CMS-SUS-19-010

CMS-SUS-19-010 ; CERN-EP-2021-022
Search for top squark production in fully-hadronic final states in proton-proton collisions at $\sqrt{s} = $ 13 TeV
CMS Collaboration
1 March 2021
Phys. Rev. D 104 (2021) 052001
Abstract: A search for production of the supersymmetric partners of the top quark, top squarks, is presented. The search is based on proton-proton collision events containing multiple jets, no leptons, and large transverse momentum imbalance. The data were collected with the CMS detector at the CERN LHC at a center-of-mass energy of 13 TeV, and correspond to an integrated luminosity of 137 fb$^{-1}$. The targeted signal production scenarios are direct and gluino-mediated top squark production, including scenarios in which the top squark and neutralino masses are nearly degenerate. The search utilizes novel algorithms based on deep neural networks that identify hadronically decaying top quarks and W bosons, which are expected in many of the targeted signal models. No statistically significant excess of events is observed relative to the expectation from the standard model, and limits on the top squark production cross section are obtained in the context of simplified supersymmetric models for various production and decay modes. Exclusion limits as high as 1310 GeV are established at the 95% confidence level on the mass of the top squark for direct top squark production models, and as high as 2260 GeV on the mass of the gluino for gluino-mediated top squark production models. These results represent a significant improvement over the results of previous searches for supersymmetry by CMS in the same final state.
Links: e-print arXiv:2103.01290 [hep-ex] (PDF) ; CDS record ; inSPIRE record ; HepData record ; CADI line (restricted) ;

Figures & Tables	Summary	Additional Figures & Tables	References	CMS Publications

Additional information on efficiencies needed for reinterpretation of these results are available here
Additional technical material for CMS speakers can be found here

Figures
png pdf	Figure 1: Diagrams for the direct top squark production scenarios considered in this study: the T2tt (upper left), T2bW (upper middle), T2tb (upper right), T2ttC (lower left), T2bWC (lower middle), and T2cc (lower right) simplified models.
png pdf	Figure 1-a: Diagram for the direct top squark production in the T2tt simplified model.
png pdf	Figure 1-b: Diagram for the direct top squark production in the T2bW simplified model.
png pdf	Figure 1-c: Diagram for the direct top squark production in the T2tb simplified model.
png pdf	Figure 1-d: Diagram for the direct top squark production in the T2ttC simplified model.
png pdf	Figure 1-e: Diagram for the direct top squark production in the T2bWC simplified model.
png pdf	Figure 1-f: Diagram for the direct top squark production in the T2cc simplified model.
png pdf	Figure 2: Diagrams for the direct gluino production scenarios considered in this study: the T1tttt (left), T1ttbb (middle), and T5ttcc (right) simplified models.
png pdf	Figure 2-a: Diagram for the direct gluino production in the T1tttt simplified model.
png pdf	Figure 2-b: Diagram for the direct gluino production in the T1ttbb simplified model.
png pdf	Figure 2-c: Diagram for the direct gluino production in the T5ttcc simplified model.
png pdf	Figure 3: Top quark and W boson tagging efficiencies are shown as a function of the generator-level top quark ${p_{\mathrm {T}}}$ and the generator-level W boson ${p_{\mathrm {T}}}$, respectively, for the merged tagging algorithm and resolved tagging algorithm described in Section 5.2. The left plot shows the efficiencies as calculated in a sample of simulated ${\mathrm{t} {}\mathrm{\bar{t}}}$ events in which one top quark decays leptonically, while the other decays hadronically. The right plot shows the W boson tagging efficiency when calculated in a sample of simulated WW events. In addition to the individual algorithms shown as orange squares (boosted top quarks), green inverted triangles (resolved top quarks), and red triangles (boosted W bosons), the total top quark tagging efficiency (blue dots) is also shown.
png pdf	Figure 3-a: Top quark tagging efficiencies are shown as a function of the generator-level top quark ${p_{\mathrm {T}}}$ for the merged tagging algorithm and resolved tagging algorithm described in Section 5.2. The plot shows the efficiencies as calculated in a sample of simulated ${\mathrm{t} {}\mathrm{\bar{t}}}$ events in which one top quark decays leptonically, while the other decays hadronically. In addition to the individual algorithms shown as orange squares (boosted top quarks) and green inverted triangles (resolved top quarks), the total top quark tagging efficiency (blue dots) is also shown.
png pdf	Figure 3-b: Boosted W boson tagging efficiency shown as a function of the generator-level W boson ${p_{\mathrm {T}}}$ for the merged tagging algorithm described in Section 5.2. The plot shows the tagging efficiency (red triangles) when calculated in a sample of simulated WW events.
png pdf	Figure 4: Comparison between data and simulation in the high ${\Delta m}$ portion of the $\ell$+jets control region, as a function of ${{p_{\mathrm {T}}} ^\text {miss}}$ (upper left), $N_{\mathrm{t}}$ (upper right), $N_{\mathrm{W}}$ (lower left), and $N_{\text{res}}$ (lower right) after scaling the simulation to match the total yield in data. The hatched region indicates the total shape uncertainty in the simulation. The lower panels display the ratios between the observed data and the simulation.
png pdf	Figure 4-a: Comparison between data and simulation in the high ${\Delta m}$ portion of the $\ell$+jets control region, as a function of ${{p_{\mathrm {T}}} ^\text {miss}}$ after scaling the simulation to match the total yield in data. The hatched region indicates the total shape uncertainty in the simulation. The lower panel displays the ratios between the observed data and the simulation.
png pdf	Figure 4-b: Comparison between data and simulation in the high ${\Delta m}$ portion of the $\ell$+jets control region, as a function of $N_{\mathrm{t}}$ after scaling the simulation to match the total yield in data. The hatched region indicates the total shape uncertainty in the simulation. The lower panel displays the ratios between the observed data and the simulation.
png pdf	Figure 4-c: Comparison between data and simulation in the high ${\Delta m}$ portion of the $\ell$+jets control region, as a function of $N_{\mathrm{W}}$ after scaling the simulation to match the total yield in data. The hatched region indicates the total shape uncertainty in the simulation. The lower panel displays the ratios between the observed data and the simulation.
png pdf	Figure 4-d: Comparison between data and simulation in the high ${\Delta m}$ portion of the $\ell$+jets control region, as a function of $N_{\text{res}}$ after scaling the simulation to match the total yield in data. The hatched region indicates the total shape uncertainty in the simulation. The lower panel displays the ratios between the observed data and the simulation.
png pdf	Figure 5: The observed numbers of events and the SM background predictions for the low ${\Delta m}$ validation bins (left) and for the high ${\Delta m}$ validation bins (right). The hatched region indicates the total uncertainty in the background predictions. The lower panels display the ratios between the data and the SM predictions.
png pdf	Figure 5-a: The observed numbers of events and the SM background predictions for the low ${\Delta m}$ validation bins. The hatched region indicates the total uncertainty in the background predictions. The lower panel displays the ratios between the data and the SM predictions.
png pdf	Figure 5-b: The observed numbers of events and the SM background predictions for the high ${\Delta m}$ validation bins. The hatched region indicates the total uncertainty in the background predictions. The lower panel displays the ratios between the data and the SM predictions.
