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.

Comparison between data and the background prediction for the (a) m_T(4ℓ, E_T^miss), (b) m^high(3ℓ), (c) m(Z), (d) E_T^miss, (e) p_T(Z), and (f) N_jets distribution in the (a, d) 2Z 0b, (b, e) 1Z 1b 2SFOS, and (c, f) 0Z 2SFOS region, after requiring the anomaly score to be below the 90% background rejection point. The background contributions after the likelihood fit to data ('post-fit') for the background-only hypothesis are shown as filled histograms. The 'tt+X' background component includes the tt̄Z, and tt̄H processes. The 'HF ℓ' ('LF ℓ') background component refers to processes containing one non-prompt light lepton from heavy-flavour (light-flavour) hadron decays. The ratio of the data to the background prediction ('Bkg.') is shown in the lower panel. The 'Other' contribution is dominated by the tWZ production. The size of the combined statistical and systematic uncertainty in the background prediction is indicated by the blue hatched band. The upward-pointing blue arrows indicate points for which the data-to-background ('Data/Bkg.’) ratio exceeds the vertical range of the figure. The last bin contains the overflow.

Comparison between data and the background prediction for the (a) m_T(4ℓ, E_T^miss), (b) m^high(3ℓ), (c) m(Z), (d) E_T^miss, (e) p_T(Z), and (f) N_jets distribution in the (a, d) 2Z 0b, (b, e) 1Z 1b 2SFOS, and (c, f) 0Z 2SFOS region, after requiring the anomaly score to be below the 90% background rejection point. The background contributions after the likelihood fit to data ('post-fit') for the background-only hypothesis are shown as filled histograms. The 'tt+X' background component includes the tt̄Z, and tt̄H processes. The 'HF ℓ' ('LF ℓ') background component refers to processes containing one non-prompt light lepton from heavy-flavour (light-flavour) hadron decays. The ratio of the data to the background prediction ('Bkg.') is shown in the lower panel. The 'Other' contribution is dominated by the tWZ production. The size of the combined statistical and systematic uncertainty in the background prediction is indicated by the blue hatched band. The upward-pointing blue arrows indicate points for which the data-to-background ('Data/Bkg.’) ratio exceeds the vertical range of the figure. The last bin contains the overflow.

Comparison between data and the background prediction for the (a) m_T(4ℓ, E_T^miss), (b) m^high(3ℓ), (c) m(Z), (d) E_T^miss, (e) p_T(Z), and (f) N_jets distribution in the (a, d) 2Z 0b, (b, e) 1Z 1b 2SFOS, and (c, f) 0Z 2SFOS region, after requiring the anomaly score to be below the 90% background rejection point. The background contributions after the likelihood fit to data ('post-fit') for the background-only hypothesis are shown as filled histograms. The 'tt+X' background component includes the tt̄Z, and tt̄H processes. The 'HF ℓ' ('LF ℓ') background component refers to processes containing one non-prompt light lepton from heavy-flavour (light-flavour) hadron decays. The ratio of the data to the background prediction ('Bkg.') is shown in the lower panel. The 'Other' contribution is dominated by the tWZ production. The size of the combined statistical and systematic uncertainty in the background prediction is indicated by the blue hatched band. The upward-pointing blue arrows indicate points for which the data-to-background ('Data/Bkg.’) ratio exceeds the vertical range of the figure. The last bin contains the overflow.

Comparison between data and the background prediction for the (a) N_jets, (b) E_T^miss, (c) m(3ℓ), and (d) H_T^lep distribution in the (a) HFe CR, (b) HFμ CR, (c) LFe CR, and (d) the Wγ^*/tt̄γ^* validation region. The background contributions after the likelihood fit to data ('post-fit') for the background-only hypothesis are shown as filled histograms. The ratio of the data to the background prediction ('Bkg.') is shown in the lower panel. The 'tt+X' background component includes the tt̄W, tt̄Z, and tt̄H processes. The 'Other' contribution in the 2ℓSS regions is dominated by the tt̄ and tt̄W production, and in the 3ℓ regions is dominated by the ZZ + LF production. The size of the combined statistical and systematic uncertainty in the background prediction is indicated by the blue hatched band. The upward-pointing blue arrows indicate points for which the data-to-background ('Data/Bkg.’) ratio exceeds the vertical range of the figure. The last bin contains the overflow.

