 95% CL upper limits on $ \sigma({ \tilde{\mathrm{q}} \to \mathrm{q} \tilde{\chi}_{1}^{0} } ) $ as a function of $ c\tau(\tilde{\chi}_{1}^{0}) $ in the RPV SUSY model, for $ \mathcal{B}({ \tilde{\chi}_{1}^{0} $\to$ \mu \mu \nu } ) = $ 0.5 and various combinations of $ m(\tilde{\mathrm{q}}) $ and $ m(\tilde{\chi}_{1}^{0}) $ indicated in the legends. The median expected limits obtained from the STA-STA and TMS-TMS dimuon categories are shown as dashed blue and red curves, respectively; the median expected limits in the ensemble of both categories are shown as dashed black curves; and the observed limits in the ensemble of both categories are shown as solid black curves. The green and yellow bands correspond, respectively, to the 68 and 95% quantiles for the expected limits in the ensemble of both categories.
Summary
Data collected by the CMS experiment in proton-proton collisions at $ \sqrt{s} = $ 13.6 TeV in 2022 and corresponding to an integrated luminosity of 36.7 fb$ ^{-1} $ have been used to conduct an inclusive search for long-lived exotic neutral particles (LLPs) decaying to a pair of oppositely charged muons. The search is largely model-independent and is sensitive to a broad range of LLP lifetimes and masses. No significant excess of events above the standard model background is observed. The results are interpreted as limits on the parameters of the hidden Abelian Higgs model, in which the Higgs boson decays to a pair of long-lived dark photons $ \mathrm{Z}\mathrm{_{D}} $, and of an $ R $-parity violating SUSY model, in which long-lived neutralinos decay to a pair of muons and a neutrino. Even though the size of the data sample used by this analysis is a factor of 2.5 smaller than that in the search for displaced dimuons in pp collisions at $ \sqrt{s} = $ 13 TeV, the constraints on the parameters of the HAHM model are comparable or tighter in a significant fraction of the parameter space, thanks mainly to recent improvements in the trigger algorithms for displaced muons. The combination of the results of this analysis with the results obtained at $ \sqrt{s} = $ 13 TeV improves the constraints on a branching fraction of the Higgs boson to dark photons $ \mathcal{B}(\mathrm{H} \to \mathrm{Z}\mathrm{_{D}} \mathrm{Z}\mathrm{_{D}}) $ by approximately a factor of 2. In the $ m(\mathrm{Z}\mathrm{_{D}}) $ range of 10-60 GeV, $ \mathcal{B}(\mathrm{H} \to \mathrm{Z}\mathrm{_{D}} \mathrm{Z}\mathrm{_{D}}) $ of 1% is excluded at 95% confidence level in the range of proper decay length $ c\tau(\mathrm{Z}\mathrm{_{D}}) $ from a few tens of $\mu$m to 30 m (at $ m(\mathrm{Z}\mathrm{_{D}}) $ = 10 GeV) and 700 m (at $ m(\mathrm{Z}\mathrm{_{D}}) $ = 60 GeV). For $ m(\mathrm{Z}\mathrm{_{D}}) $ greater than 20 GeV and less than $ m(\mathrm{H})/ $ 2, the combined limits provide the best limits to date on $ \mathcal{B}(\mathrm{H} \to \mathrm{Z}\mathrm{_{D}} \mathrm{Z}\mathrm{_{D}}) $ for $ c\tau(\mathrm{Z}\mathrm{_{D}}) $ (varying with $ m(\mathrm{Z}\mathrm{_{D}}) $) between 300 $\mu$m and $ {\approx}$0.1cm, and above $ {\approx}$10 cm.
Additional Figures

png pdf 		Additional Figure 1:
Fractions of signal events with zero (green), one (blue), and two (red) STA muons matched to TMS muons by the STA to TMS association procedure, as a function of generated $ L_{\mathrm{xy}} $, in all HAHM signal samples combined.

png pdf 		Additional Figure 2:
Efficiencies of the Run 2 and Run 3 triggers as a function of $ c\tau $. The efficiency is defined as the fraction of simulated HAHM events with $ m(\mathrm{Z}\mathrm{_{D}}) = $ 50 GeV that satisfy the requirements of the following sets of trigger paths: the Run 2 (2018) triggers (dashed black); the Run 3 (2022, L3) triggers (blue); the Run 3 (2022, L2) triggers (red); and the OR of all Run 3 (2022) triggers (black). The lower panel shows the ratio of the overall Run 3 (2022) efficiency to the Run 2 (2018) efficiency.