png pdf	Figure 6: Observed event yields in data (black points) and predicted SM background (filled histograms) for the low ${\Delta m}$ search bins 0-52 (upper), and for the high ${\Delta m}$ search bins 53-104 (lower). The bracketed numbers in the lower plot represent the respective ${N_{\mathrm{t}}}$, ${N_{\mathrm{W}}}$, and ${N_{\text {res}}}$ requirements used in that region. The signal models are denoted in the legend with the masses in GeV of the SUSY particles in parentheses: $({m_{\tilde{\mathrm{t}}}}, {m_{\tilde{\chi}^0_1}})$ or $({m_{{\mathrm{\widetilde{g}}}}}, {m_{\tilde{\chi}^0_1}})$ for the T2 or T1 signal models, respectively. For both plots, the lower panel shows the ratio of the data to the total background prediction. The hatched bands correspond to the total uncertainty in the background prediction. The (unstacked) distributions for two example signal models are also shown in both plots.
png pdf	Figure 6-a: Observed event yields in data (black points) and predicted SM background (filled histograms) for the low ${\Delta m}$ search bins 0-52. The signal T2 models are denoted in the legend with the masses in GeV of the SUSY particles in parentheses, $({m_{\tilde{\mathrm{t}}}}, {m_{\tilde{\chi}^0_1}})$. The lower panel shows the ratio of the data to the total background prediction. The hatched band corresponds to the total uncertainty in the background prediction. The (unstacked) distributions for two example signal models are also shown.
png pdf	Figure 6-b: Observed event yields in data (black points) and predicted SM background (filled histograms) for the high ${\Delta m}$ search bins 53-104. The bracketed numbers represent the respective ${N_{\mathrm{t}}}$, ${N_{\mathrm{W}}}$, and ${N_{\text {res}}}$ requirements used in that region. The signal models are denoted in the legend with the masses in GeV of the SUSY particles in parentheses, $({m_{\tilde{\mathrm{t}}}}, {m_{\tilde{\chi}^0_1}})$ or $({m_{{\mathrm{\widetilde{g}}}}}, {m_{\tilde{\chi}^0_1}})$, for the T2 or T1 signal models. The lower panel shows the ratio of the data to the total background prediction. The hatched band corresponds to the total uncertainty in the background prediction. The (unstacked) distributions for two example signal models are also shown.
png pdf	Figure 7: Observed event yields in data (black points) and predicted SM background (filled histograms) for the high ${\Delta m}$ search bins 105-152 with ${{N_{\mathrm{b}}} = 2}$ (upper), and for the high ${\Delta m}$ search bins 153-182 with ${{N_{\mathrm{b}}} \geq 3}$ (lower). The bracketed numbers in each plot represent the respective ${N_{\mathrm{t}}}$, ${N_{\mathrm{W}}}$, and ${N_{\text {res}}}$ requirements used in that region. The signal models are denoted in the legend with the masses in GeV of the SUSY particles in parentheses: $({m_{\tilde{\mathrm{t}}}}, {m_{\tilde{\chi}^0_1}})$ or $({m_{{\mathrm{\widetilde{g}}}}}, {m_{\tilde{\chi}^0_1}})$ for the T2 or T1 signal models, respectively. For both plots, the lower panel shows the ratio of the data to the total background prediction. The hatched bands correspond to the total uncertainty in the background prediction. The (unstacked) distributions for two example signal models are also shown in both plots.
png pdf	Figure 7-a: Observed event yields in data (black points) and predicted SM background (filled histograms) for the high ${\Delta m}$ search bins 105-152 with ${{N_{\mathrm{b}}} = 2}$. The bracketed numbers represent the respective ${N_{\mathrm{t}}}$, ${N_{\mathrm{W}}}$, and ${N_{\text {res}}}$ requirements used in that region. The signal models are denoted in the legend with the masses in GeV of the SUSY particles in parentheses: $({m_{\tilde{\mathrm{t}}}}, {m_{\tilde{\chi}^0_1}})$ or $({m_{{\mathrm{\widetilde{g}}}}}, {m_{\tilde{\chi}^0_1}})$ for the T2 or T1 signal models, respectively. The lower panel shows the ratio of the data to the total background prediction. The hatched band corresponds to the total uncertainty in the background prediction. The (unstacked) distributions for two example signal models are also shown.
png pdf	Figure 7-b: Observed event yields in data (black points) and predicted SM background (filled histograms) for the high ${\Delta m}$ search bins 153-182 with ${{N_{\mathrm{b}}} \geq 3}$. The bracketed numbers represent the respective ${N_{\mathrm{t}}}$, ${N_{\mathrm{W}}}$, and ${N_{\text {res}}}$ requirements used in that region. The signal models are denoted in the legend with the masses in GeV of the SUSY particles in parentheses: $({m_{\tilde{\mathrm{t}}}}, {m_{\tilde{\chi}^0_1}})$ or $({m_{{\mathrm{\widetilde{g}}}}}, {m_{\tilde{\chi}^0_1}})$ for the T2 or T1 signal models, respectively. The lower panel shows the ratio of the data to the total background prediction. The hatched band corresponds to the total uncertainty in the background prediction. The (unstacked) distributions for two example signal models are also shown.
png pdf	Figure 8: The 95% CL upper limit on the production cross section of the T2tt (upper left), T2bW (upper right), and T2tb (lower) simplified models as a function of the top squark and LSP masses. The solid black curves represent the observed exclusion contour with respect to approximate NNLO+NNLL signal cross sections and the change in this contour due to variation of these cross sections within their theoretical uncertainties ($\sigma _{\text {theory}}$) [64,65,66,67,68,69,70,71,72,73,74]. The dashed red curves indicate the mean expected exclusion contour and the region containing 68 and 95% ($\pm$1 and 2$\sigma _{\text {experiment}}$) of the distribution of expected exclusion limits under the background-only hypothesis. For T2tt, no interpretation is provided for signal models for which ${\| {m_{\tilde{\mathrm{t}}}} - {m_{\tilde{\chi}^0_1}} - {m_{\mathrm{t}}} \|} < $ 25 GeV and ${m_{\tilde{\mathrm{t}}}} < $ 275 GeV as described in the text.
png pdf	Figure 8-a: The 95% CL upper limit on the production cross section of the T2tt simplified model as a function of the top squark and LSP masses. The solid black curves represent the observed exclusion contour with respect to approximate NNLO+NNLL signal cross sections and the change in this contour due to variation of these cross sections within their theoretical uncertainties ($\sigma _{\text {theory}}$). The dashed red curves indicate the mean expected exclusion contour and the region containing 68 and 95% ($\pm$1 and 2$\sigma _{\text {experiment}}$) of the distribution of expected exclusion limits under the background-only hypothesis. For this model, no interpretation is provided for signal models for which ${\| {m_{\tilde{\mathrm{t}}}} - {m_{\tilde{\chi}^0_1}} - {m_{\mathrm{t}}} \|} < $ 25 GeV and ${m_{\tilde{\mathrm{t}}}} < $ 275 GeV as described in the text.
png pdf	Figure 8-b: The 95% CL upper limit on the production cross section of the T2bW simplified model as a function of the top squark and LSP masses. The solid black curves represent the observed exclusion contour with respect to approximate NNLO+NNLL signal cross sections and the change in this contour due to variation of these cross sections within their theoretical uncertainties ($\sigma _{\text {theory}}$). The dashed red curves indicate the mean expected exclusion contour and the region containing 68 and 95% ($\pm$1 and 2$\sigma _{\text {experiment}}$) of the distribution of expected exclusion limits under the background-only hypothesis.