Comparison between data and the background prediction for the (a) N_jets, (b) E_T^miss, (c) m(3ℓ), and (d) H_T^lep distribution in the (a) HFe CR, (b) HFμ CR, (c) LFe CR, and (d) the Wγ^*/tt̄γ^* validation region. The background contributions after the likelihood fit to data ('post-fit') for the background-only hypothesis are shown as filled histograms. The ratio of the data to the background prediction ('Bkg.') is shown in the lower panel. The 'tt+X' background component includes the tt̄W, tt̄Z, and tt̄H processes. The 'Other' contribution in the 2ℓSS regions is dominated by the tt̄ and tt̄W production, and in the 3ℓ regions is dominated by the ZZ + LF production. The size of the combined statistical and systematic uncertainty in the background prediction is indicated by the blue hatched band. The upward-pointing blue arrows indicate points for which the data-to-background ('Data/Bkg.’) ratio exceeds the vertical range of the figure. The last bin contains the overflow.

Comparison between data and the background prediction for the (a) N_jets, (b) E_T^miss, (c) m(3ℓ), and (d) H_T^lep distribution in the (a) HFe CR, (b) HFμ CR, (c) LFe CR, and (d) the Wγ^*/tt̄γ^* validation region. The background contributions after the likelihood fit to data ('post-fit') for the background-only hypothesis are shown as filled histograms. The ratio of the data to the background prediction ('Bkg.') is shown in the lower panel. The 'tt+X' background component includes the tt̄W, tt̄Z, and tt̄H processes. The 'Other' contribution in the 2ℓSS regions is dominated by the tt̄ and tt̄W production, and in the 3ℓ regions is dominated by the ZZ + LF production. The size of the combined statistical and systematic uncertainty in the background prediction is indicated by the blue hatched band. The upward-pointing blue arrows indicate points for which the data-to-background ('Data/Bkg.’) ratio exceeds the vertical range of the figure. The last bin contains the overflow.

Comparison between data and the background prediction for the (a) N_jets, (b) E_T^miss, (c) m(3ℓ), and (d) H_T^lep distribution in the (a) HFe CR, (b) HFμ CR, (c) LFe CR, and (d) the Wγ^*/tt̄γ^* validation region. The background contributions after the likelihood fit to data ('post-fit') for the background-only hypothesis are shown as filled histograms. The ratio of the data to the background prediction ('Bkg.') is shown in the lower panel. The 'tt+X' background component includes the tt̄W, tt̄Z, and tt̄H processes. The 'Other' contribution in the 2ℓSS regions is dominated by the tt̄ and tt̄W production, and in the 3ℓ regions is dominated by the ZZ + LF production. The size of the combined statistical and systematic uncertainty in the background prediction is indicated by the blue hatched band. The upward-pointing blue arrows indicate points for which the data-to-background ('Data/Bkg.’) ratio exceeds the vertical range of the figure. The last bin contains the overflow.

Comparison between data and the background prediction for the discovery regions included in the model-independent fit, after a background-only fit to data in the five cut-based control regions and ten low-anomaly score discovery regions ('post-fit'). All signal bins are shown ('SR') together with the low-anomaly score discovery regions ('CR'). The various requirements on the anomaly score corresponding to the specified background rejection cuts (99.9/99/90/50%) are shown for all the applicable SRs and CRs. The lower panels show the ratio of data to the background estimate ('Bkg'). The 'tt+X' background component includes the tt̄Z (4ℓ only) and tt̄H processes. The 'Other' contribution is dominated by the VH process. The size of the combined statistical and systematic uncertainty in the background prediction is indicated by the blue hatched band. The upward-pointing blue arrows indicate points for which the data-to-background ('Data/Bkg.’) ratio exceeds the vertical range of the figure.

Observed and expected excluded visible cross section limits, σ_vis for the model-independent regions. The various requirements on the anomaly score corresponding to the specified background rejection cuts (99.9/99/90/50%) are shown for all the applicable regions.

