Data vs. the ABCD method background prediction for 2017 in $\mathrm{SR_{b}^{mm}}$. Events are divided by the bin width, hence fractional data counts. Error bars show statistical uncertainties of data. The blue band shows the propagated uncertainty of all individual fit variations in a given bin, which we consider to be uncorrelated. The lower panels show the ratio of the observed data to the background estimation.

Data vs. the ABCD method background prediction for 2018 in $\mathrm{SR_{b}^{mm}}$. Events are divided by the bin width, hence fractional data counts. Error bars show statistical uncertainties of data. The blue band shows the propagated uncertainty of all individual fit variations in a given bin, which we consider to be uncorrelated. The lower panels show the ratio of the observed data to the background estimation.

Data vs. the ABCD method background prediction for 2016 in $\mathrm{SR_{b+\textrm{j}/b}^{mm}}$. Events are divided by the bin width, hence fractional data counts. Error bars show statistical uncertainties of data. The blue band shows the propagated uncertainty of all individual fit variations in a given bin, which we consider to be uncorrelated. The lower panels show the ratio of the observed data to the background estimation.

Data vs. the ABCD method background prediction for 2017 in $\mathrm{SR_{b+\textrm{j}/b}^{mm}}$. Events are divided by the bin width, hence fractional data counts. Error bars show statistical uncertainties of data. The blue band shows the propagated uncertainty of all individual fit variations in a given bin, which we consider to be uncorrelated. The lower panels show the ratio of the observed data to the background estimation.

Data vs. the ABCD method background prediction for 2018 in $\mathrm{SR_{b+\textrm{j}/b}^{mm}}$. Events are divided by the bin width, hence fractional data counts. Error bars show statistical uncertainties of data. The blue band shows the propagated uncertainty of all individual fit variations in a given bin, which we consider to be uncorrelated. The lower panels show the ratio of the observed data to the background estimation.

The asymptotic 95% CL limits on the product of cross section ($\sigma$), branching fraction into a pair of muons ($\mathcal{B}$) to dimuons, acceptance (A), and efficiency ($\epsilon$) in $\mathrm{SR_{b}^{mm}}$. A combination of both limits depends on the relative acceptance contributions in each region and is omitted here.

The asymptotic 95% CL limits on the product of cross section ($\sigma$), branching fraction into a pair of muons ($\mathcal{B}$) to dimuons, acceptance (A), and efficiency ($\epsilon$) in $\mathrm{SR_{b+\textrm{j}/b}^{mm}}$. A combination of both limits depends on the relative acceptance contributions in each region and is omitted here.

Cutflow for signal samples in 2016. Samples are divided by generated mass, signal region, and the b to s quark flavor changing coupling of the $Z^\prime$, dbs. For some mass values, multiple values of this coupling strength have been generated. It is described in this minimal lagrangian: $\mathcal{L} \supset Z^{\prime}_{\eta} \Big[ g_{\mu}\, \bar{\mu}\, \gamma^{\eta}\, \mu + \big( g_b\, \delta_{bs}\, \bar{s}\, \gamma^{\eta}\, P_{L}\, b + \text{h.c.} \big) \Big]$. The cutflow shows the selection into signal regions, and then the effects of specialized HTLT and RelMET selections, which grow with greater mass.

Cutflow for signal samples in 2017. Samples are divided by generated mass, signal region, and the b to s quark flavor changing coupling of the $Z^\prime$, dbs. For some mass values, multiple values of this coupling strength have been generated. It is described in this minimal lagrangian: $\mathcal{L} \supset Z^{\prime}_{\eta} \Big[ g_{\mu}\, \bar{\mu}\, \gamma^{\eta}\, \mu + \big( g_b\, \delta_{bs}\, \bar{s}\, \gamma^{\eta}\, P_{L}\, b + \text{h.c.} \big) \Big]$. The cutflow shows the selection into signal regions, and then the effects of specialized HTLT and RelMET selections, which grow with greater mass.

Cutflow for signal samples in 2018. Samples are divided by generated mass, signal region, and the b to s quark flavor changing coupling of the $Z^\prime$, dbs. For some mass values, multiple values of this coupling strength have been generated. It is described in this minimal lagrangian: $\mathcal{L} \supset Z^{\prime}_{\eta} \Big[ g_{\mu}\, \bar{\mu}\, \gamma^{\eta}\, \mu + \big( g_b\, \delta_{bs}\, \bar{s}\, \gamma^{\eta}\, P_{L}\, b + \text{h.c.} \big) \Big]$. The cutflow shows the selection into signal regions, and then the effects of specialized HTLT and RelMET selections, which grow with greater mass.

The groomed momentum balance distribution of b jets.

The jet fragmentation function distribution of b jets.

The b jet to inclusive jet ratio of the groomed jet radius distributions.

The b jet to inclusive jet ratio of the groomed momentum balance distributions.

Measured $\frac{d\sigma}{d(-t^{\prime})}~[\mathrm{nb/GeV^{2}}]$ for reaction $\gamma p\to \{\Lambda \bar{\Lambda}\} p$ including data of $6.5 \leq E_{\gamma} \leq 11.5$ [GeV], splitted in 10 energy bins (each as a column in the table). The observable $(-t^{\prime})$ is in unit of $[\mathrm{nb/GeV^{2}}]$ and is divided into bins of width 0.03 $[\mathrm{GeV^{2}}]$ (each as a row in the table). The global systematic uncertainty is 19% (not included in the table), with contributions of 5% from kinematic fitting, 10% from data selection, 5% from flux normalization, 13% from tracking efficiency, 3% from model dependence, and 6% from run-period variations.

Measured $\frac{d\sigma}{d(-t^{\prime})}~[\mathrm{nb/GeV^{2}}]$ for reaction $\gamma p\to \{p \bar{\Lambda}\} \Lambda$ including data of $6.5 \leq E_{\gamma} \leq 11.5$ [GeV], splitted in 10 energy bins (each as a column in the table). The observable $(-t^{\prime})$ is in unit of $[\mathrm{nb/GeV^{2}}]$ and is divided into bins of width 0.075 $[\mathrm{GeV^{2}}]$ (each as a row in the table). The global systematic uncertainty is 22% (not included in the table), with contributions of 2% from kinematic fitting, 10% from data selection, 5% from flux normalization, 15% from tracking efficiency, 3% from model dependence, and 10% from run-period variations.

Measured $\frac{d\sigma}{d(-t^{\prime})}~[\mathrm{nb/GeV^{2}}]$ for reaction $\gamma p\to \{p \bar{p}\} p$ including data of $6.5 \leq E_{\gamma} \leq 11.5$ [GeV], splitted in 10 energy bins (each as a column in the table). The observable $(-t^{\prime})$ is in unit of $[\mathrm{nb/GeV^{2}}]$ and is divided into bins of width 0.01 $[\mathrm{GeV^{2}}]$ (each as a row in the table). The global systematic uncertainty is 13% (not included in the table), with contributions of 8% from kinematic fitting, 4% from data selection, 5% from flux normalization, 8% from tracking efficiency, 3% from model dependence, and 1% from run-period variations.