png pdf	Figure 8-c: The 95% CL upper limit on the production cross section of the T2tb simplified model as a function of the top squark and LSP masses. The solid black curves represent the observed exclusion contour with respect to approximate NNLO+NNLL signal cross sections and the change in this contour due to variation of these cross sections within their theoretical uncertainties ($\sigma _{\text {theory}}$). The dashed red curves indicate the mean expected exclusion contour and the region containing 68 and 95% ($\pm$1 and 2$\sigma _{\text {experiment}}$) of the distribution of expected exclusion limits under the background-only hypothesis.
png pdf	Figure 9: The 95% CL upper limit on the production cross section of the T2ttC (upper left), T2bWC (upper right), and T2cc (lower) simplified models as a function of the top squark mass and the difference between the top squark and LSP masses. The solid black curves represent the observed exclusion contour with respect to approximate NNLO+NNLL signal cross sections and the change in this contour due to variation of these cross sections within their theoretical uncertainties ($\sigma _{\text {theory}}$) [64,65,66,67,68,69,70,71,72,73,74]. The dashed red curves indicate the mean expected exclusion contour and the region containing 68% ($\pm$1$\sigma _{\text {experiment}}$) of the distribution of expected exclusion limits under the background-only hypothesis.
png pdf	Figure 9-a: The 95% CL upper limit on the production cross section of the T2ttC simplified model as a function of the top squark mass and the difference between the top squark and LSP masses. The solid black curves represent the observed exclusion contour with respect to approximate NNLO+NNLL signal cross sections and the change in this contour due to variation of these cross sections within their theoretical uncertainties ($\sigma _{\text {theory}}$). The dashed red curves indicate the mean expected exclusion contour and the region containing 68% ($\pm$1$\sigma _{\text {experiment}}$) of the distribution of expected exclusion limits under the background-only hypothesis.
png pdf	Figure 9-b: The 95% CL upper limit on the production cross section of the T2bWC simplified model as a function of the top squark mass and the difference between the top squark and LSP masses. The solid black curves represent the observed exclusion contour with respect to approximate NNLO+NNLL signal cross sections and the change in this contour due to variation of these cross sections within their theoretical uncertainties ($\sigma _{\text {theory}}$). The dashed red curves indicate the mean expected exclusion contour and the region containing 68% ($\pm$1$\sigma _{\text {experiment}}$) of the distribution of expected exclusion limits under the background-only hypothesis.
png pdf	Figure 9-c: The 95% CL upper limit on the production cross section of the T2cc simplified model as a function of the top squark mass and the difference between the top squark and LSP masses. The solid black curves represent the observed exclusion contour with respect to approximate NNLO+NNLL signal cross sections and the change in this contour due to variation of these cross sections within their theoretical uncertainties ($\sigma _{\text {theory}}$). The dashed red curves indicate the mean expected exclusion contour and the region containing 68% ($\pm$1$\sigma _{\text {experiment}}$) of the distribution of expected exclusion limits under the background-only hypothesis.
png pdf	Figure 10: The 95% CL upper limit on the production cross section of the T1tttt (left) and T1ttbb (right) simplified models as a function of the gluino and LSP masses. The solid black curves represent the observed exclusion contour with respect to approximate NNLO+NNLL signal cross sections and the change in this contour due to variation of these cross sections within their theoretical uncertainties ($\sigma _{\text {theory}}$) [64,65,66,67,68,69,70,71,72,73,74]. The dashed red curves indicate the mean expected exclusion contour and the region containing 68 and 95% ($\pm$1 and 2$\sigma _{\text {experiment}}$) of the distribution of expected exclusion limits under the background-only hypothesis.
png pdf	Figure 10-a: The 95% CL upper limit on the production cross section of the T1tttt simplified model as a function of the gluino and LSP masses. The solid black curves represent the observed exclusion contour with respect to approximate NNLO+NNLL signal cross sections and the change in this contour due to variation of these cross sections within their theoretical uncertainties ($\sigma _{\text {theory}}$). The dashed red curves indicate the mean expected exclusion contour and the region containing 68 and 95% ($\pm$1 and 2$\sigma _{\text {experiment}}$) of the distribution of expected exclusion limits under the background-only hypothesis.
png pdf	Figure 10-b: The 95% CL upper limit on the production cross section of the T1ttbb simplified model as a function of the gluino and LSP masses. The solid black curves represent the observed exclusion contour with respect to approximate NNLO+NNLL signal cross sections and the change in this contour due to variation of these cross sections within their theoretical uncertainties ($\sigma _{\text {theory}}$). The dashed red curves indicate the mean expected exclusion contour and the region containing 68 and 95% ($\pm$1 and 2$\sigma _{\text {experiment}}$) of the distribution of expected exclusion limits under the background-only hypothesis.
png pdf	Figure 11: The 95% CL upper limit on the production cross section of the T5ttcc simplified model as a function of the gluino and LSP masses. The solid black curves represent the observed exclusion contour with respect to approximate NNLO+NNLL signal cross sections and the change in this contour due to variation of these cross sections within their theoretical uncertainties ($\sigma _{\text {theory}}$) [64,65,66,67,68,69,70,71,72,73,74]. The dashed red curves indicate the mean expected exclusion contour and the region containing 68% and 95% ($\pm$1 and 2$\sigma _{\text {experiment}}$) of the distribution of expected exclusion limits under the background-only hypothesis. The expected and observed upper limits do not take into account contributions from direct top squark pair production; however, its effect is small for $ {m_{\tilde{\chi}^0_1}} > $ 600 GeV, which corresponds to the phase space beyond the exclusions based on direct top squark pair production. The excluded regions based on direct top squark pair production from this search and earlier searches by the ATLAS [27] and CMS [37,40,42] experiments, as well as by the LEP experiments [129,130,131,132] are indicated by the hatched areas.

Tables
png pdf	Table 1: Summary of the preselection requirements (baseline selection) imposed on the reconstructed physics objects for this search, as well as the low ${\Delta m}$ and high ${\Delta m}$ baseline selections. Here $R$ is the distance parameter of the anti-$ {k_{\mathrm {T}}}$ algorithm. Electron and muon candidates as well as ${\tau _\mathrm {h}}$ candidates and isolated tracks are as defined in Section 5. The $i$-th highest- ${p_{\mathrm {T}}}$ jet is denoted by ${\mathrm {j}_{i}}$.
png pdf	Table 2: Summary of the 53 search bins that mainly target low ${\Delta m}$ signal models. For these search bins, events are required to pass the low ${\Delta m}$ region selection discussed in Section 6.1. Within each row of this table, the bins are ordered by increasing ${{p_{\mathrm {T}}} ^\text {miss}}$ requirements. A dash (--) indicates that no requirements are made.
png pdf	Table 3: Summary of the 130 search bins that mainly target high ${\Delta m}$ signal models. For these search bins, events are required to pass the high ${\Delta m}$ region selection discussed in Section 6.2. Within each row of this table, the bins are ordered by increasing ${{p_{\mathrm {T}}} ^\text {miss}}$ requirements.
png pdf	Table 4: Summary of the 19 validation bins for low ${\Delta m}$. Bins 0 to 14 use the normal low ${\Delta m}$ region selection with lower ${{p_{\mathrm {T}}} ^\text {miss}}$ requirements than any of the low ${\Delta m}$ search bins. Bins 15-18 use a similar selection, but additionally require medium ${\Delta \phi}$, as discussed in Section 6.3. A dash (--) indicates that no requirements are made.
png pdf	Table 5: Summary of the 24 validation bins for high ${\Delta m}$. These search bins are orthogonal to the high ${\Delta m}$ search region because of the ${\Delta \phi}$ requirements discussed in Section 6.3.
png pdf	Table A1: Observed number of events and SM background predictions in search bins 0-27.
png pdf	Table A2: Observed number of events and SM background predictions in search bins 28-52.
png pdf	Table A3: Observed number of events and SM background predictions in search bins 53-80.
png pdf	Table A4: Observed number of events and SM background predictions in search bins 81-107.
png pdf	Table A5: Observed number of events and SM background predictions in search bins 108-136.
png pdf	Table A6: Observed number of events and SM background predictions in search bins 137-161.
png pdf	Table A7: Observed number of events and SM background predictions in search bins 162-182.