Comparison between data and the background estimate for the anomaly score distribution used in different benchmark regions, after a background-only fit to data ('post-fit'): (a) 4ℓ Q=0 0Z 0b 2SFOS e>μ, (b) 4ℓ Q=0 0Z ≥1b 2SFOS e>μ, (c) 4ℓ Q=0 1Z 0b 2SFOS μ>e, (d) 4ℓ Q=±2 0b e>μ, (e) 4ℓ Q=±2 ≥1b μ>e, and (f) the three ≥5ℓ regions: 0Z 0b μ>e, 0Z 0b e≥μ, and 0Z ≥1b, defined without AD. Distributions for one flavourful VLL_e signal point for a VLL mass of 1 TeV and scalar of 550 GeV, a wino-like chargino and neutralino signal point of mass 1.3 TeV, and a smuon signal point of mass 350 GeV and neutralino mass of 250 GeV are overlaid for comparison. The lower panels show the ratio of data to the background estimate ('Bkg.'). The 'tt+X' background component includes the tt̄Z (4ℓ only) and tt̄H processes. The 'Other' contribution is dominated by the VH process. The size of the combined statistical and systematic uncertainty in the signal-plus-background prediction is indicated by the blue hatched band. The upward-pointing blue arrow indicates a point for which the data-to-background ('Data/Bkg.’) ratio exceeds the vertical range of the figure.

Comparison between data and the background estimate for the anomaly score distribution used in different benchmark regions, after a background-only fit to data ('post-fit'): (a) 4ℓ Q=0 0Z 0b 2SFOS e>μ, (b) 4ℓ Q=0 0Z ≥1b 2SFOS e>μ, (c) 4ℓ Q=0 1Z 0b 2SFOS μ>e, (d) 4ℓ Q=±2 0b e>μ, (e) 4ℓ Q=±2 ≥1b μ>e, and (f) the three ≥5ℓ regions: 0Z 0b μ>e, 0Z 0b e≥μ, and 0Z ≥1b, defined without AD. Distributions for one flavourful VLL_e signal point for a VLL mass of 1 TeV and scalar of 550 GeV, a wino-like chargino and neutralino signal point of mass 1.3 TeV, and a smuon signal point of mass 350 GeV and neutralino mass of 250 GeV are overlaid for comparison. The lower panels show the ratio of data to the background estimate ('Bkg.'). The 'tt+X' background component includes the tt̄Z (4ℓ only) and tt̄H processes. The 'Other' contribution is dominated by the VH process. The size of the combined statistical and systematic uncertainty in the signal-plus-background prediction is indicated by the blue hatched band. The upward-pointing blue arrow indicates a point for which the data-to-background ('Data/Bkg.’) ratio exceeds the vertical range of the figure.

Comparison between data and the background estimate for the anomaly score distribution used in different benchmark regions, after a background-only fit to data ('post-fit'): (a) 4ℓ Q=0 0Z 0b 2SFOS e>μ, (b) 4ℓ Q=0 0Z ≥1b 2SFOS e>μ, (c) 4ℓ Q=0 1Z 0b 2SFOS μ>e, (d) 4ℓ Q=±2 0b e>μ, (e) 4ℓ Q=±2 ≥1b μ>e, and (f) the three ≥5ℓ regions: 0Z 0b μ>e, 0Z 0b e≥μ, and 0Z ≥1b, defined without AD. Distributions for one flavourful VLL_e signal point for a VLL mass of 1 TeV and scalar of 550 GeV, a wino-like chargino and neutralino signal point of mass 1.3 TeV, and a smuon signal point of mass 350 GeV and neutralino mass of 250 GeV are overlaid for comparison. The lower panels show the ratio of data to the background estimate ('Bkg.'). The 'tt+X' background component includes the tt̄Z (4ℓ only) and tt̄H processes. The 'Other' contribution is dominated by the VH process. The size of the combined statistical and systematic uncertainty in the signal-plus-background prediction is indicated by the blue hatched band. The upward-pointing blue arrow indicates a point for which the data-to-background ('Data/Bkg.’) ratio exceeds the vertical range of the figure.