png pdf 		Additional Figure 3:
Trigger efficiency (black), defined as the fraction of events recorded by the triggers based on the information from jets and missing transverse energy that also satisfy the requirements of the Run 3 (2022, L3) triggers, as a function of min($ p_{\mathrm{T}} $) (upper left), max($ p_{\mathrm{T}} $) (upper right), and min($ d_{\mathrm{0}} $) (lower) in events enriched in $ {\mathrm{J}/\psi} \to\mu\mu $. Efficiencies in data are compared to efficiencies from a combination of simulated samples of non-prompt $ {\mathrm{J}/\psi} \to\mu\mu $ produced in B hadron decays (yellow).

png pdf 		Additional Figure 3-a:
Trigger efficiency (black), defined as the fraction of events recorded by the triggers based on the information from jets and missing transverse energy that also satisfy the requirements of the Run 3 (2022, L3) triggers, as a function of min($ p_{\mathrm{T}} $) (upper left), max($ p_{\mathrm{T}} $) (upper right), and min($ d_{\mathrm{0}} $) (lower) in events enriched in $ {\mathrm{J}/\psi} \to\mu\mu $. Efficiencies in data are compared to efficiencies from a combination of simulated samples of non-prompt $ {\mathrm{J}/\psi} \to\mu\mu $ produced in B hadron decays (yellow).

png pdf 		Additional Figure 3-b:
Trigger efficiency (black), defined as the fraction of events recorded by the triggers based on the information from jets and missing transverse energy that also satisfy the requirements of the Run 3 (2022, L3) triggers, as a function of min($ p_{\mathrm{T}} $) (upper left), max($ p_{\mathrm{T}} $) (upper right), and min($ d_{\mathrm{0}} $) (lower) in events enriched in $ {\mathrm{J}/\psi} \to\mu\mu $. Efficiencies in data are compared to efficiencies from a combination of simulated samples of non-prompt $ {\mathrm{J}/\psi} \to\mu\mu $ produced in B hadron decays (yellow).

png pdf 		Additional Figure 3-c:
Trigger efficiency (black), defined as the fraction of events recorded by the triggers based on the information from jets and missing transverse energy that also satisfy the requirements of the Run 3 (2022, L3) triggers, as a function of min($ p_{\mathrm{T}} $) (upper left), max($ p_{\mathrm{T}} $) (upper right), and min($ d_{\mathrm{0}} $) (lower) in events enriched in $ {\mathrm{J}/\psi} \to\mu\mu $. Efficiencies in data are compared to efficiencies from a combination of simulated samples of non-prompt $ {\mathrm{J}/\psi} \to\mu\mu $ produced in B hadron decays (yellow).

png pdf 		Additional Figure 4:
Left: Invariant mass distribution for TMS-TMS dimuons with $ L_{\mathrm{xy}}/\sigma_{L_{\mathrm{xy}}} < $ 1 in events recorded by the Run 2 (2018) triggers in 2022 data (black), and in the subset of events also selected by the Run 3 (2022, L3) triggers (blue), illustrating the background rejection of the Run 3 (2022, L3) triggers. Right: Trigger efficiency, defined as the fraction of events recorded by the Run 2 (2018) triggers that also satisfied the requirements of the Run 3 (2022, L3) triggers, as a function of offline-reconstructed min($ d_{\mathrm{0}} $) for TMS-TMS dimuons in events enriched in $ {\mathrm{J}/\psi} \to\mu\mu $. Different symbols show efficiencies in different periods of the 2022 data taking corresponding to the integrated luminosities indicated in the legend. For dimuons with offline $ \text{min}(d_{\mathrm{0}}) > $ 0.012 cm, the combined efficiency of the L3 muon reconstruction and the online min($ d_{\mathrm{0}} $) requirement is larger than 90% in all data taking periods.

png pdf 		Additional Figure 4-a:
Left: Invariant mass distribution for TMS-TMS dimuons with $ L_{\mathrm{xy}}/\sigma_{L_{\mathrm{xy}}} < $ 1 in events recorded by the Run 2 (2018) triggers in 2022 data (black), and in the subset of events also selected by the Run 3 (2022, L3) triggers (blue), illustrating the background rejection of the Run 3 (2022, L3) triggers. Right: Trigger efficiency, defined as the fraction of events recorded by the Run 2 (2018) triggers that also satisfied the requirements of the Run 3 (2022, L3) triggers, as a function of offline-reconstructed min($ d_{\mathrm{0}} $) for TMS-TMS dimuons in events enriched in $ {\mathrm{J}/\psi} \to\mu\mu $. Different symbols show efficiencies in different periods of the 2022 data taking corresponding to the integrated luminosities indicated in the legend. For dimuons with offline $ \text{min}(d_{\mathrm{0}}) > $ 0.012 cm, the combined efficiency of the L3 muon reconstruction and the online min($ d_{\mathrm{0}} $) requirement is larger than 90% in all data taking periods.