Summary

Results are presented from a search for direct and gluino-mediated top squark production in proton-proton collisions at a center-of-mass energy of 13 TeV. The analysis includes deep neural network based tagging algorithms for top quarks and W bosons both at low and high transverse momentum. The search is based on events with at least two jets and large imbalance in transverse momentum ${p_{\mathrm{T}}^{\text{miss}}}$. The data set corresponds to an integrated luminosity of 137 fb$^{-1}$ collected with the CMS detector at the LHC in 2016-2018. A set of 183 search bins is defined based on several kinematic variables and the number of reconstructed top quarks, bottom quarks, and W bosons. No statistically significant excess of events is observed with respect to the expectation from the standard model.

Upper limits at the 95% confidence level are established on the cross section for several simplified models of direct and gluino-mediated top squark pair production as a function of the masses of the supersymmetric particles. Using the predicted cross sections, which are calculated with approximate next-to-next-to-leading order plus next-to-next-to-leading logarithmic accuracy, lower limits at the 95% confidence level are established on the top squark, lightest supersymmetric particle (LSP), and gluino masses. In the case of the direct top squark production models, top squark masses are excluded below a limit ranging from 1150 to 1310 GeV in the region of parameter space where the mass difference between the top squark and the LSP is larger than the W boson mass, depending on the top squark decay scenario. In the region of parameter space where the mass difference between the top squark and the LSP is smaller than the mass of the W boson, top squark masses are excluded below a limit ranging from 630 to 740 GeV, depending on the top squark decay scenario. In the case of the gluino-mediated top squark production models, gluino masses are excluded below a limit ranging from 2150 to 2260 GeV, depending on the signal model. These results significantly extend the mass exclusions of the previous top squark searches in the fully-hadronic final state from CMS [40,41] by about 100-300 GeV, benefiting not only from the larger data set, but also from improved analysis methods. For models of direct top squark production, the results obtained in this analysis are the most stringent constraints to date, regardless of the final state.

Additional Figures
png pdf	Additional Figure 1: The misidentification rate for the DeepResolved top quark tagger is shown as a function of the ${p_{\mathrm {T}}}$ of the top quark candidate with the highest ${p_{\mathrm {T}}}$. A top quark candidate is defined as a trijet combination which satisfies the preselection requirements on the trijet mass (100 to 250 GeV), the maximum angle (no jet is farther than 3.1 from the trijet centroid in $\Delta R$), and the ${p_{\mathrm {T}}}$ of each of the three jets ($ {p_{\mathrm {T}}} > $ 40, 30, and 20 GeV, respectively). Top quark candidates must also survive the cross-cleaning process, which removes overlaps with tagged AK8 jets and other trijet candidates with lower NN discriminator scores. The misidentification rate is calculated in a simulated sample of QCD multijet events with $ {H_{\mathrm {T}}} > $ 300 GeV and is defined as the fraction of the candidates which have an NN discriminator score greater than 0.92.
png pdf	Additional Figure 2: The observed significance of any excess in the data above the expected backgrounds, interpreted in the context of the SMS squark models for T2tt as a function of the top squark and LSP masses.
png pdf	Additional Figure 3: The observed significance of any excess in the data above the expected backgrounds, interpreted in the context of the SMS squark models for T2bW as a function of the top squark and LSP masses.
png pdf	Additional Figure 4: The observed significance of any excess in the data above the expected backgrounds, interpreted in the context of the SMS squark models for T2tb as a function of the top squark and LSP masses.
png pdf	Additional Figure 5: The observed significance of any excess in the data above the expected backgrounds, interpreted in the context of the SMS squark models for T2ttC as a function of the top squark mass and the difference between the top squark and LSP masses.
png pdf	Additional Figure 6: The observed significance of any excess in the data above the expected backgrounds, interpreted in the context of the SMS squark models for T2bWC as a function of the top squark mass and the difference between the top squark and LSP masses.
png pdf	Additional Figure 7: The observed significance of any excess in the data above the expected backgrounds, interpreted in the context of the SMS squark models for T2cc as a function of the top squark mass and the difference between the top squark and LSP masses.
png pdf	Additional Figure 8: The observed significance of any excess in the data above the expected backgrounds, interpreted in the context of the SMS squark models for T1tttt as a function of the gluino and LSP masses.
png pdf	Additional Figure 9: The observed significance of any excess in the data above the expected backgrounds, interpreted in the context of the SMS squark models for T1ttbb as a function of the gluino and LSP masses.
png pdf	Additional Figure 10: The observed significance of any excess in the data above the expected backgrounds, interpreted in the context of the SMS squark models for T5ttcc as a function of the gluino and LSP masses. Excluded regions based on direct top squark pair production from this search and earlier searches by the ATLAS, CMS, and LEP experiments are indicated by the hatched areas.
png pdf	Additional Figure 11: The efficiency times acceptance of the SMS squark models for T2tt as a function of the top squark and LSP masses in the union of the 53 low ${\Delta m}$ search regions (left) and the 130 high ${\Delta m}$ search regions (right).
png pdf	Additional Figure 11-a: The efficiency times acceptance of the SMS squark models for T2tt as a function of the top squark and LSP masses in the union of the 53 low ${\Delta m}$ search regions.
png pdf	Additional Figure 11-b: The efficiency times acceptance of the SMS squark models for T2tt as a function of the top squark and LSP masses in the union of the 130 high ${\Delta m}$ search regions.
png pdf	Additional Figure 12: The efficiency times acceptance of the SMS squark models for T2bW as a function of the top squark and LSP masses in the union of the 53 low ${\Delta m}$ search regions (left) and the 130 high ${\Delta m}$ search regions (right).
png pdf	Additional Figure 12-a: The efficiency times acceptance of the SMS squark models for T2bW as a function of the top squark and LSP masses in the union of the 53 low ${\Delta m}$ search regions.
png pdf	Additional Figure 12-b: The efficiency times acceptance of the SMS squark models for T2bW as a function of the top squark and LSP masses in the union of the 130 high ${\Delta m}$ search regions.
png pdf	Additional Figure 13: The efficiency times acceptance of the SMS squark models for T2tb as a function of the top squark and LSP masses in the union of the 53 low ${\Delta m}$ search regions (left) and the 130 high ${\Delta m}$ search regions (right).
png pdf	Additional Figure 13-a: The efficiency times acceptance of the SMS squark models for T2tb as a function of the top squark and LSP masses in the union of the 53 low ${\Delta m}$ search regions.