Comparison between data and the background estimate for the anomaly score distribution used in different benchmark regions, after a background-only fit to data ('post-fit'): (a) 4ℓ Q=0 0Z 0b 2SFOS e>μ, (b) 4ℓ Q=0 0Z ≥1b 2SFOS e>μ, (c) 4ℓ Q=0 1Z 0b 2SFOS μ>e, (d) 4ℓ Q=±2 0b e>μ, (e) 4ℓ Q=±2 ≥1b μ>e, and (f) the three ≥5ℓ regions: 0Z 0b μ>e, 0Z 0b e≥μ, and 0Z ≥1b, defined without AD. Distributions for one flavourful VLL_e signal point for a VLL mass of 1 TeV and scalar of 550 GeV, a wino-like chargino and neutralino signal point of mass 1.3 TeV, and a smuon signal point of mass 350 GeV and neutralino mass of 250 GeV are overlaid for comparison. The lower panels show the ratio of data to the background estimate ('Bkg.'). The 'tt+X' background component includes the tt̄Z (4ℓ only) and tt̄H processes. The 'Other' contribution is dominated by the VH process. The size of the combined statistical and systematic uncertainty in the signal-plus-background prediction is indicated by the blue hatched band. The upward-pointing blue arrow indicates a point for which the data-to-background ('Data/Bkg.’) ratio exceeds the vertical range of the figure.

Comparison between data and the background estimate for the anomaly score distribution used in different benchmark regions, after a background-only fit to data ('post-fit'): (a) 4ℓ Q=0 0Z 0b 2SFOS e>μ, (b) 4ℓ Q=0 0Z ≥1b 2SFOS e>μ, (c) 4ℓ Q=0 1Z 0b 2SFOS μ>e, (d) 4ℓ Q=±2 0b e>μ, (e) 4ℓ Q=±2 ≥1b μ>e, and (f) the three ≥5ℓ regions: 0Z 0b μ>e, 0Z 0b e≥μ, and 0Z ≥1b, defined without AD. Distributions for one flavourful VLL_e signal point for a VLL mass of 1 TeV and scalar of 550 GeV, a wino-like chargino and neutralino signal point of mass 1.3 TeV, and a smuon signal point of mass 350 GeV and neutralino mass of 250 GeV are overlaid for comparison. The lower panels show the ratio of data to the background estimate ('Bkg.'). The 'tt+X' background component includes the tt̄Z (4ℓ only) and tt̄H processes. The 'Other' contribution is dominated by the VH process. The size of the combined statistical and systematic uncertainty in the signal-plus-background prediction is indicated by the blue hatched band. The upward-pointing blue arrow indicates a point for which the data-to-background ('Data/Bkg.’) ratio exceeds the vertical range of the figure.

Comparison between data and the background estimate for the anomaly score distribution used in different benchmark regions, after a background-only fit to data ('post-fit'): (a) 4ℓ Q=0 0Z 0b 2SFOS e>μ, (b) 4ℓ Q=0 0Z ≥1b 2SFOS e>μ, (c) 4ℓ Q=0 1Z 0b 2SFOS μ>e, (d) 4ℓ Q=±2 0b e>μ, (e) 4ℓ Q=±2 ≥1b μ>e, and (f) the three ≥5ℓ regions: 0Z 0b μ>e, 0Z 0b e≥μ, and 0Z ≥1b, defined without AD. Distributions for one flavourful VLL_e signal point for a VLL mass of 1 TeV and scalar of 550 GeV, a wino-like chargino and neutralino signal point of mass 1.3 TeV, and a smuon signal point of mass 350 GeV and neutralino mass of 250 GeV are overlaid for comparison. The lower panels show the ratio of data to the background estimate ('Bkg.'). The 'tt+X' background component includes the tt̄Z (4ℓ only) and tt̄H processes. The 'Other' contribution is dominated by the VH process. The size of the combined statistical and systematic uncertainty in the signal-plus-background prediction is indicated by the blue hatched band. The upward-pointing blue arrow indicates a point for which the data-to-background ('Data/Bkg.’) ratio exceeds the vertical range of the figure.