Measured $\frac{d\sigma}{d(-t^{\prime})}~[\mathrm{nb/GeV^{2}}]$ for reaction $\gamma p\to \{p \bar{p}\} p$ including data of $3.5 \leq E_{\gamma} \leq 6.0$ [GeV], splitted in 5 energy bins (each as a column in the table). The observable $(-t^{\prime})$ is in unit of $[\mathrm{nb/GeV^{2}}]$ and is divided into bins of width 0.1 $[\mathrm{GeV^{2}}]$ (each as a row in the table). The global systematic uncertainty is 13% (not included in the table), with contributions of 8% from kinematic fitting, 4% from data selection, 5% from flux normalization, 8% from tracking efficiency, 3% from model dependence, and 1% from run-period variations.

Measured total cross section $\sigma(\gamma\,p\to\{\Lambda\bar{\Lambda}\}p)$ in unit of [nb] with beam energy in the range $5.0 < E_{\gamma} < 11.5~[\mathrm{GeV}]$ with various bin width. The table only includes point-to-point statistical uncertainties. The global systematic uncertainty is 19% (not included in the table), with contributions of 5% from kinematic fitting, 10% from data selection, 5% from flux normalization, 13% from tracking efficiency, 3% from model dependence, and 6% from run-period variations.

Measured total cross section $\sigma(\gamma\,p\to\{p\bar{\Lambda}\}\Lambda)$ in unit of [nb] with beam energy in the range $5.0 < E_{\gamma} < 11.5~[\mathrm{GeV}]$ with various bin width. The table only includes point-to-point statistical uncertainties. The global systematic uncertainty is 22% (not included in the table), with contributions of 2% from kinematic fitting, 10% from data selection, 5% from flux normalization, 15% from tracking efficiency, 3% from model dependence, and 10% from run-period variations.

Measured total cross section $\sigma(\gamma\,p\to\{p\bar{p}\}p)$ in unit of [nb] with beam energy in the range $3.5 < E_{\gamma} < 11.5~[\mathrm{GeV}]$ with various bin width. The table only includes point-to-point statistical uncertainties. The global systematic uncertainty is 13% (not included in the table), with contributions of 8% from kinematic fitting, 4% from data selection, 5% from flux normalization, 8% from tracking efficiency, 3% from model dependence, and 1% from run-period variations.

95&percnt; CL upper limits as a function of (left) c&tau;_{&pi;_d} and (right) M_&phi;. The upper plots show the expected and observed limits on &sigma;(pp &rarr;&phi;^&dagger;&phi;) for m_{&pi;_d} = 20&nbsp;GeV: (a) using M_&phi; = 1.6&nbsp;TeV and (b) using c&tau;_{&pi;_d} = 20&nbsp;mm. The lower plots show a comparison of the observed limits for all three dark pion masses: (c) using M_&phi; = 1.4&nbsp;TeV, and (d) using c&tau;_{&pi;_d} = 1&nbsp;mm. The mediator mass-dependent theoretical cross-section is given with the band corresponding to the uncertainty from NNLL-Fast.

95&percnt; CL upper limits as a function of (left) c&tau;_{&pi;_d} and (right) M_&phi;. The upper plots show the expected and observed limits on &sigma;(pp &rarr;&phi;^&dagger;&phi;) for m_{&pi;_d} = 20&nbsp;GeV: (a) using M_&phi; = 1.6&nbsp;TeV and (b) using c&tau;_{&pi;_d} = 20&nbsp;mm. The lower plots show a comparison of the observed limits for all three dark pion masses: (c) using M_&phi; = 1.4&nbsp;TeV, and (d) using c&tau;_{&pi;_d} = 1&nbsp;mm. The mediator mass-dependent theoretical cross-section is given with the band corresponding to the uncertainty from NNLL-Fast.

95&percnt; CL exclusion contours as a function of M_&phi; and c&tau;_{&pi;_d}. The expected and observed limits on &sigma;(pp &rarr;&phi;^&dagger;&phi;) are shown for (a) m_{&pi;_d} = 5&nbsp;GeV, (b) m_{&pi;_d} = 10&nbsp;GeV, and (c) m_{&pi;_d} = 20&nbsp;GeV. A comparison of the observed limits is given in (d) for each of the three dark pion masses.

95&percnt; CL exclusion contours as a function of M_&phi; and c&tau;_{&pi;_d}. The expected and observed limits on &sigma;(pp &rarr;&phi;^&dagger;&phi;) are shown for (a) m_{&pi;_d} = 5&nbsp;GeV, (b) m_{&pi;_d} = 10&nbsp;GeV, and (c) m_{&pi;_d} = 20&nbsp;GeV. A comparison of the observed limits is given in (d) for each of the three dark pion masses.

95&percnt; CL exclusion contours as a function of M_&phi; and c&tau;_{&pi;_d}. The expected and observed limits on &sigma;(pp &rarr;&phi;^&dagger;&phi;) are shown for (a) m_{&pi;_d} = 5&nbsp;GeV, (b) m_{&pi;_d} = 10&nbsp;GeV, and (c) m_{&pi;_d} = 20&nbsp;GeV. A comparison of the observed limits is given in (d) for each of the three dark pion masses.

95&percnt; CL exclusion contours as a function of M_&phi; and c&tau;_{&pi;_d}. The expected and observed limits on &sigma;(pp &rarr;&phi;^&dagger;&phi;) are shown for (a) m_{&pi;_d} = 5&nbsp;GeV, (b) m_{&pi;_d} = 10&nbsp;GeV, and (c) m_{&pi;_d} = 20&nbsp;GeV. A comparison of the observed limits is given in (d) for each of the three dark pion masses.

Comparison of the 95&percnt; CL exclusion contours between ATLAS and CMS&nbsp; for (a) models with m_{&pi;_d} = 10&nbsp;GeV and (b) models with m_{&pi;_d} = 20&nbsp;GeV. The expected and observed limits are shown for ATLAS, while only the observed limits in both the model agnostic and GNN cases are included for CMS. The expected limits from the CMS result are omitted, but are, in general, very close to the CMS observed limits.

Comparison of the 95&percnt; CL exclusion contours between ATLAS and CMS&nbsp; for (a) models with m_{&pi;_d} = 10&nbsp;GeV and (b) models with m_{&pi;_d} = 20&nbsp;GeV. The expected and observed limits are shown for ATLAS, while only the observed limits in both the model agnostic and GNN cases are included for CMS. The expected limits from the CMS result are omitted, but are, in general, very close to the CMS observed limits.