png pdf 		Additional Figure 4-b:
Left: Invariant mass distribution for TMS-TMS dimuons with $ L_{\mathrm{xy}}/\sigma_{L_{\mathrm{xy}}} < $ 1 in events recorded by the Run 2 (2018) triggers in 2022 data (black), and in the subset of events also selected by the Run 3 (2022, L3) triggers (blue), illustrating the background rejection of the Run 3 (2022, L3) triggers. Right: Trigger efficiency, defined as the fraction of events recorded by the Run 2 (2018) triggers that also satisfied the requirements of the Run 3 (2022, L3) triggers, as a function of offline-reconstructed min($ d_{\mathrm{0}} $) for TMS-TMS dimuons in events enriched in $ {\mathrm{J}/\psi} \to\mu\mu $. Different symbols show efficiencies in different periods of the 2022 data taking corresponding to the integrated luminosities indicated in the legend. For dimuons with offline $ \text{min}(d_{\mathrm{0}}) > $ 0.012 cm, the combined efficiency of the L3 muon reconstruction and the online min($ d_{\mathrm{0}} $) requirement is larger than 90% in all data taking periods.

png pdf 		Additional Figure 5:
Left: Invariant mass distribution of TMS-TMS dimuons in events recorded by the Run 2 (2018) triggers in 2022 data (black), and in the subset of events also selected by the Run 3 (2022, L2) triggers (pink), illustrating the background rejection of the Run 3 (2022, L2) triggers. Right: Trigger efficiency, defined as the fraction of events recorded by the Run 2 (2018) triggers that also satisfied the requirements of the Run 3 (2022, L2) triggers, as a function of offline-reconstructed min($ d_{\mathrm{0}} $) for STA-STA dimuons in events enriched in cosmic ray muons. Different symbols show efficiencies in different periods of the 2022 data taking corresponding to the integrated luminosities indicated in the legend. For displaced muons, the efficiency of the online min($ d_{\mathrm{0}} $) requirement is larger than 95% in all data taking periods.

png pdf 		Additional Figure 5-a:
Left: Invariant mass distribution of TMS-TMS dimuons in events recorded by the Run 2 (2018) triggers in 2022 data (black), and in the subset of events also selected by the Run 3 (2022, L2) triggers (pink), illustrating the background rejection of the Run 3 (2022, L2) triggers. Right: Trigger efficiency, defined as the fraction of events recorded by the Run 2 (2018) triggers that also satisfied the requirements of the Run 3 (2022, L2) triggers, as a function of offline-reconstructed min($ d_{\mathrm{0}} $) for STA-STA dimuons in events enriched in cosmic ray muons. Different symbols show efficiencies in different periods of the 2022 data taking corresponding to the integrated luminosities indicated in the legend. For displaced muons, the efficiency of the online min($ d_{\mathrm{0}} $) requirement is larger than 95% in all data taking periods.

png pdf 		Additional Figure 5-b:
Left: Invariant mass distribution of TMS-TMS dimuons in events recorded by the Run 2 (2018) triggers in 2022 data (black), and in the subset of events also selected by the Run 3 (2022, L2) triggers (pink), illustrating the background rejection of the Run 3 (2022, L2) triggers. Right: Trigger efficiency, defined as the fraction of events recorded by the Run 2 (2018) triggers that also satisfied the requirements of the Run 3 (2022, L2) triggers, as a function of offline-reconstructed min($ d_{\mathrm{0}} $) for STA-STA dimuons in events enriched in cosmic ray muons. Different symbols show efficiencies in different periods of the 2022 data taking corresponding to the integrated luminosities indicated in the legend. For displaced muons, the efficiency of the online min($ d_{\mathrm{0}} $) requirement is larger than 95% in all data taking periods.

png pdf 		Additional Figure 6:
Distributions of (left) $ m_{\mu\mu} $ and (right) $ m^\text{corr}_{\mu\mu} $ in the TMS-TMS dimuon category, for simulated signal events with $ m(\tilde{q}) = $ 125 GeV and $ m(\tilde{\chi}^{0}_{1}) = $ 50 GeV in the RPV SUSY model.