Combined observed and expected limits at 95&percnt; CL on the cross-section (&sigma;) as a function of the VLL mass for the (a) VLL_e^D, (b) VLL_&mu;^D, (c) VLL_e^S, (d) VLL_&mu;^S models, and on the plane of the S_ji mass versus the VLL mass for the (e) flavourful VLL_e, and (f) flavourful VLL_&mu; models. The expected limits from the dedicated ATLAS search [<a href=" https://doi.org/10.1007/JHEP05%282025%29075">JHEP05(2025)075</a>], considering only the 4&#8467; channel, are overlaid in dashed grey lines in (a-d). The inner and outer bands around the expected limit are the &plusmn;1 &sigma; and &plusmn;2 &sigma; variations including all uncertainties, respectively.

Combined observed and expected limits at 95&percnt; CL on the cross-section (&sigma;) as a function of the VLL mass for the (a) VLL_e^D, (b) VLL_&mu;^D, (c) VLL_e^S, (d) VLL_&mu;^S models, and on the plane of the S_ji mass versus the VLL mass for the (e) flavourful VLL_e, and (f) flavourful VLL_&mu; models. The expected limits from the dedicated ATLAS search [<a href=" https://doi.org/10.1007/JHEP05%282025%29075">JHEP05(2025)075</a>], considering only the 4&#8467; channel, are overlaid in dashed grey lines in (a-d). The inner and outer bands around the expected limit are the &plusmn;1 &sigma; and &plusmn;2 &sigma; variations including all uncertainties, respectively.

Combined observed and expected limits at 95&percnt; CL on the cross-section (&sigma;) as a function of the VLL mass for the (a) VLL_e^D, (b) VLL_&mu;^D, (c) VLL_e^S, (d) VLL_&mu;^S models, and on the plane of the S_ji mass versus the VLL mass for the (e) flavourful VLL_e, and (f) flavourful VLL_&mu; models. The expected limits from the dedicated ATLAS search [<a href=" https://doi.org/10.1007/JHEP05%282025%29075">JHEP05(2025)075</a>], considering only the 4&#8467; channel, are overlaid in dashed grey lines in (a-d). The inner and outer bands around the expected limit are the &plusmn;1 &sigma; and &plusmn;2 &sigma; variations including all uncertainties, respectively.

Combined observed and expected limits at 95&percnt; CL on the cross-section (&sigma;) as a function of the VLL mass for the (a) VLL_e^D, (b) VLL_&mu;^D, (c) VLL_e^S, (d) VLL_&mu;^S models, and on the plane of the S_ji mass versus the VLL mass for the (e) flavourful VLL_e, and (f) flavourful VLL_&mu; models. The expected limits from the dedicated ATLAS search [<a href=" https://doi.org/10.1007/JHEP05%282025%29075">JHEP05(2025)075</a>], considering only the 4&#8467; channel, are overlaid in dashed grey lines in (a-d). The inner and outer bands around the expected limit are the &plusmn;1 &sigma; and &plusmn;2 &sigma; variations including all uncertainties, respectively.

Combined observed and expected limits at 95&percnt; CL on the cross-section (&sigma;) as a function of the VLL mass for the (a) VLL_e^D, (b) VLL_&mu;^D, (c) VLL_e^S, (d) VLL_&mu;^S models, and on the plane of the S_ji mass versus the VLL mass for the (e) flavourful VLL_e, and (f) flavourful VLL_&mu; models. The expected limits from the dedicated ATLAS search [<a href=" https://doi.org/10.1007/JHEP05%282025%29075">JHEP05(2025)075</a>], considering only the 4&#8467; channel, are overlaid in dashed grey lines in (a-d). The inner and outer bands around the expected limit are the &plusmn;1 &sigma; and &plusmn;2 &sigma; variations including all uncertainties, respectively.