Normalized minPTF distribution in data, with three selected signal samples for comparison

95&percnt; CL exclusion contours as a function of M_&phi; and c&tau;_{&pi;_d} for the Cut-Based analysis. The expected and observed limits on &sigma;(pp &rarr;&phi;^&dagger;&phi;) are shown for (a) m_{&pi;_d} = 5&nbsp;GeV, (b) m_{&pi;_d} = 10&nbsp;GeV, and (c) m_{&pi;_d} = 20&nbsp;GeV. A comparison of the observed limits is given in (d) for each of the three dark pion masses.

95&percnt; CL exclusion contours as a function of M_&phi; and c&tau;_{&pi;_d} for the Cut-Based analysis. The expected and observed limits on &sigma;(pp &rarr;&phi;^&dagger;&phi;) are shown for (a) m_{&pi;_d} = 5&nbsp;GeV, (b) m_{&pi;_d} = 10&nbsp;GeV, and (c) m_{&pi;_d} = 20&nbsp;GeV. A comparison of the observed limits is given in (d) for each of the three dark pion masses.

95&percnt; CL exclusion contours as a function of M_&phi; and c&tau;_{&pi;_d} for the Cut-Based analysis. The expected and observed limits on &sigma;(pp &rarr;&phi;^&dagger;&phi;) are shown for (a) m_{&pi;_d} = 5&nbsp;GeV, (b) m_{&pi;_d} = 10&nbsp;GeV, and (c) m_{&pi;_d} = 20&nbsp;GeV. A comparison of the observed limits is given in (d) for each of the three dark pion masses.

95&percnt; CL exclusion contours as a function of M_&phi; and c&tau;_{&pi;_d} for the Cut-Based analysis. The expected and observed limits on &sigma;(pp &rarr;&phi;^&dagger;&phi;) are shown for (a) m_{&pi;_d} = 5&nbsp;GeV, (b) m_{&pi;_d} = 10&nbsp;GeV, and (c) m_{&pi;_d} = 20&nbsp;GeV. A comparison of the observed limits is given in (d) for each of the three dark pion masses.

Comparison of observed and expected 95&percnt; CL limits of the Cut-Based analysis against the corresponding BDT-based analysis. Limits on &sigma;(pp &rarr;&phi;^&dagger;&phi;) are shown as a function of M_&phi; and c&tau;_{&pi;_d} for (a) m_{&pi;_d} = 5&nbsp;GeV, (b) m_{&pi;_d} = 10&nbsp;GeV, and (c) m_{&pi;_d} = 20&nbsp;GeV.

Comparison of observed and expected 95&percnt; CL limits of the Cut-Based analysis against the corresponding BDT-based analysis. Limits on &sigma;(pp &rarr;&phi;^&dagger;&phi;) are shown as a function of M_&phi; and c&tau;_{&pi;_d} for (a) m_{&pi;_d} = 5&nbsp;GeV, (b) m_{&pi;_d} = 10&nbsp;GeV, and (c) m_{&pi;_d} = 20&nbsp;GeV.

Comparison of observed and expected 95&percnt; CL limits of the Cut-Based analysis against the corresponding BDT-based analysis. Limits on &sigma;(pp &rarr;&phi;^&dagger;&phi;) are shown as a function of M_&phi; and c&tau;_{&pi;_d} for (a) m_{&pi;_d} = 5&nbsp;GeV, (b) m_{&pi;_d} = 10&nbsp;GeV, and (c) m_{&pi;_d} = 20&nbsp;GeV.

Normalized event-level BDT response distribution in data, with three selected signal samples for comparison.

Normalized jet-matched displaced vertex multiplicity (N_DV) distribution in data, with three selected signal samples for comparison.

Normalized event-level BDT response distribution in data, with three selected signal samples for comparison. All three signal models have M_&phi; = 1.8&nbsp;TeV and c&tau;_{&pi;_d} = 75&nbsp;mm, but different m_{&pi;_d}.

Normalized event-level BDT response distribution in data, with three selected signal samples for comparison. All three signal models have m_{&pi;_d} = 10&nbsp;GeV and c&tau;_{&pi;_d} = 20&nbsp;mm, but different M_&phi;.

Normalized event-level BDT response distribution in data, with three selected signal samples for comparison. All three signal models have m_{&pi;_d} = 10&nbsp;GeV and M_&phi; = 1.4&nbsp;TeV, but different c&tau;_{&pi;_d}.

Observed 95&percnt; CL limits for models with m_{&pi;_d} = 5, 10,&nbsp;and&nbsp;20&nbsp;GeV and c&tau;_{&pi;_d} = 1000 mm as a function of dark mediator mass. The mediator mass-dependent theoretical cross-section is given with the band corresponding to the uncertainty from NNLL-Fast.

Observed 95&percnt; CL limits for models with m_{&pi;_d} = 5, 10,&nbsp;and&nbsp;20&nbsp;GeV and c&tau;_{&pi;_d} = 500 mm as a function of dark mediator mass. The mediator mass-dependent theoretical cross-section is given with the band corresponding to the uncertainty from NNLL-Fast.

Observed 95&percnt; CL limits for models with m_{&pi;_d} = 5, 10,&nbsp;and&nbsp;20&nbsp;GeV and c&tau;_{&pi;_d} = 300 mm as a function of dark mediator mass. The mediator mass-dependent theoretical cross-section is given with the band corresponding to the uncertainty from NNLL-Fast.

Observed 95&percnt; CL limits for models with m_{&pi;_d} = 5, 10,&nbsp;and&nbsp;20&nbsp;GeV and c&tau;_{&pi;_d} = 150 mm as a function of dark mediator mass. The mediator mass-dependent theoretical cross-section is given with the band corresponding to the uncertainty from NNLL-Fast.

Observed 95&percnt; CL limits for models with m_{&pi;_d} = 5, 10,&nbsp;and&nbsp;20&nbsp;GeV and c&tau;_{&pi;_d} = 75 mm as a function of dark mediator mass. The mediator mass-dependent theoretical cross-section is given with the band corresponding to the uncertainty from NNLL-Fast.

Observed 95&percnt; CL limits for models with m_{&pi;_d} = 5, 10,&nbsp;and&nbsp;20&nbsp;GeV and c&tau;_{&pi;_d} = 20 mm as a function of dark mediator mass. The mediator mass-dependent theoretical cross-section is given with the band corresponding to the uncertainty from NNLL-Fast.

Observed 95&percnt; CL limits for models with m_{&pi;_d} = 5, 10,&nbsp;and&nbsp;20&nbsp;GeV and c&tau;_{&pi;_d} = 5 mm as a function of dark mediator mass. The mediator mass-dependent theoretical cross-section is given with the band corresponding to the uncertainty from NNLL-Fast.

Observed 95&percnt; CL limit for models with m_{&pi;_d} = 5, 10,&nbsp;and&nbsp;20&nbsp;GeV and c&tau;_{&pi;_d} = 2 mm as a function of dark mediator mass. The mediator mass-dependent theoretical cross-section is given with the band corresponding to the uncertainty from NNLL-Fast.