png pdf	Additional Figure 13-b: The efficiency times acceptance of the SMS squark models for T2tb as a function of the top squark and LSP masses in the union of the 130 high ${\Delta m}$ search regions.
png pdf	Additional Figure 14: The efficiency times acceptance of the SMS squark models for T2ttC as a function of the top squark and the difference between the top squark and LSP masses in the union of the 53 low ${\Delta m}$ search regions (left) and the 130 high ${\Delta m}$ search regions (right).
png pdf	Additional Figure 14-a: The efficiency times acceptance of the SMS squark models for T2ttC as a function of the top squark and the difference between the top squark and LSP masses in the union of the 53 low ${\Delta m}$ search regions.
png pdf	Additional Figure 14-b: The efficiency times acceptance of the SMS squark models for T2ttC as a function of the top squark and the difference between the top squark and LSP masses in the union of the 130 high ${\Delta m}$ search regions.
png pdf	Additional Figure 15: The efficiency times acceptance of the SMS squark models for T2bWC as a function of the top squark and the difference between the top squark and LSP masses in the union of the 53 low ${\Delta m}$ search regions (left) and the 130 high ${\Delta m}$ search regions (right).
png pdf	Additional Figure 15-a: The efficiency times acceptance of the SMS squark models for T2bWC as a function of the top squark and the difference between the top squark and LSP masses in the union of the 53 low ${\Delta m}$ search regions.
png pdf	Additional Figure 15-b: The efficiency times acceptance of the SMS squark models for T2bWC as a function of the top squark and the difference between the top squark and LSP masses in the union of the 130 high ${\Delta m}$ search regions.
png pdf	Additional Figure 16: The efficiency times acceptance of the SMS squark models for T2cc as a function of the top squark and the difference between the top squark and LSP masses in the union of the 53 low ${\Delta m}$ search regions (left) and the 130 high ${\Delta m}$ search regions (right).
png pdf	Additional Figure 16-a: The efficiency times acceptance of the SMS squark models for T2cc as a function of the top squark and the difference between the top squark and LSP masses in the union of the 53 low ${\Delta m}$ search regions.
png pdf	Additional Figure 16-b: The efficiency times acceptance of the SMS squark models for T2cc as a function of the top squark and the difference between the top squark and LSP masses in the union of the 130 high ${\Delta m}$ search regions.
png pdf	Additional Figure 17: The efficiency times acceptance of the SMS gluino models for T1tttt as a function of the gluino and LSP masses in the union of the 53 low ${\Delta m}$ search regions (left) and the 130 high ${\Delta m}$ search regions (right).
png pdf	Additional Figure 17-a: The efficiency times acceptance of the SMS gluino models for T1tttt as a function of the gluino and LSP masses in the union of the 53 low ${\Delta m}$ search regions.
png pdf	Additional Figure 17-b: The efficiency times acceptance of the SMS gluino models for T1tttt as a function of the gluino and LSP masses in the union of the 130 high ${\Delta m}$ search regions.
png pdf	Additional Figure 18: The efficiency times acceptance of the SMS gluino models for T1ttbb as a function of the gluino and LSP masses in the union of the 53 low ${\Delta m}$ search regions (left) and the 130 high ${\Delta m}$ search regions (right).
png pdf	Additional Figure 18-a: The efficiency times acceptance of the SMS gluino models for T1ttbb as a function of the gluino and LSP masses in the union of the 53 low ${\Delta m}$ search regions.
png pdf	Additional Figure 18-b: The efficiency times acceptance of the SMS gluino models for T1ttbb as a function of the gluino and LSP masses in the union of the 130 high ${\Delta m}$ search regions.
png pdf	Additional Figure 19: The efficiency times acceptance of the SMS gluino models for T5ttcc as a function of the gluino and LSP masses in the union of the 53 low ${\Delta m}$ search regions (left) and the 130 high ${\Delta m}$ search regions (right).
png pdf	Additional Figure 19-a: The efficiency times acceptance of the SMS gluino models for T5ttcc as a function of the gluino and LSP masses in the union of the 53 low ${\Delta m}$ search regions.
png pdf	Additional Figure 19-b: The efficiency times acceptance of the SMS gluino models for T5ttcc as a function of the gluino and LSP masses in the union of the 130 high ${\Delta m}$ search regions.
png pdf	Additional Figure 20: The expected and observed limits for T2ttC signal as a function of the top squark and LSP masses.
png pdf	Additional Figure 21: The expected and observed limits for T2bWC signal as a function of the top squark and LSP masses.
png pdf	Additional Figure 22: The expected and observed limits for T2cc signal as a function of the top squark and LSP masses.
png pdf	Additional Figure 23: The expected and observed limits for all of the signals for direct top squark production as a function of the top squark and LSP masses.

Additional Tables
png pdf	Additional Table 1: The expected number of direct top squark production signal events that satisfy each selection requirement in turn. The percentages shown are the efficiency with respect to the previous line in most cases; the start of the low ${\Delta m}$ and high ${\Delta m}$ sections are with respect to the end of the general baseline.
png pdf	Additional Table 2: The expected number of gluino-mediated top squark production signal events that satisfy each selection requirement in turn. All object and event weights are applied. Percentages shown are the efficiency with respect to the previous line in most cases; the start of the low ${\Delta m}$ and high ${\Delta m}$ sections are with respect to the end of the general baseline.
png pdf	Additional Table 3: Summary of the 10 disjoint super search regions in the low ${\Delta m}$ category.
png pdf	Additional Table 4: Summary of the 15 disjoint super search regions in the high ${\Delta m}$ category. The selection requirements $ {{\Delta \phi} (\text {j}_{\text {1,2,3,4}}, {{p_{\mathrm {T}}} ^\text {miss}})} > 0.5$ and zero leptons are common to all high ${\Delta m}$ regions. A dash ({\text {--}}) indicates that no requirements are made.
png pdf	Additional Table 5: Predicted event yields in super search regions 0-9 for a selection of direct top squark production signals.
png pdf	Additional Table 6: Predicted event yields in super search regions 10-24 for a selection of direct top squark production signals.
png pdf	Additional Table 7: Predicted event yields in super search regions 0-9 for a selection of gluino-mediated production signals.
png pdf	Additional Table 8: Predicted event yields in super search regions 10-24 for a selection of gluino-mediated production signals.
