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| CMS-PAS-EXO-16-017 | ||
| Search for dark matter in association with a boosted top quark in the hadronic final state at $\sqrt{s}= $ 13 TeV | ||
| CMS Collaboration | ||
| June 2016 | ||
| Abstract: A search for dark matter is conducted in events with large missing transverse energy and a hadronically decaying, boosted top quark. This study is performed using proton-proton collision data collected by the CMS detector, corresponding to an integrated luminosity of 2.3 fb$^{-1}$. No significant deviations from standard model predictions are observed and limits are placed on the production of inivisible bosons coupling to dark matter particles. | ||
| Links: CDS record (PDF) ; inSPIRE record ; CADI line (restricted) ; | ||
| Figures | |
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Figure 1:
Example of monotop production via a neutral flavor-changing current. |
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Figure 2-a:
Comparison between data and Monte Carlo simulation in the control regions before and after performing the simultaneous fit to the different control regions and signal region. Plot (a) corresponds to the dielectron control region, and plot (b) corresponds to the dimuon control region. Plot (c) corresponds to the single photon control region. The blue solid line represents the sum of the SM background contributions normalized to the post-fit yield. The red solid line represents the sum of the SM background contributions normalized to the theoretical prediction. The stacked histograms show the individual SM background distributions after the fit is performed. The last bin contains overflow events. The gray band indicates the post-fit uncertainty after propagating all the systematic uncertainties in the fit. |
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Figure 2-b:
Comparison between data and Monte Carlo simulation in the control regions before and after performing the simultaneous fit to the different control regions and signal region. Plot (a) corresponds to the dielectron control region, and plot (b) corresponds to the dimuon control region. Plot (c) corresponds to the single photon control region. The blue solid line represents the sum of the SM background contributions normalized to the post-fit yield. The red solid line represents the sum of the SM background contributions normalized to the theoretical prediction. The stacked histograms show the individual SM background distributions after the fit is performed. The last bin contains overflow events. The gray band indicates the post-fit uncertainty after propagating all the systematic uncertainties in the fit. |
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Figure 2-c:
Comparison between data and Monte Carlo simulation in the control regions before and after performing the simultaneous fit to the different control regions and signal region. Plot (a) corresponds to the dielectron control region, and plot (b) corresponds to the dimuon control region. Plot (c) corresponds to the single photon control region. The blue solid line represents the sum of the SM background contributions normalized to the post-fit yield. The red solid line represents the sum of the SM background contributions normalized to the theoretical prediction. The stacked histograms show the individual SM background distributions after the fit is performed. The last bin contains overflow events. The gray band indicates the post-fit uncertainty after propagating all the systematic uncertainties in the fit. |
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Figure 3-a:
Comparison between data and Monte Carlo simulation in the control regions before and after performing the simultaneous fit to the different control regions and signal region. Plot (a) corresponds to the single electron anti-$b$-tagged control region and plot (b) corresponds to the single muon anti-$b$-tagged control region. The blue solid line represents the sum of the SM background contributions normalized to the post-fit yield. The red solid line represents the sum of the SM background contributions normalized to the theoretical prediction. The stacked histograms show the individual SM background distributions after the fit is performed. The last bin contains overflow events. The gray band represents the post-fit uncertainty propagating all the systematics through. |
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Figure 3-b:
Comparison between data and Monte Carlo simulation in the control regions before and after performing the simultaneous fit to the different control regions and signal region. Plot (a) corresponds to the single electron anti-$b$-tagged control region and plot (b) corresponds to the single muon anti-$b$-tagged control region. The blue solid line represents the sum of the SM background contributions normalized to the post-fit yield. The red solid line represents the sum of the SM background contributions normalized to the theoretical prediction. The stacked histograms show the individual SM background distributions after the fit is performed. The last bin contains overflow events. The gray band represents the post-fit uncertainty propagating all the systematics through. |
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Figure 4-a:
Comparison between data and Monte Carlo simulation in the control regions before and after performing the simultaneous fit to the different control regions and signal region. Plot (a) corresponds to the single electron $b$-tagged control region and plot (b) corresponds to the single muon $b$-tagged control region. The blue solid line represents the sum of the SM background contributions normalized to the post-fit yield. The red solid line represents the sum of the SM background contributions normalized to the theoretical prediction. The stacked histograms show the individual SM background distributions after the fit is performed. The last bin contains overflow events. The gray band represents the post-fit uncertainty propagating all the systematics through. |
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Figure 4-b:
Comparison between data and Monte Carlo simulation in the control regions before and after performing the simultaneous fit to the different control regions and signal region. Plot (a) corresponds to the single electron $b$-tagged control region and plot (b) corresponds to the single muon $b$-tagged control region. The blue solid line represents the sum of the SM background contributions normalized to the post-fit yield. The red solid line represents the sum of the SM background contributions normalized to the theoretical prediction. The stacked histograms show the individual SM background distributions after the fit is performed. The last bin contains overflow events. The gray band represents the post-fit uncertainty propagating all the systematics through. |
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Figure 5:
Distribution of ${E_{\mathrm {T}}^{\text {miss}}}$ from SM backgrounds superimposed to data in the signal region. The stacked histograms show the individual SM background distributions after the fit is performed. The blue solid line represents the sum of the SM background contributions normalized to the post-fit yield. The red solid line represents the sum of the SM background contributions normalized to the theoretical prediction. The last bin contains overflow events. The gray bands indicate the post-fit uncertainty on the background, assuming no signal. For comparison, the ${E_{\mathrm {T}}^{\text {miss}}}$ distribution from the FCNC signal model with $m_V= $ 900 GeV and $a_\text {FC} = b_\text {FC} = $ 0.1 is shown. |
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Figure 6-a:
Results assuming a FCNC interpretation of the monotop signature. Shown are upper limits as a function of the mass of the vector field $V$, assuming fixed $a_\text {FC} = b_\text {FC}= $ 0.1 . the limits are placed at a confidence level of 95%. a: limits on the inclusive cross section for monotop production; b: limits on $\sigma /\sigma _\text {theory}$. With the assumptions on $a_\text {FC}, b_\text {FC}$, the model is excluded in the range 300 $ < M_V < $ 1100 GeV. |
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Figure 6-b:
Results assuming a FCNC interpretation of the monotop signature. Shown are upper limits as a function of the mass of the vector field $V$, assuming fixed $a_\text {FC} = b_\text {FC}= $ 0.1 . the limits are placed at a confidence level of 95%. a: limits on the inclusive cross section for monotop production; b: limits on $\sigma /\sigma _\text {theory}$. With the assumptions on $a_\text {FC}, b_\text {FC}$, the model is excluded in the range 300 $ < M_V < $ 1100 GeV. |
| Summary |
| A search for dark matter in the monotop final state is performed. The data is found to be in agreement with the Standard Model prediction. Results are interpreted in terms of dark matter particles produced via a neutral flavor-changing interaction. Assuming couplings of $a_\text{FC} = b_\text{FC} =$ 0.1, the flavor-changing neutral current is excluded for mediator masses of 300 $ < M_\phi < $ 1100 GeV. Compared to previous CMS searches for monotop production, the exclusion mass range is extended. |
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