Observed 95&percnt; CL limits for models with m_{&pi;_d} = 5, 10,&nbsp;and&nbsp;20&nbsp;GeV and c&tau;_{&pi;_d} = 1 mm as a function of dark mediator mass. The mediator mass-dependent theoretical cross-section is given with the band corresponding to the uncertainty from NNLL-Fast.

Observed 95&percnt; CL limits for models with m_{&pi;_d} = 5, 10,&nbsp;and&nbsp;20&nbsp;GeV and M_&phi; = 2.2&nbsp;TeV as a function of dark pion lifetime. The mediator mass-dependent theoretical cross-section is given with the band corresponding to the uncertainty from NNLL-Fast.

Observed 95&percnt; CL limits for models with m_{&pi;_d} = 5, 10,&nbsp;and&nbsp;20&nbsp;GeV and M_&phi; = 2&nbsp;TeV as a function of dark pion lifetime. The mediator mass-dependent theoretical cross-section is given with the band corresponding to the uncertainty from NNLL-Fast.

Observed 95&percnt; CL limits for models with m_{&pi;_d} = 5, 10,&nbsp;and&nbsp;20&nbsp;GeV and M_&phi; = 1.8&nbsp;TeV as a function of dark pion lifetime. The mediator mass-dependent theoretical cross-section is given with the band corresponding to the uncertainty from NNLL-Fast.

Observed 95&percnt; CL limits for models with m_{&pi;_d} = 5, 10,&nbsp;and&nbsp;20&nbsp;GeV and M_&phi; = 1.6&nbsp;TeV as a function of dark pion lifetime. The mediator mass-dependent theoretical cross-section is given with the band corresponding to the uncertainty from NNLL-Fast.

Observed 95&percnt; CL limits for models with m_{&pi;_d} = 5, 10,&nbsp;and&nbsp;20&nbsp;GeV and M_&phi; = 1.4&nbsp;TeV as a function of dark pion lifetime. The mediator mass-dependent theoretical cross-section is given with the band corresponding to the uncertainty from NNLL-Fast.

Observed 95&percnt; CL limits for models with m_{&pi;_d} = 5, 10,&nbsp;and&nbsp;20&nbsp;GeV and M_&phi; = 1&nbsp;TeV as a function of dark pion lifetime. The mediator mass-dependent theoretical cross-section is given with the band corresponding to the uncertainty from NNLL-Fast.

Observed and expected 95&percnt; CL limits for models with m_{&pi;_d} = 20&nbsp;GeV as a function of M_&phi; and c&tau;_{&pi;_d}.

Observed and expected 95&percnt; CL limits for models with m_{&pi;_d} = 20&nbsp;GeV as a function of M_&phi; and c&tau;_{&pi;_d}.

Observed and expected 95&percnt; CL limits for models with m_{&pi;_d} = 20&nbsp;GeV as a function of M_&phi; and c&tau;_{&pi;_d}.

Observed and expected 95&percnt; CL limits for models with m_{&pi;_d} = 20&nbsp;GeV as a function of M_&phi; and c&tau;_{&pi;_d}.

Observed and expected 95&percnt; CL limits for models with m_{&pi;_d} = 20&nbsp;GeV as a function of M_&phi; and c&tau;_{&pi;_d}.

Observed and expected 95&percnt; CL limits for models with m_{&pi;_d} = 20&nbsp;GeV as a function of M_&phi; and c&tau;_{&pi;_d}.

Cut-Flow efficiencies for the m_{&pi;_d} = 10&nbsp;GeV, M_&phi; = 1600&nbsp;GeV models for all cuts before entering the Search region (ABCD plane) and then for each of the ABCD regions separately.

Cut-Flow efficiencies for the m_{&pi;_d} = 10&nbsp;GeV, M_&phi; = 1400&nbsp;GeV models for all cuts before entering the Search region (ABCD plane) and then for each of the ABCD regions separately.

Cut-Flow efficiencies for the m_{&pi;_d} = 10&nbsp;GeV, M_&phi; = 1000&nbsp;GeV models for all cuts before entering the Search region (ABCD plane) and then for each of the ABCD regions separately.

Cut-Flow efficiencies for the m_{&pi;_d} = 5&nbsp;GeV, M_&phi; = 2200&nbsp;GeV models for all cuts before entering the Search region (ABCD plane) and then for each of the ABCD regions separately.

Cut-Flow efficiencies for the m_{&pi;_d} = 5&nbsp;GeV, M_&phi; = 2000&nbsp;GeV models for all cuts before entering the Search region (ABCD plane) and then for each of the ABCD regions separately.

Cut-Flow efficiencies for the m_{&pi;_d} = 5&nbsp;GeV, M_&phi; = 1800&nbsp;GeV models for all cuts before entering the Search region (ABCD plane) and then for each of the ABCD regions separately.

Cut-Flow efficiencies for the m_{&pi;_d} = 5&nbsp;GeV, M_&phi; = 1600&nbsp;GeV models for all cuts before entering the Search region (ABCD plane) and then for each of the ABCD regions separately.

Cut-Flow efficiencies for the m_{&pi;_d} = 5&nbsp;GeV, M_&phi; = 1400&nbsp;GeV models for all cuts before entering the Search region (ABCD plane) and then for each of the ABCD regions separately.

Cut-Flow efficiencies for the m_{&pi;_d} = 5&nbsp;GeV, M_&phi; = 1000&nbsp;GeV models for all cuts before entering the Search region (ABCD plane) and then for each of the ABCD regions separately.

Cut-Flow efficiencies for the m_{&pi;_d} = 20&nbsp;GeV, M_&phi; = 2200&nbsp;GeV models for all cuts before entering the Search region (ABCD plane) and then for each of the ABCD regions separately.

Cut-Flow efficiencies for the m_{&pi;_d} = 20&nbsp;GeV, M_&phi; = 2000&nbsp;GeV models for all cuts before entering the Search region (ABCD plane) and then for each of the ABCD regions separately.

Cut-Flow efficiencies for the m_{&pi;_d} = 20&nbsp;GeV, M_&phi; = 1800&nbsp;GeV models for all cuts before entering the Search region (ABCD plane) and then for each of the ABCD regions separately.

Cut-Flow efficiencies for the m_{&pi;_d} = 20&nbsp;GeV, M_&phi; = 1600&nbsp;GeV models for all cuts before entering the Search region (ABCD plane) and then for each of the ABCD regions separately.

Cut-Flow efficiencies for the m_{&pi;_d} = 20&nbsp;GeV, M_&phi; = 1400&nbsp;GeV models for all cuts before entering the Search region (ABCD plane) and then for each of the ABCD regions separately.

Cut-Flow efficiencies for the m_{&pi;_d} = 20&nbsp;GeV, M_&phi; = 1000&nbsp;GeV models for all cuts before entering the Search region (ABCD plane) and then for each of the ABCD regions separately.