png pdf 		Additional Figure 6-a:
Distributions of (left) $ m_{\mu\mu} $ and (right) $ m^\text{corr}_{\mu\mu} $ in the TMS-TMS dimuon category, for simulated signal events with $ m(\tilde{q}) = $ 125 GeV and $ m(\tilde{\chi}^{0}_{1}) = $ 50 GeV in the RPV SUSY model.

png pdf 		Additional Figure 6-b:
Distributions of (left) $ m_{\mu\mu} $ and (right) $ m^\text{corr}_{\mu\mu} $ in the TMS-TMS dimuon category, for simulated signal events with $ m(\tilde{q}) = $ 125 GeV and $ m(\tilde{\chi}^{0}_{1}) = $ 50 GeV in the RPV SUSY model.

png pdf 		Additional Figure 7:
Observed (solid) and expected (dashed) 95% CL upper limits on $ \sigma( \tilde{\mathrm{q}} \to \mathrm{q} \tilde{\chi}^{0}_{1} ) $ as a function of $ c\tau(\tilde{\chi}^{0}_{1}) $ for $ \mathcal{B}( \tilde{\chi}^{0}_{1} \to \mu \mu \nu ) = $ 0.5 in the RPV SUSY model, for various combinations of $ m(\tilde{q}) $ and $ m(\tilde{\chi}^{0}_{1}) $ indicated in the legends. The limits obtained in this analysis (black) are compared with the corresponding limits in the analysis of Run 1 data rescaled by the ratio of $ \sigma( \tilde{q} \to \mathrm{q} \tilde{\chi}^{0}_{1} ) $ at 13 TeV and 8 TeV (red).

png pdf 		Additional Figure 7-a:
Observed (solid) and expected (dashed) 95% CL upper limits on $ \sigma( \tilde{\mathrm{q}} \to \mathrm{q} \tilde{\chi}^{0}_{1} ) $ as a function of $ c\tau(\tilde{\chi}^{0}_{1}) $ for $ \mathcal{B}( \tilde{\chi}^{0}_{1} \to \mu \mu \nu ) = $ 0.5 in the RPV SUSY model, for various combinations of $ m(\tilde{q}) $ and $ m(\tilde{\chi}^{0}_{1}) $ indicated in the legends. The limits obtained in this analysis (black) are compared with the corresponding limits in the analysis of Run 1 data rescaled by the ratio of $ \sigma( \tilde{q} \to \mathrm{q} \tilde{\chi}^{0}_{1} ) $ at 13 TeV and 8 TeV (red).

png pdf 		Additional Figure 7-b:
Observed (solid) and expected (dashed) 95% CL upper limits on $ \sigma( \tilde{\mathrm{q}} \to \mathrm{q} \tilde{\chi}^{0}_{1} ) $ as a function of $ c\tau(\tilde{\chi}^{0}_{1}) $ for $ \mathcal{B}( \tilde{\chi}^{0}_{1} \to \mu \mu \nu ) = $ 0.5 in the RPV SUSY model, for various combinations of $ m(\tilde{q}) $ and $ m(\tilde{\chi}^{0}_{1}) $ indicated in the legends. The limits obtained in this analysis (black) are compared with the corresponding limits in the analysis of Run 1 data rescaled by the ratio of $ \sigma( \tilde{q} \to \mathrm{q} \tilde{\chi}^{0}_{1} ) $ at 13 TeV and 8 TeV (red).

png pdf 		Additional Figure 7-c:
Observed (solid) and expected (dashed) 95% CL upper limits on $ \sigma( \tilde{\mathrm{q}} \to \mathrm{q} \tilde{\chi}^{0}_{1} ) $ as a function of $ c\tau(\tilde{\chi}^{0}_{1}) $ for $ \mathcal{B}( \tilde{\chi}^{0}_{1} \to \mu \mu \nu ) = $ 0.5 in the RPV SUSY model, for various combinations of $ m(\tilde{q}) $ and $ m(\tilde{\chi}^{0}_{1}) $ indicated in the legends. The limits obtained in this analysis (black) are compared with the corresponding limits in the analysis of Run 1 data rescaled by the ratio of $ \sigma( \tilde{q} \to \mathrm{q} \tilde{\chi}^{0}_{1} ) $ at 13 TeV and 8 TeV (red).
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