png pdf	Additional Table 9: Prediction for bins 0-9
png pdf	Additional Table 10: Prediction for bins 10-24

References
1	R. Barbieri and G. F. Giudice	Upper bounds on supersymmetric particle masses	NPB 306 (1988) 63
2	V. C. Rubin and W. K. Ford, Jr.	Rotation of the Andromeda nebula from a spectroscopic survey of emission regions	Astrophys. J. 159 (1970) 379
3	J. Wess and B. Zumino	A Lagrangian model invariant under supergauge transformations	PLB 49 (1974) 52
4	P. Fayet and S. Ferrara	Supersymmetry	PR 32 (1977) 249
5	R. Barbieri, S. Ferrara, and C. A. Savoy	Gauge models with spontaneously broken local supersymmetry	PLB 119 (1982) 343
6	H. P. Nilles	Supersymmetry, supergravity and particle physics	PR 110 (1984) 1
7	H. E. Haber and G. L. Kane	The search for supersymmetry: probing physics beyond the standard model	PR 117 (1985) 75
8	S. P. Martin	A supersymmetry primer	in Perspectives on supersymmetry. Vol.2, G. L. Kane, ed., volume 21, p. 1 2010	hep-ph/9709356
9	B. de Carlos and J. A. Casas	One-loop analysis of the electroweak breaking in supersymmetric models and the fine tuning problem	PLB 309 (1993) 320	hep-ph/9303291
10	S. Dimopoulos and G. F. Giudice	Naturalness constraints in supersymmetric theories with nonuniversal soft terms	PLB 357 (1995) 573	hep-ph/9507282
11	M. Papucci, J. T. Ruderman, and A. Weiler	Natural SUSY endures	JHEP 09 (2012) 035	1110.6926
12	C. Brust, A. Katz, S. Lawrence, and R. Sundrum	SUSY, the third generation and the LHC	JHEP 03 (2012) 103	1110.6670
13	A. Delgado et al.	The light stop window	EPJC 73 (2013) 2370	1212.6847
14	C. Han et al.	Top-squark in natural SUSY under current LHC run-2 data	EPJC 77 (2017) 93	1609.02361
15	H. Baer et al.	Gluino reach and mass extraction at the LHC in radiatively-driven natural SUSY	EPJC 77 (2017) 499	1612.00795
16	H. Baer, V. Barger, N. Nagata, and M. Savoy	Phenomenological profile of top squarks from natural supersymmetry at the LHC	PRD 95 (2017) 055012	1611.08511
17	J. L. Feng	Naturalness and the status of supersymmetry	Ann. Rev. Nucl. Part. Sci. 63 (2013) 351	1302.6587
18	G. R. Farrar and P. Fayet	Phenomenology of the production, decay, and detection of new hadronic states associated with supersymmetry	PLB 76 (1978) 575
19	ATLAS Collaboration	Search for top squarks in final states with one isolated lepton, jets, and missing transverse momentum in $ \sqrt{s}= $ 13 TeV pp collisions with the ATLAS detector	PRD 94 (2016) 052009	1606.03903
20	ATLAS Collaboration	Search for direct top squark pair production in events with a Higgs or $ Z $ boson, and missing transverse momentum in $ \sqrt{s}= $ 13 TeV pp collisions with the ATLAS detector	JHEP 08 (2017) 006	1706.03986
21	ATLAS Collaboration	Search for direct top squark pair production in final states with two leptons in $ \sqrt{s} = $ 13 TeV pp collisions with the ATLAS detector	EPJC 77 (2017) 898	1708.03247
22	ATLAS Collaboration	Search for a scalar partner of the top quark in the jets plus missing transverse momentum final state at $ \sqrt{s}= $ 13 TeV with the ATLAS detector	JHEP 12 (2017) 085	1709.04183
23	ATLAS Collaboration	Search for $ B-L R $-parity-violating top squarks in $ \sqrt{s}= $ 13 TeV pp collisions with the ATLAS experiment	PRD 97 (2018) 032003	1710.05544
24	ATLAS Collaboration	A search for pair-produced resonances in four-jet final states at $ \sqrt{s}= $ 13 TeV with the ATLAS detector	EPJC 78 (2018) 250	1710.07171
25	ATLAS Collaboration	Search for top-squark pair production in final states with one lepton, jets, and missing transverse momentum using 36 fb$ {}^{-1} $ of $ \sqrt{s}= $ 13 TeV pp collision data with the ATLAS detector	JHEP 06 (2018) 108	1711.11520
26	ATLAS Collaboration	Search for top squarks decaying to tau sleptons in pp collisions at $ \sqrt{s}= $ 13 TeV with the ATLAS detector	PRD 98 (2018) 032008	1803.10178
27	ATLAS Collaboration	Search for supersymmetry in final states with charm jets and missing transverse momentum in 13 TeV pp collisions with the ATLAS detector	JHEP 09 (2018) 050	1805.01649
28	ATLAS Collaboration	Search for heavy charged long-lived particles in proton-proton collisions at $ \sqrt{s} = $ 13 TeV using an ionisation measurement with the ATLAS detector	PLB 788 (2019) 96	1808.04095
29	ATLAS Collaboration	Search for heavy charged long-lived particles in the ATLAS detector in 36.1 fb$ ^{-1} $ of proton-proton collision data at $ \sqrt{s} = $ 13 TeV	PRD 99 (2019) 092007	1902.01636
30	ATLAS Collaboration	Search for a scalar partner of the top quark in the all-hadronic $ t{\bar{t}} $ plus missing transverse momentum final state at $ \sqrt{s} = $ 13 TeV with the ATLAS detector	EPJC 80 (2020) 737	2004.14060
31	ATLAS Collaboration	Search for phenomena beyond the standard model in events with large $ b $-jet multiplicity using the ATLAS detector at the LHC	EPJC 81 (2021) 11	2010.01015
32	ATLAS Collaboration	Search for top squarks in events with a Higgs or $ Z $ boson using 139 fb$ ^{-1} $ of $ pp $ collision data at $ \sqrt{s}= $ 13 TeV with the ATLAS detector	EPJC 80 (2020) 1080	2006.05880
33	ATLAS Collaboration	Search for long-lived, massive particles in events with a displaced vertex and a muon with large impact parameter in $ pp $ collisions at $ \sqrt{s} = $ 13 TeV with the ATLAS detector	PRD 102 (2020) 032006	2003.11956
34	ATLAS Collaboration	Search for squarks and gluinos in final states with same-sign leptons and jets using 139 fb$ ^{-1} $ of data collected with the ATLAS detector	JHEP 06 (2020) 046	1909.08457
35	ATLAS Collaboration	Search for new phenomena with top quark pairs in final states with one lepton, jets, and missing transverse momentum in $ pp $ collisions at $ \sqrt{s} = $ 13 TeV with the ATLAS detector	Submitted to JHEP	2012.03799
36	ATLAS Collaboration	Search for new phenomena in events with two opposite-charge leptons, jets and missing transverse momentum in $ pp $ collisions at $ \sqrt{s} = $ 13 TeV with the ATLAS detector	Submitted to JHEP	2102.01444
37	CMS Collaboration	Searches for pair production of third-generation squarks in $ \sqrt{s}= $ 13 TeV pp collisions	EPJC 77 (2017) 327	CMS-SUS-16-008 1612.03877
38	CMS Collaboration	Search for supersymmetry in the all-hadronic final state using top quark tagging in pp collisions at $ \sqrt{s}= $ 13 TeV	PRD 96 (2017) 012004	CMS-SUS-16-009 1701.01954
39	CMS Collaboration	Search for top squark pair production in pp collisions at $ \sqrt{s}= $ 13 TeV using single lepton events	JHEP 10 (2017) 019	CMS-SUS-16-051 1706.04402