Cut-Flow efficiencies for the m_{&pi;_d} = 10&nbsp;GeV, M_&phi; = 2200&nbsp;GeV models for all cuts before entering the Search region (ABCD plane) and then for each of the ABCD regions separately.

Cut-Flow efficiencies for the m_{&pi;_d} = 10&nbsp;GeV, M_&phi; = 2000&nbsp;GeV models for all cuts before entering the Search region (ABCD plane) and then for each of the ABCD regions separately.

Cut-Flow efficiencies for the m_{&pi;_d} = 10&nbsp;GeV, M_&phi; = 1800&nbsp;GeV models for all cuts before entering the Search region (ABCD plane) and then for each of the ABCD regions separately.

Observed (black markers) and expected distributions of number of jets after event selection. The hatched (grey) areas denote the systematic (total) uncertainties in the expected yields. Events from all data-taking periods and all channels are combined. The lower panel of each plot shows the ratio between observed and expected distributions. The last bin includes all events above the plotted range. The entry Background corresponds to the sum of all the SM predictions.

Observed (black markers) and expected distributions of number of b tagged jets after event selection. The hatched (grey) areas denote the systematic (total) uncertainties in the expected yields. Events from all data-taking periods and all channels are combined. The lower panel of each plot shows the ratio between observed and expected distributions. The last bin includes all events above the plotted range. The entry Background corresponds to the sum of all the SM predictions.

Difference between $p_{\mathrm{T,gen.}}^\text{miss}$ and $p_{\mathrm{T,rec.}}^\text{miss}$ as a function of the $p_{\mathrm{T,gen.}}^\text{miss}$ for signal events. The mean difference between the generated and the $p_{\mathrm{T,rec.}}^\text{miss}$ per bin is shown as solid line. The results for $p_{\mathrm{T}}^\text{miss}$ corrected by the DNN regression (light blue), derived with the PUPPI algorithm (red), and the PF algorithm (orange) are shown. A simulated sample for the 2018 data-taking period is used.

Difference between $p_{\mathrm{T,gen.}}^\text{miss}$ and $p_{\mathrm{T,rec.}}^\text{miss}$ as a function of the $p_{\mathrm{T,gen.}}^\text{miss}$ for signal events. The dashed line shows the standard deviation $\sigma$, which corresponds to the resolution of the $p_{\mathrm{T,gen.}}^\text{miss}$ and $p_{\mathrm{T,rec.}}^\text{miss}$ difference. The results for $p_{\mathrm{T}}^\text{miss}$ corrected by the DNN regression (light blue), derived with the PUPPI algorithm (red), and the PF algorithm (orange) are shown. A simulated sample for the 2018 data-taking period is used.

Difference between $p_{\mathrm{T,gen.}}^\text{miss}$ and $p_{\mathrm{T,rec.}}^\text{miss}$ as a function of the number of primary vertices for signal events. The mean difference between the generated and the $p_{\mathrm{T,rec.}}^\text{miss}$ per bin is shown as solid line. The results for $p_{\mathrm{T}}^\text{miss}$ corrected by the DNN regression (light blue), derived with the PUPPI algorithm (red), and the PF algorithm (orange) are shown. A simulated sample for the 2018 data-taking period is used.

Difference between $p_{\mathrm{T,gen.}}^\text{miss}$ and $p_{\mathrm{T,rec.}}^\text{miss}$ as a function of the $p_{\mathrm{T,gen.}}^\text{miss}$ for signal events. The dashed line shows the standard deviation $\sigma$, which corresponds to the resolution of the $p_{\mathrm{T,gen.}}^\text{miss}$ and $p_{\mathrm{T,rec.}}^\text{miss}$ difference. The results for $p_{\mathrm{T}}^\text{miss}$ corrected by the DNN regression (light blue), derived with the PUPPI algorithm (red), and the PF algorithm (orange) are shown. A simulated sample for the 2018 data-taking period is used.

Results of the $\chi^{2}$ tests for the absolute and normalized differential cross section measurements for each of the predictions. The $\chi^{2}$ values including uncertainties on the predictions are given in parentheses in the table in the paper and in a separate column here.

The p-value of the $\chi^{2}$ tests for the absolute and normalized cross section measurements for each of the predictions. The resulting p-values including uncertainties on the predictions are given in parentheses in the table in the paper and in a separate column here.

Breakdown of the relative contribution from experimental uncertainties in the differential cross section measurement as a function of $p_{\text{T}}^{\nu\nu}$. The statistical uncertainty (dark grey) takes the size of the available simulated samples and the recorded data into account. The last bin includes all events above the plotted range.

Breakdown of the relative contribution from theory uncertainties in the differential cross section measurement as a function of $p_{\text{T}}^{\nu\nu}$. The statistical uncertainty (dark grey) takes the size of the available simulated samples and the recorded data into account. The last bin includes all events above the plotted range.

Breakdown of the relative contribution from experimental uncertainties in the differential cross section measurement as a function of $\text{min}[\Delta\phi(\vec{p}_{\text{T}}^{\nu\nu},\vec{p}_{\text{T}}^{\ell})]$. The statistical uncertainty (dark grey) takes the size of the available simulated samples and the recorded data into account. The last bin includes all events above the plotted range.

Breakdown of the relative contribution from theory uncertainties in the differential cross section measurement as a function of $\text{min}[\Delta\phi(\vec{p}_{\text{T}}^{\nu\nu},\vec{p}_{\text{T}}^{\ell})]$. The statistical uncertainty (dark grey) takes the size of the available simulated samples and the recorded data into account. The last bin includes all events above the plotted range.

Breakdown of the relative contribution from experimental uncertainties in the differential cross section measurement as a function of $p_{\text{T}}^{\nu\nu}$ and $\text{min}[\Delta\phi(\vec{p}_{\text{T}}^{\nu\nu},\vec{p}_{\text{T}}^{\ell})]$ for the azimuthal angle range 0<$\phi$<0.56. Each group of four bins corresponds to $p_{\text{T}}^{\nu\nu}$ bins, and $\text{min}[\Delta\phi(\vec{p}_{\text{T}}^{\nu\nu},\vec{p}_{\text{T}}^{\ell})]$ bin edges are indicated by vertical solid lines. The statistical uncertainty (dark grey) takes the size of the available simulated samples and the recorded data into account. The last bin includes all events above the plotted range.

Breakdown of the relative contribution from experimental uncertainties in the differential cross section measurement as a function of $p_{\text{T}}^{\nu\nu}$ and $\text{min}[\Delta\phi(\vec{p}_{\text{T}}^{\nu\nu},\vec{p}_{\text{T}}^{\ell})]$ for the azimuthal angle range 0.56<$\phi$<1.08. Each group of four bins corresponds to $p_{\text{T}}^{\nu\nu}$ bins, and $\text{min}[\Delta\phi(\vec{p}_{\text{T}}^{\nu\nu},\vec{p}_{\text{T}}^{\ell})]$ bin edges are indicated by vertical solid lines. The statistical uncertainty (dark grey) takes the size of the available simulated samples and the recorded data into account. The last bin includes all events above the plotted range.

