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.

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 $W^-$.

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.

Groomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet,gr}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data, without any WTA flavour requirement. Normalization is set to unity. $20 < p_{\textrm{T,jet}} < 30$ GeV, soft drop $z_{\textrm{cut}}=0.1, \beta=0$.

Groomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet,gr}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data, without any WTA flavour requirement. Normalization is set to unity. $30 < p_{\textrm{T,jet}} < 50$ GeV, soft drop $z_{\textrm{cut}}=0.1, \beta=0$.

Groomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet,gr}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data, without any WTA flavour requirement. Normalization is set to unity. $50 < p_{\textrm{T,jet}} < 100$ GeV, soft drop $z_{\textrm{cut}}=0.1, \beta=0$.

Groomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet,gr}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data, without any WTA flavour requirement. Normalization is set to the soft drop tagging fraction, given by the number of groomed jets (without any WTA flavour requirement) to number of ungroomed jets (without any WTA flavour requirement). $10 < p_{\textrm{T,jet}} < 12$ GeV, soft drop $z_{\textrm{cut}}=0.1, \beta=0$.

Groomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet,gr}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data, without any WTA flavour requirement. Normalization is set to the soft drop tagging fraction, given by the number of groomed jets (without any WTA flavour requirement) to number of ungroomed jets (without any WTA flavour requirement). $12 < p_{\textrm{T,jet}} < 15$ GeV, soft drop $z_{\textrm{cut}}=0.1, \beta=0$.

Groomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet,gr}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data, without any WTA flavour requirement. Normalization is set to the soft drop tagging fraction, given by the number of groomed jets (without any WTA flavour requirement) to number of ungroomed jets (without any WTA flavour requirement). $15 < p_{\textrm{T,jet}} < 20$ GeV, soft drop $z_{\textrm{cut}}=0.1, \beta=0$.

Groomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet,gr}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data, without any WTA flavour requirement. Normalization is set to the soft drop tagging fraction, given by the number of groomed jets (without any WTA flavour requirement) to number of ungroomed jets (without any WTA flavour requirement). $20 < p_{\textrm{T,jet}} < 30$ GeV, soft drop $z_{\textrm{cut}}=0.1, \beta=0$.

Groomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet,gr}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data, without any WTA flavour requirement. Normalization is set to the soft drop tagging fraction, given by the number of groomed jets (without any WTA flavour requirement) to number of ungroomed jets (without any WTA flavour requirement). $30 < p_{\textrm{T,jet}} < 50$ GeV, soft drop $z_{\textrm{cut}}=0.1, \beta=0$.

Groomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet,gr}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data, without any WTA flavour requirement. Normalization is set to the soft drop tagging fraction, given by the number of groomed jets (without any WTA flavour requirement) to number of ungroomed jets (without any WTA flavour requirement). $50 < p_{\textrm{T,jet}} < 100$ GeV, soft drop $z_{\textrm{cut}}=0.1, \beta=0$.

Ungroomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data, without any WTA flavour requirement. Normalization is set to unity. $10 < p_{\textrm{T,jet}} < 12$ GeV.

Ungroomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data, without any WTA flavour requirement. Normalization is set to unity. $12 < p_{\textrm{T,jet}} < 15$ GeV.

Ungroomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data, without any WTA flavour requirement. Normalization is set to unity. $15 < p_{\textrm{T,jet}} < 20$ GeV.

Ungroomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data, without any WTA flavour requirement. Normalization is set to unity. $20 < p_{\textrm{T,jet}} < 30$ GeV.

Ungroomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data, without any WTA flavour requirement. Normalization is set to unity. $30 < p_{\textrm{T,jet}} < 50$ GeV.

Ungroomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data, without any WTA flavour requirement. Normalization is set to unity. $50 < p_{\textrm{T,jet}} < 100$ GeV.

Groomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet,gr}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data tagged with WTA flavour. Normalization is set to the WTA tagging fraction, given by the number of (groomed) jets tagged with WTA flavour to number of (groomed) jets without WTA flavour tagging. $10 < p_{\textrm{T,jet}} < 12$ GeV, soft drop $z_{\textrm{cut}}=0.1, \beta=0$.

Groomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet,gr}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data tagged with WTA flavour. Normalization is set to the WTA tagging fraction, given by the number of (groomed) jets tagged with WTA flavour to number of (groomed) jets without WTA flavour tagging. $12 < p_{\textrm{T,jet}} < 15$ GeV, soft drop $z_{\textrm{cut}}=0.1, \beta=0$.

Groomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet,gr}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data tagged with WTA flavour. Normalization is set to the WTA tagging fraction, given by the number of (groomed) jets tagged with WTA flavour to number of (groomed) jets without WTA flavour tagging. $15 < p_{\textrm{T,jet}} < 20$ GeV, soft drop $z_{\textrm{cut}}=0.1, \beta=0$.

Groomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet,gr}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data tagged with WTA flavour. Normalization is set to the WTA tagging fraction, given by the number of (groomed) jets tagged with WTA flavour to number of (groomed) jets without WTA flavour tagging. $20 < p_{\textrm{T,jet}} < 30$ GeV, soft drop $z_{\textrm{cut}}=0.1, \beta=0$.

Groomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet,gr}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data tagged with WTA flavour. Normalization is set to the WTA tagging fraction, given by the number of (groomed) jets tagged with WTA flavour to number of (groomed) jets without WTA flavour tagging. $30 < p_{\textrm{T,jet}} < 50$ GeV, soft drop $z_{\textrm{cut}}=0.1, \beta=0$.

Groomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet,gr}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data tagged with WTA flavour. Normalization is set to the WTA tagging fraction, given by the number of (groomed) jets tagged with WTA flavour to number of (groomed) jets without WTA flavour tagging. $50 < p_{\textrm{T,jet}} < 100$ GeV, soft drop $z_{\textrm{cut}}=0.1, \beta=0$.

Groomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet,gr}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data tagged with WTA flavour. Normalization is set to the soft drop tagging fraction, given by the number of groomed jets (tagged with WTA flavour) to number of ungroomed jets (tagged with WTA flavour). $10 < p_{\textrm{T,jet}} < 12$ GeV, soft drop $z_{\textrm{cut}}=0.1, \beta=0$.

Groomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet,gr}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data tagged with WTA flavour. Normalization is set to the soft drop tagging fraction, given by the number of groomed jets (tagged with WTA flavour) to number of ungroomed jets (tagged with WTA flavour). $12 < p_{\textrm{T,jet}} < 15$ GeV, soft drop $z_{\textrm{cut}}=0.1, \beta=0$.

Groomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet,gr}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data tagged with WTA flavour. Normalization is set to the soft drop tagging fraction, given by the number of groomed jets (tagged with WTA flavour) to number of ungroomed jets (tagged with WTA flavour). $15 < p_{\textrm{T,jet}} < 20$ GeV, soft drop $z_{\textrm{cut}}=0.1, \beta=0$.

Groomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet,gr}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data tagged with WTA flavour. Normalization is set to the soft drop tagging fraction, given by the number of groomed jets (tagged with WTA flavour) to number of ungroomed jets (tagged with WTA flavour). $20 < p_{\textrm{T,jet}} < 30$ GeV, soft drop $z_{\textrm{cut}}=0.1, \beta=0$.

Groomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet,gr}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data tagged with WTA flavour. Normalization is set to the soft drop tagging fraction, given by the number of groomed jets (tagged with WTA flavour) to number of ungroomed jets (tagged with WTA flavour). $30 < p_{\textrm{T,jet}} < 50$ GeV, soft drop $z_{\textrm{cut}}=0.1, \beta=0$.

Groomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet,gr}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data tagged with WTA flavour. Normalization is set to the soft drop tagging fraction, given by the number of groomed jets (tagged with WTA flavour) to number of ungroomed jets (tagged with WTA flavour). $50 < p_{\textrm{T,jet}} < 100$ GeV, soft drop $z_{\textrm{cut}}=0.1, \beta=0$.

Ungroomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data tagged with WTA flavour. Normalization is set to the WTA tagging fraction, given by the number of (ungroomed) jets tagged with WTA flavour to number of (ungroomed) jets without WTA flavour tagging. $10 < p_{\textrm{T,jet}} < 12$ GeV.

Ungroomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data tagged with WTA flavour. Normalization is set to the WTA tagging fraction, given by the number of (ungroomed) jets tagged with WTA flavour to number of (ungroomed) jets without WTA flavour tagging. $12 < p_{\textrm{T,jet}} < 15$ GeV.

Ungroomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data tagged with WTA flavour. Normalization is set to the WTA tagging fraction, given by the number of (ungroomed) jets tagged with WTA flavour to number of (ungroomed) jets without WTA flavour tagging. $15 < p_{\textrm{T,jet}} < 20$ GeV.

Ungroomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data tagged with WTA flavour. Normalization is set to the WTA tagging fraction, given by the number of (ungroomed) jets tagged with WTA flavour to number of (ungroomed) jets without WTA flavour tagging. $20 < p_{\textrm{T,jet}} < 30$ GeV.

Ungroomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data tagged with WTA flavour. Normalization is set to the WTA tagging fraction, given by the number of (ungroomed) jets tagged with WTA flavour to number of (ungroomed) jets without WTA flavour tagging. $30 < p_{\textrm{T,jet}} < 50$ GeV.

Ungroomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data tagged with WTA flavour. Normalization is set to the WTA tagging fraction, given by the number of (ungroomed) jets tagged with WTA flavour to number of (ungroomed) jets without WTA flavour tagging. $50 < p_{\textrm{T,jet}} < 100$ GeV.

Ungroomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data tagged with WTA flavour. Normalization is set to unity. $10 < p_{\textrm{T,jet}} < 12$ GeV.

Ungroomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data tagged with WTA flavour. Normalization is set to unity. $12 < p_{\textrm{T,jet}} < 15$ GeV.

Ungroomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data tagged with WTA flavour. Normalization is set to unity. $15 < p_{\textrm{T,jet}} < 20$ GeV.

Ungroomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data tagged with WTA flavour. Normalization is set to unity. $20 < p_{\textrm{T,jet}} < 30$ GeV.

Ungroomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data tagged with WTA flavour. Normalization is set to unity. $30 < p_{\textrm{T,jet}} < 50$ GeV.

Ungroomed $B^\pm$-tagged jet invariant mass $m_{\textrm{jet}}/p_{\textrm{T,jet}}$ for $R=0.5$ jets reconstructed in pp data tagged with WTA flavour. Normalization is set to unity. $50 < p_{\textrm{T,jet}} < 100$ GeV.