40	CMS Collaboration	Search for direct production of supersymmetric partners of the top quark in the all-jets final state in proton-proton collisions at $ \sqrt{s}= $ 13 TeV	JHEP 10 (2017) 005	CMS-SUS-16-049 1707.03316
41	CMS Collaboration	Search for supersymmetry in proton-proton collisions at 13 TeV using identified top quarks	PRD 97 (2018) 012007	CMS-SUS-16-050 1710.11188
42	CMS Collaboration	Search for the pair production of third-generation squarks with two-body decays to a bottom or charm quark and a neutralino in proton-proton collisions at $ \sqrt{s} = $ 13 TeV	PLB 778 (2018) 263	CMS-SUS-16-032 1707.07274
43	CMS Collaboration	Search for top squarks and dark matter particles in opposite-charge dilepton final states at $ \sqrt{s} = $ 13 TeV	PRD 97 (2018) 032009	CMS-SUS-17-001 1711.00752
44	CMS Collaboration	Search for new physics in events with two soft oppositely charged leptons and missing transverse momentum in proton-proton collisions at $ \sqrt{s} = $ 13 TeV	PLB 782 (2018) 440	CMS-SUS-16-048 1801.01846
45	CMS Collaboration	Search for pair-produced resonances decaying to quark pairs in proton-proton collisions at $ \sqrt{s} = $ 13 TeV	PRD 98 (2018) 112014	CMS-EXO-17-021 1808.03124
46	CMS Collaboration	Search for the pair production of light top squarks in the e$ ^{\pm}\mu^{\mp} $ final state in proton-proton collisions at $ \sqrt{s} = $ 13 TeV	JHEP 03 (2019) 101	CMS-SUS-18-003 1901.01288
47	CMS Collaboration	Search for direct top squark pair production in events with one lepton, jets, and missing transverse momentum at 13 TeV with the CMS experiment	JHEP 05 (2020) 032	CMS-SUS-19-009 1912.08887
48	CMS Collaboration	Search for top squark pair production using dilepton final states in pp collision data collected at $ \sqrt{s}= $ 13 TeV	EPJC 81 (2021) 3	CMS-SUS-19-011 2008.05936
49	CMS Collaboration	Identification of heavy-flavour jets with the CMS detector in pp collisions at 13 TeV	JINST 13 (2018) P05011	CMS-BTV-16-002 1712.07158
50	CMS Collaboration	Identification of heavy, energetic, hadronically decaying particles using machine-learning techniques	JINST 15 (2020) P06005	CMS-JME-18-002 2004.08262
51	J. Alwall, M.-P. Le, M. Lisanti, and J. G. Wacker	Model-independent jets plus missing energy searches	PRD 79 (2009) 015005	0809.3264
52	J. Alwall, P. C. Schuster, and N. Toro	Simplified models for a first characterization of new physics at the LHC	PRD 79 (2009) 075020	0810.3921
53	D. Alves et al.	Simplified models for LHC new physics searches	JPG 39 (2012) 105005	1105.2838
54	CMS Collaboration	Interpretation of searches for supersymmetry with simplified models	PRD 88 (2013) 052017	CMS-SUS-11-016 1301.2175
55	C. Balazs, M. Carena, and C. E. M. Wagner	Dark matter, light top squarks and electroweak baryogenesis	PRD 70 (2004) 015007	hep-ph/0403224
56	J. Ellis, K. A. Olive, and Y. Santoso	Calculations of neutralino-stop coannihilation in the CMSSM	Astropart. Phys. 18 (2003) 395	hep-ph/0112113
57	J. Ellis, K. A. Olive, and J. Zheng	The extent of the stop coannihilation strip	EPJC 74 (2014) 2947	1404.5571
58	CMS Collaboration	The CMS trigger system	JINST 12 (2017) P01020	CMS-TRG-12-001 1609.02366
59	CMS Collaboration	CMS luminosity measurements for the 2016 data taking period	CMS-PAS-LUM-17-001	CMS-PAS-LUM-17-001
60	CMS Collaboration	CMS luminosity measurement for the 2017 data-taking period at $ \sqrt{s} = $ 13 TeV	CMS-PAS-LUM-17-004	CMS-PAS-LUM-17-004
61	CMS Collaboration	CMS luminosity measurement for the 2018 data-taking period at $ \sqrt{s} = $ 13 TeV	CMS-PAS-LUM-18-002	CMS-PAS-LUM-18-002
62	CMS Collaboration	The CMS experiment at the CERN LHC	JINST 3 (2008) S08004	CMS-00-001
63	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
64	W. Beenakker et al.	NNLL-fast: predictions for coloured supersymmetric particle production at the LHC with threshold and Coulomb resummation	JHEP 12 (2016) 133	1607.07741
65	W. Beenakker, R. Hopker, M. Spira, and P. M. Zerwas	Squark and gluino production at hadron colliders	NPB 492 (1997) 51	hep-ph/9610490
66	A. Kulesza and L. Motyka	Threshold resummation for squark-antisquark and gluino-pair production at the LHC	PRL 102 (2009) 111802	0807.2405
67	A. Kulesza and L. Motyka	Soft gluon resummation for the production of gluino-gluino and squark-antisquark pairs at the LHC	PRD 80 (2009) 095004	0905.4749
68	W. Beenakker et al.	Soft-gluon resummation for squark and gluino hadroproduction	JHEP 12 (2009) 041	0909.4418
69	W. Beenakker et al.	NNLL resummation for squark-antisquark pair production at the LHC	JHEP 01 (2012) 076	1110.2446
70	W. Beenakker et al.	Towards NNLL resummation: hard matching coefficients for squark and gluino hadroproduction	JHEP 10 (2013) 120	1304.6354
71	W. Beenakker et al.	NNLL resummation for squark and gluino production at the LHC	JHEP 12 (2014) 023	1404.3134
72	W. Beenakker et al.	Stop production at hadron colliders	NPB 515 (1998) 3	hep-ph/9710451
73	W. Beenakker et al.	Supersymmetric top and bottom squark production at hadron colliders	JHEP 08 (2010) 098	1006.4771
74	W. Beenakker et al.	NNLL resummation for stop pair-production at the LHC	JHEP 05 (2016) 153	1601.02954
75	R. Frederix and S. Frixione	Merging meets matching in MC@NLO	JHEP 12 (2012) 061	1209.6215
76	P. Nason	A new method for combining NLO QCD with shower Monte Carlo algorithms	JHEP 11 (2004) 040	hep-ph/0409146
77	S. Frixione, P. Nason, and C. Oleari	Matching NLO QCD computations with parton shower simulations: the POWHEG method	JHEP 11 (2007) 070	0709.2092
78	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
79	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
80	E. Re	Single-top $ \text{Wt} $-channel production matched with parton showers using the POWHEG method	EPJC 71 (2011) 1547	1009.2450
81	T. Melia, P. Nason, R. Rontsch, and G. Zanderighi	$ W^+W^- $, $ WZ $ and $ ZZ $ production in the POWHEG BOX	JHEP 11 (2011) 078	1107.5051
82	P. Nason and G. Zanderighi	$ W^+W^- $, $ WZ $ and $ ZZ $ production in the POWHEG-BOX-V2	EPJC 74 (2014) 2702	1311.1365
83	H. B. Hartanto, B. Jager, L. Reina, and D. Wackeroth	Higgs boson production in association with top quarks in the POWHEG BOX	PRD 91 (2015) 094003	1501.04498
84	T. Sjostrand et al.	An introduction to PYTHIA 8.2	CPC 191 (2015) 159	1410.3012
85	S. Quackenbush, R. Gavin, Y. Li, and F. Petriello	W physics at the LHC with FEWZ 2.1	CPC 184 (2013) 209	1201.5896
86	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