Breakdown of the relative contribution from experimental uncertainties in the differential cross section measurement as a function of $p_{\text{T}}^{\nu\nu}$ and $\text{min}[\Delta\phi(\vec{p}_{\text{T}}^{\nu\nu},\vec{p}_{\text{T}}^{\ell})]$ for the azimuthal angle range 1.08<$\phi$<3.14. Each group of four bins corresponds to $p_{\text{T}}^{\nu\nu}$ bins, and $\text{min}[\Delta\phi(\vec{p}_{\text{T}}^{\nu\nu},\vec{p}_{\text{T}}^{\ell})]$ bin edges are indicated by vertical solid lines. The statistical uncertainty (dark grey) takes the size of the available simulated samples and the recorded data into account. The last bin includes all events above the plotted range.

Breakdown of the relative contribution from theory uncertainties in the differential cross section measurement as a function of $p_{\text{T}}^{\nu\nu}$ and $\text{min}[\Delta\phi(\vec{p}_{\text{T}}^{\nu\nu},\vec{p}_{\text{T}}^{\ell})]$ for the azimuthal angle range 0<$\phi$<0.56. Each group of four bins corresponds to $p_{\text{T}}^{\nu\nu}$ bins, and $\text{min}[\Delta\phi(\vec{p}_{\text{T}}^{\nu\nu},\vec{p}_{\text{T}}^{\ell})]$ bin edges are indicated by vertical solid lines. The statistical uncertainty (dark grey) takes the size of the available simulated samples and the recorded data into account. The last bin includes all events above the plotted range.

Breakdown of the relative contribution from theory uncertainties in the differential cross section measurement as a function of $p_{\text{T}}^{\nu\nu}$ and $\text{min}[\Delta\phi(\vec{p}_{\text{T}}^{\nu\nu},\vec{p}_{\text{T}}^{\ell})]$ for the azimuthal angle range 0.56<$\phi$<1.08. Each group of four bins corresponds to $p_{\text{T}}^{\nu\nu}$ bins, and $\text{min}[\Delta\phi(\vec{p}_{\text{T}}^{\nu\nu},\vec{p}_{\text{T}}^{\ell})]$ bin edges are indicated by vertical solid lines. The statistical uncertainty (dark grey) takes the size of the available simulated samples and the recorded data into account. The last bin includes all events above the plotted range.

Breakdown of the relative contribution from theory uncertainties in the differential cross section measurement as a function of $p_{\text{T}}^{\nu\nu}$ and $\text{min}[\Delta\phi(\vec{p}_{\text{T}}^{\nu\nu},\vec{p}_{\text{T}}^{\ell})]$ for the azimuthal angle range 1.08<$\phi$<3.14. Each group of four bins corresponds to $p_{\text{T}}^{\nu\nu}$ bins, and $\text{min}[\Delta\phi(\vec{p}_{\text{T}}^{\nu\nu},\vec{p}_{\text{T}}^{\ell})]$ bin edges are indicated by vertical solid lines. The statistical uncertainty (dark grey) takes the size of the available simulated samples and the recorded data into account. The last bin includes all events above the plotted range.

The observed (black markers) and simulated distributions of $p_{\mathrm{T,DNN}}^\text{miss}$ is shown. Events from all data-taking periods and all channels are combined. The hatched (grey) areas indicate the systematic (total) uncertainty in the simulation. The lower panel of each plot shows the ratio of observed data to the expectation from MC simulation in each bin. The last bin includes all events above the plotted range.

The observed (black markers) and simulated distributions of $\text{min}[\Delta\phi(\vec{p}_{\text{T, DNN}}^{\text{miss}},\vec{p}_{\text{T}}^{\ell})]$ is shown. Events from all data-taking periods and all channels are combined. The hatched (grey) areas indicate the systematic (total) uncertainty in the simulation. The lower panel of each plot shows the ratio of observed data to the expectation from MC simulation in each bin. The last bin includes all events above the plotted range.

The observed (black markers) and simulated two-dimensional distribution of $p_{\mathrm{T,DNN}}^\text{miss}$ and $\text{min}[\Delta\phi(\vec{p}_{\text{T, DNN}}^{\text{miss}},\vec{p}_{\text{T}}^{\ell})]$ for the azimuthal angle range 0<$\phi$<0.28 is shown. Events from all data-taking periods and all channels are combined. The hatched (grey) areas indicate the systematic (total) uncertainty in the simulation. The lower panel of each plot shows the ratio of observed data to the expectation from MC simulation in each bin. The last bin includes all events above the plotted range.

The observed (black markers) and simulated two-dimensional distribution of $p_{\mathrm{T,DNN}}^\text{miss}$ and $\text{min}[\Delta\phi(\vec{p}_{\text{T, DNN}}^{\text{miss}},\vec{p}_{\text{T}}^{\ell})]$ for the azimuthal angle range 0.28<$\phi$<0.56 is shown. Events from all data-taking periods and all channels are combined. The hatched (grey) areas indicate the systematic (total) uncertainty in the simulation. The lower panel of each plot shows the ratio of observed data to the expectation from MC simulation in each bin. The last bin includes all events above the plotted range.

The observed (black markers) and simulated two-dimensional distribution of $p_{\mathrm{T,DNN}}^\text{miss}$ and $\text{min}[\Delta\phi(\vec{p}_{\text{T, DNN}}^{\text{miss}},\vec{p}_{\text{T}}^{\ell})]$ for the azimuthal angle range 0.56<$\phi$<0.82 is shown. Events from all data-taking periods and all channels are combined. The hatched (grey) areas indicate the systematic (total) uncertainty in the simulation. The lower panel of each plot shows the ratio of observed data to the expectation from MC simulation in each bin. The last bin includes all events above the plotted range.

The observed (black markers) and simulated two-dimensional distribution of $p_{\mathrm{T,DNN}}^\text{miss}$ and $\text{min}[\Delta\phi(\vec{p}_{\text{T, DNN}}^{\text{miss}},\vec{p}_{\text{T}}^{\ell})]$ for the azimuthal angle range 0.82<$\phi$<1.08 is shown. Events from all data-taking periods and all channels are combined. The hatched (grey) areas indicate the systematic (total) uncertainty in the simulation. The lower panel of each plot shows the ratio of observed data to the expectation from MC simulation in each bin. The last bin includes all events above the plotted range.