87	Y. Li and F. Petriello	Combining QCD and electroweak corrections to dilepton production in the framework of the FEWZ simulation code	PRD 86 (2012) 094034	1208.5967
88	T. Gehrmann et al.	$ W^+W^- $ production at hadron colliders in next to next to leading order QCD	PRL 113 (2014) 212001	1408.5243
89	J. M. Campbell, R. K. Ellis, and C. Williams	Vector boson pair production at the LHC	JHEP 07 (2011) 018	1105.0020
90	M. Beneke, P. Falgari, S. Klein, and C. Schwinn	Hadronic top-quark pair production with NNLL threshold resummation	NPB 855 (2012) 695	1109.1536
91	M. Cacciari et al.	Top-pair production at hadron colliders with next-to-next-to-leading logarithmic soft-gluon resummation	PLB 710 (2012) 612	1111.5869
92	P. Barnreuther, M. Czakon, and A. Mitov	Percent-level-precision physics at the Tevatron: next-to-next-to-leading order QCD corrections to $ \mathrm{q\bar{q}} \to \mathrm{t\bar{t}} + {X} $	PRL 109 (2012) 132001	1204.5201
93	M. Czakon and A. Mitov	NNLO corrections to top-pair production at hadron colliders: the all-fermionic scattering channels	JHEP 12 (2012) 054	1207.0236
94	M. Czakon and A. Mitov	NNLO corrections to top pair production at hadron colliders: the quark-gluon reaction	JHEP 01 (2013) 080	1210.6832
95	M. Czakon, P. Fiedler, and A. Mitov	Total top-quark pair-production cross section at hadron colliders through $ O({\alpha_S}^4) $	PRL 110 (2013) 252004	1303.6254
96	M. Czakon and A. Mitov	Top++: a program for the calculation of the top-pair cross-section at hadron colliders	CPC 185 (2014) 2930	1112.5675
97	M. L. Mangano, M. Moretti, F. Piccinini, and M. Treccani	Matching matrix elements and shower evolution for top-pair production in hadronic collisions	JHEP 01 (2007) 013	hep-ph/0611129
98	CMS Collaboration	Event generator tunes obtained from underlying event and multiparton scattering measurements	EPJC 76 (2016) 155	CMS-GEN-14-001 1512.00815
99	CMS Collaboration	Extraction and validation of a new set of CMS PYTHIA8 tunes from underlying-event measurements	EPJC 80 (2020) 4	CMS-GEN-17-001 1903.12179
100	NNPDF Collaboration	Parton distributions with QED corrections	NPB 877 (2013) 290	1308.0598
101	NNPDF Collaboration	Parton distributions from high-precision collider data	EPJC 77 (2017) 663	1706.00428
102	GEANT4 Collaboration	GEANT4--a simulation toolkit	NIMA 506 (2003) 250
103	S. Abdullin et al.	The fast simulation of the CMS detector at LHC	J. Phys. Conf. Ser. 331 (2011) 032049
104	A. Giammanco	The fast simulation of the CMS experiment	J. Phys. Conf. Ser. 513 (2014) 022012
105	CMS Collaboration	Measurement of differential cross sections for top quark pair production using the lepton+jets final state in proton-proton collisions at 13 TeV	PRD 95 (2017) 092001	CMS-TOP-16-008 1610.04191
106	CMS Collaboration	Particle-flow reconstruction and global event description with the CMS detector	JINST 12 (2017) P10003	CMS-PRF-14-001 1706.04965
107	CMS Collaboration	Performance of missing transverse momentum reconstruction in proton-proton collisions at $ \sqrt{s} = $ 13 TeV using the CMS detector	JINST 14 (2019) P07004	CMS-JME-17-001 1903.06078
108	M. Cacciari, G. P. Salam, and G. Soyez	The anti-$ {k_{\mathrm{T}}} $ jet clustering algorithm	JHEP 04 (2008) 063	0802.1189
109	M. Cacciari, G. P. Salam, and G. Soyez	FastJet user manual	EPJC 72 (2012) 1896	1111.6097
110	CMS Collaboration	Pileup mitigation at CMS in 13 TeV data	JINST 15 (2020) P09018	CMS-JME-18-001 2003.00503
111	M. Cacciari and G. P. Salam	Pileup subtraction using jet areas	PLB 659 (2008) 119	0707.1378
112	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
113	CMS Collaboration	Measurement of $ B\overline{B} $ angular correlations based on secondary vertex reconstruction at $ \sqrt{s}= $ 7 TeV	JHEP 03 (2011) 136	CMS-BPH-10-010 1102.3194
114	D. Bertolini, P. Harris, M. Low, and N. Tran	Pileup per particle identification	JHEP 10 (2014) 059	1407.6013
115	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
116	CMS Collaboration	Performance of the CMS muon detector and muon reconstruction with proton-proton collisions at $ \sqrt{s}= $ 13 TeV	JINST 13 (2018) P06015	CMS-MUO-16-001 1804.04528
117	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
118	CMS Collaboration	Performance of reconstruction and identification of $ \tau $ leptons in their decays to hadrons and $ \nu_{\tau} $ in LHC Run-2	CMS-PAS-TAU-16-002	CMS-PAS-TAU-16-002
119	CMS Collaboration	Performance of photon reconstruction and identification with the CMS detector in proton-proton collisions at $ \sqrt{s}= $ 8 TeV	JINST 10 (2015) P08010	CMS-EGM-14-001 1502.02702
120	CMS Collaboration	Performance of quark/gluon discrimination in 8 TeV pp data	CMS-PAS-JME-13-002	CMS-PAS-JME-13-002
121	Y. Ganin et al.	Domain-adversarial training of neural networks	in Domain Adaptation in Computer Vision Applications, G. Csurka, ed., Advances in Computer Vision and Pattern Recognition, Springer, Cham, Switzerland	1505.07818
122	CMS Collaboration	A deep neural network to search for new long-lived particles decaying to jets	Mach. Learn. Sci. Tech. 1 (2020) 035012	CMS-EXO-19-011 1912.12238
123	CMS Collaboration	Measurement of top quark pair production in association with a Z boson in proton-proton collisions at $ \sqrt{s} = $ 13 TeV	JHEP 03 (2020) 056	CMS-TOP-18-009 1907.11270
124	A. L. Read	Presentation of search results: The $ \mathrm{CL_s} $ technique	JPG 28 (2002) 2693
125	T. Junk	Confidence level computation for combining searches with small statistics	NIMA 434 (1999) 435	hep-ex/9902006
126	G. Cowan, K. Cranmer, E. Gross, and O. Vitells	Asymptotic formulae for likelihood-based tests of new physics	EPJC 71 (2011) 1554	1007.1727
127	R. J. Barlow and C. Beeston	Fitting using finite Monte Carlo samples	CPC 77 (1993) 219
128	ATLAS Collaboration	Measurements of top-quark pair spin correlations in the $ e\mu $ channel at $ \sqrt{s} = $ 13 TeV using $ pp $ collisions in the ATLAS detector	EPJC 80 (2020) 754	1903.07570
129	ALEPH Collaboration	Search for scalar quarks in $ e^{+} e^{-} $ collisions at $ \sqrt{s} $ up to 209 GeV	PLB 537 (2002) 5	hep-ex/0204036
130	DELPHI Collaboration	Searches for supersymmetric particles in $ e^{+} e^{-} $ collisions up to 208 GeV and interpretation of the results within the MSSM	EPJC 31 (2003) 421	hep-ex/0311019
131	L3 Collaboration	Search for scalar leptons and scalar quarks at LEP	PLB 580 (2004) 37	hep-ex/0310007
132	OPAL Collaboration	Search for scalar top and scalar bottom quarks at LEP	PLB 545 (2002) 272	hep-ex/0209026