The observed (black markers) and simulated two-dimensional distribution of $p_{\mathrm{T,DNN}}^\text{miss}$ and $\text{min}[\Delta\phi(\vec{p}_{\text{T, DNN}}^{\text{miss}},\vec{p}_{\text{T}}^{\ell})]$ for the azimuthal angle range 1.08<$\phi$<2.14 is shown. Events from all data-taking periods and all channels are combined. The hatched (grey) areas indicate the systematic (total) uncertainty in the simulation. The lower panel of each plot shows the ratio of observed data to the expectation from MC simulation in each bin. The last bin includes all events above the plotted range.

The observed (black markers) and simulated two-dimensional distribution of $p_{\mathrm{T,DNN}}^\text{miss}$ and $\text{min}[\Delta\phi(\vec{p}_{\text{T, DNN}}^{\text{miss}},\vec{p}_{\text{T}}^{\ell})]$ for the azimuthal angle range 2.14<$\phi$<3.2 is shown. Events from all data-taking periods and all channels are combined. The hatched (grey) areas indicate the systematic (total) uncertainty in the simulation. The lower panel of each plot shows the ratio of observed data to the expectation from MC simulation in each bin. The last bin includes all events above the plotted range.

Result of the closure test based on simulation accounting for potential BSM contributions based on a top squark pair production scenario with a stop mass of 525 GeV and a neutralino mass of 350 GeV. The potential BSM contribution is scaled by a factor of ten. The test is performed for the $p_{\text{T}}^{\nu\nu}$ using the nominal (black), the regularized (orange), and the bin-by-bin unfolding (purple), based on all data-taking periods combined. The unfolded distributions are compared to the expected distribution (red) based on the sum of the nominal dileptonic $t\bar{t}$ signal sample and BSM signal with the corresponding $\chi^2/\text{ndf}$ values given in the legend in square brackets. The distribution used for the response matrix, is shown in blue. The error bars correspond to the statistical uncertainty. The lower part shows the ratios between the unfolded and the expected distributions.

Result of the closure test based on simulation. The potential BSM contribution is scaled by a factor of ten. The test is performed for the 2D measurement of $p_{\text{T}}^{\nu\nu}$ and $\text{min}[\Delta\phi(\vec{p}_{\text{T}}^{\nu\nu},\vec{p}_{\text{T}}^{\ell})]$ in the azimuthal angle range 0<$\phi$<0.56 using the nominal (black), the regularized (orange), and the bin-by-bin unfolding (purple), based on all data-taking periods combined. The unfolded distributions are compared to the expected distribution (red) based on the sum of the nominal dileptonic $t\bar{t}$ signal sample and BSM signal with the corresponding $\chi^2/\text{ndf}$ values given in the legend. The nominal distribution, used for the response matrix, is shown in blue. The error bars correspond to the statistical uncertainty. The lower part shows the ratios between the unfolded and the expected distributions.

Result of the closure test based on simulation. The potential BSM contribution is scaled by a factor of ten. The test is performed for the 2D measurement of $p_{\text{T}}^{\nu\nu}$ and $\text{min}[\Delta\phi(\vec{p}_{\text{T}}^{\nu\nu},\vec{p}_{\text{T}}^{\ell})]$ in the azimuthal angle range 0.56<$\phi$<1.08 using the nominal (black), the regularized (orange), and the bin-by-bin unfolding (purple), based on all data-taking periods combined. The unfolded distributions are compared to the expected distribution (red) based on the sum of the nominal dileptonic $t\bar{t}$ signal sample and BSM signal with the corresponding $\chi^2/\text{ndf}$ values given in the legend. The nominal distribution, used for the response matrix, is shown in blue. The error bars correspond to the statistical uncertainty. The lower part shows the ratios between the unfolded and the expected distributions.

Result of the closure test based on simulation. The potential BSM contribution is scaled by a factor of ten. The test is performed for the 2D measurement of $p_{\text{T}}^{\nu\nu}$ and $\text{min}[\Delta\phi(\vec{p}_{\text{T}}^{\nu\nu},\vec{p}_{\text{T}}^{\ell})]$ in the azimuthal angle range 1.08<$\phi$<3.14 using the nominal (black), the regularized (orange), and the bin-by-bin unfolding (purple), based on all data-taking periods combined. The unfolded distributions are compared to the expected distribution (red) based on the sum of the nominal dileptonic $t\bar{t}$ signal sample and BSM signal with the corresponding $\chi^2/\text{ndf}$ values given in the legend. The nominal distribution, used for the response matrix, is shown in blue. The error bars correspond to the statistical uncertainty. The lower part shows the ratios between the unfolded and the expected distributions.

The measured differential signal cross section (black markers) as a function of $p_{\text{T}}^{\nu\nu}$ is shown. The theoretical predictions from POWHEG+PYTHIA (dark red), POWHEG+HERWIG (orange), MC@NLO+PYTHIA (purple), and the fixed-order NLO (light blue) and NNLO (brown) calculations are compared to the measurement. The total (statistical) uncertainty in the measurement is shown as an orange (dark grey) band. The lower panel of each plot shows the ratio between theoretical predictions and the measurement.

The measured differential signal cross section (black markers) as a function of $\text{min}[\Delta\phi(\vec{p}_{\text{T}}^{\nu\nu},\vec{p}_{\text{T}}^{\ell})]$ is shown. The theoretical predictions from POWHEG+PYTHIA (dark red), POWHEG+HERWIG (orange), MC@NLO+PYTHIA (purple), and the fixed-order NLO (light blue) and NNLO (brown) calculations are compared to the measurement. The total (statistical) uncertainty in the measurement is shown as an orange (dark grey) band. The lower panel of each plot shows the ratio between theoretical predictions and the measurement.

The measured two-dimensional differential signal cross section (black markers) as a function of $p_{\text{T}}^{\nu\nu}$ and $\text{min}[\Delta\phi(\vec{p}_{\text{T}}^{\nu\nu},\vec{p}_{\text{T}}^{\ell})]$ for the azimuthal angle range 0<$\phi$<0.56 is shown. The theoretical predictions from POWHEG+PYTHIA (dark red), POWHEG+HERWIG (orange), MC@NLO+PYTHIA (purple), and the fixed-order NLO (light blue) and NNLO (brown) calculations are compared to the measurement. The total (statistical) uncertainty in the measurement is shown as an orange (dark grey) band. The lower panel of each plot shows the ratio between theoretical predictions and the measurement.

The measured two-dimensional differential signal cross section (black markers) as a function of $p_{\text{T}}^{\nu\nu}$ and $\text{min}[\Delta\phi(\vec{p}_{\text{T}}^{\nu\nu},\vec{p}_{\text{T}}^{\ell})]$ for the azimuthal angle range 0.56<$\phi$<1.08 is shown. The theoretical predictions from POWHEG+PYTHIA (dark red), POWHEG+HERWIG (orange), MC@NLO+PYTHIA (purple), and the fixed-order NLO (light blue) and NNLO (brown) calculations are compared to the measurement. The total (statistical) uncertainty in the measurement is shown as an orange (dark grey) band. The lower panel of each plot shows the ratio between theoretical predictions and the measurement.

The measured two-dimensional differential signal cross section (black markers) as a function of $p_{\text{T}}^{\nu\nu}$ and $\text{min}[\Delta\phi(\vec{p}_{\text{T}}^{\nu\nu},\vec{p}_{\text{T}}^{\ell})]$ for the azimuthal angle range 1.08<$\phi$<3.14 is shown. The theoretical predictions from POWHEG+PYTHIA (dark red), POWHEG+HERWIG (orange), MC@NLO+PYTHIA (purple), and the fixed-order NLO (light blue) and NNLO (brown) calculations are compared to the measurement. The total (statistical) uncertainty in the measurement is shown as an orange (dark grey) band. The lower panel of each plot shows the ratio between theoretical predictions and the measurement.

The normalized measured differential signal cross section (black markers) as a function of $p_{\text{T}}^{\nu\nu}$ is shown. The theoretical predictions from POWHEG+PYTHIA (dark red), POWHEG+HERWIG (orange), MC@NLO+PYTHIA (purple), and the fixed-order NLO (light blue) and NNLO (brown) calculations are compared to the measurement. The total (statistical) uncertainty in the measurement is shown as an orange (dark grey) band. The lower panel of each plot shows the ratio between theoretical predictions and the measurement.

The normalized measured differential signal cross section (black markers) as a function of $\text{min}[\Delta\phi(\vec{p}_{\text{T}}^{\nu\nu},\vec{p}_{\text{T}}^{\ell})]$ is shown. The theoretical predictions from POWHEG+PYTHIA (dark red), POWHEG+HERWIG (orange), MC@NLO+PYTHIA (purple), and the fixed-order NLO (light blue) and NNLO (brown) calculations are compared to the measurement. The total (statistical) uncertainty in the measurement is shown as an orange (dark grey) band. The lower panel of each plot shows the ratio between theoretical predictions and the measurement.

The normalized measured two-dimensional differential signal cross section (black markers) as a function of $p_{\text{T}}^{\nu\nu}$ and $\text{min}[\Delta\phi(\vec{p}_{\text{T}}^{\nu\nu},\vec{p}_{\text{T}}^{\ell})]$ for the azimuthal angle range 0<$\phi$<0.56 is shown. The theoretical predictions from POWHEG+PYTHIA (dark red), POWHEG+HERWIG (orange), MC@NLO+PYTHIA (purple), and the fixed-order NLO (light blue) and NNLO (brown) calculations are compared to the measurement. The total (statistical) uncertainty in the measurement is shown as an orange (dark grey) band. The lower panel of each plot shows the ratio between theoretical predictions and the measurement.

The normalized measured two-dimensional differential signal cross section (black markers) as a function of $p_{\text{T}}^{\nu\nu}$ and $\text{min}[\Delta\phi(\vec{p}_{\text{T}}^{\nu\nu},\vec{p}_{\text{T}}^{\ell})]$ for the azimuthal angle range 0.56<$\phi$<1.08 is shown. The theoretical predictions from POWHEG+PYTHIA (dark red), POWHEG+HERWIG (orange), MC@NLO+PYTHIA (purple), and the fixed-order NLO (light blue) and NNLO (brown) calculations are compared to the measurement. The total (statistical) uncertainty in the measurement is shown as an orange (dark grey) band. The lower panel of each plot shows the ratio between theoretical predictions and the measurement.

The normalized measured two-dimensional differential signal cross section (black markers) as a function of $p_{\text{T}}^{\nu\nu}$ and $\text{min}[\Delta\phi(\vec{p}_{\text{T}}^{\nu\nu},\vec{p}_{\text{T}}^{\ell})]$ for the azimuthal angle range 1.08<$\phi$<3.14 is shown. The theoretical predictions from POWHEG+PYTHIA (dark red), POWHEG+HERWIG (orange), MC@NLO+PYTHIA (purple), and the fixed-order NLO (light blue) and NNLO (brown) calculations are compared to the measurement. The total (statistical) uncertainty in the measurement is shown as an orange (dark grey) band. The lower panel of each plot shows the ratio between theoretical predictions and the measurement.

The correlation matrix corresponding to the statistical uncertainties on the differential cross-section ($d\sigma/dp_T$) fit results for $W^-$. To combine with $W^+$ results (Fig8a), use the rows and columns ordered as $W^+$ and then $W^-$. Assume no correlation in the statistical uncertainties between $W^+$ and $W^-$ (zero entries in the off-diagonal blocks).

The correlation matrix corresponding to all of the systematic uncertainties on the differential cross-section ($d\sigma/dp_T$) fit results for $W^+$ and $W^-$ combined together, with rows and columns ordered as $W^+$ and then $W^-$.

The d$^{2}\sigma$/dydp$_{\mathrm{T}}$ production cross section of D$^{0}$ for $8 < p_{\mathrm{T}} < 12$ GeV in ultraperipheral PbPb collisions.

Observed 95% $\text{CL}_\text{S}$ upper limits on the production cross-section times acceptance times branching ratio to jets, $\sigma \cdot A \cdot \text{BR}$, of Gaussian-shaped signals of 5%, 10%, and 15% width relative to their peak mass, $m_G$. Also included are the corresponding expected upper limits predicted for the case the $m_{jj}$ distribution is observed to be identical to the background prediction in each bin and the $1\sigma$ and $2\sigma$ envelopes of outcomes expected for Poisson fluctuations around the background expectation. Limits are derived from the J100 signal region.

Observed 95% $\text{CL}_\text{S}$ upper limits on the the value of the coupling to quarks, $g_q$, of the $Z^\prime$ model as a function of the resonance mass $m_{Z^\prime}$. Also included are the corresponding expected upper limits predicted for the case the $m_{jj}$ distribution is observed to be identical to the background prediction in each bin and the $1\sigma$ and $2\sigma$ envelopes of outcomes expected for Poisson fluctuations around the background expectation. Limits are derived from the J50 signal region.

Observed 95% $\text{CL}_\text{S}$ upper limits on the the value of the coupling to quarks, $g_q$, of the $Z^\prime$ model as a function of the resonance mass $m_{Z^\prime}$. Also included are the corresponding expected upper limits predicted for the case the $m_{jj}$ distribution is observed to be identical to the background prediction in each bin and the $1\sigma$ and $2\sigma$ envelopes of outcomes expected for Poisson fluctuations around the background expectation. Limits are derived from the J100 signal region.

Acceptance of simulated $Z^\prime$ signal events given the analysis event selection as a function of $m_{Z^\prime}$. The solid black line corresponds to the acceptance without a lower $m_{jj}$ requirement applied, the solid blue line includes the $m_{jj} > 344$ GeV requirement of the J50 signal region, and the solid red line includes the $m_{jj} > 481$ GeV requirement of the J100 signal region.

Numbers of events in each of the two considered datasets after consecutively applying the analysis selections.