Combined observed and expected limits at 95&percnt; CL on the cross-section (&sigma;) as a function of the VLL mass for the (a) VLL_e^D, (b) VLL_&mu;^D, (c) VLL_e^S, (d) VLL_&mu;^S models, and on the plane of the S_ji mass versus the VLL mass for the (e) flavourful VLL_e, and (f) flavourful VLL_&mu; models. The expected limits from the dedicated ATLAS search [<a href=" https://doi.org/10.1007/JHEP05%282025%29075">JHEP05(2025)075</a>], considering only the 4&#8467; channel, are overlaid in dashed grey lines in (a-d). The inner and outer bands around the expected limit are the &plusmn;1 &sigma; and &plusmn;2 &sigma; variations including all uncertainties, respectively.

Combined observed and expected limits at 95&percnt; CL on the cross-section (&sigma;) as a function of the VLL mass for the (a) VLL_e^D, (b) VLL_&mu;^D, (c) VLL_e^S, (d) VLL_&mu;^S models, and on the plane of the S_ji mass versus the VLL mass for the (e) flavourful VLL_e, and (f) flavourful VLL_&mu; models. The expected limits from the dedicated ATLAS search [<a href=" https://doi.org/10.1007/JHEP05%282025%29075">JHEP05(2025)075</a>], considering only the 4&#8467; channel, are overlaid in dashed grey lines in (a-d). The inner and outer bands around the expected limit are the &plusmn;1 &sigma; and &plusmn;2 &sigma; variations including all uncertainties, respectively.

Combined observed and expected limits at 95&percnt; CL on the cross-section (&sigma;) as a function of the VLL mass for the (a) VLL_e^D, (b) VLL_&mu;^D, (c) VLL_e^S, (d) VLL_&mu;^S models, and on the plane of the S_ji mass versus the VLL mass for the (e) flavourful VLL_e, and (f) flavourful VLL_&mu; models. The expected limits from the dedicated ATLAS search [<a href=" https://doi.org/10.1007/JHEP05%282025%29075">JHEP05(2025)075</a>], considering only the 4&#8467; channel, are overlaid in dashed grey lines in (a-d). The inner and outer bands around the expected limit are the &plusmn;1 &sigma; and &plusmn;2 &sigma; variations including all uncertainties, respectively.

Combined observed and expected limits at 95&percnt; CL on the cross-section (&sigma;) as a function of the VLL mass for the (a) VLL_e^D, (b) VLL_&mu;^D, (c) VLL_e^S, (d) VLL_&mu;^S models, and on the plane of the S_ji mass versus the VLL mass for the (e) flavourful VLL_e, and (f) flavourful VLL_&mu; models. The expected limits from the dedicated ATLAS search [<a href=" https://doi.org/10.1007/JHEP05%282025%29075">JHEP05(2025)075</a>], considering only the 4&#8467; channel, are overlaid in dashed grey lines in (a-d). The inner and outer bands around the expected limit are the &plusmn;1 &sigma; and &plusmn;2 &sigma; variations including all uncertainties, respectively.

Combined observed and expected limits at 95&percnt; CL on the cross-section (&sigma;) as a function of the VLL mass for the (a) VLL_e^D, (b) VLL_&mu;^D, (c) VLL_e^S, (d) VLL_&mu;^S models, and on the plane of the S_ji mass versus the VLL mass for the (e) flavourful VLL_e, and (f) flavourful VLL_&mu; models. The expected limits from the dedicated ATLAS search [<a href=" https://doi.org/10.1007/JHEP05%282025%29075">JHEP05(2025)075</a>], considering only the 4&#8467; channel, are overlaid in dashed grey lines in (a-d). The inner and outer bands around the expected limit are the &plusmn;1 &sigma; and &plusmn;2 &sigma; variations including all uncertainties, respectively.

Combined observed and expected limits at 95&percnt; CL on the cross-section (&sigma;) as a function of the VLL mass for the (a) VLL_e^D, (b) VLL_&mu;^D, (c) VLL_e^S, (d) VLL_&mu;^S models, and on the plane of the S_ji mass versus the VLL mass for the (e) flavourful VLL_e, and (f) flavourful VLL_&mu; models. The expected limits from the dedicated ATLAS search [<a href=" https://doi.org/10.1007/JHEP05%282025%29075">JHEP05(2025)075</a>], considering only the 4&#8467; channel, are overlaid in dashed grey lines in (a-d). The inner and outer bands around the expected limit are the &plusmn;1 &sigma; and &plusmn;2 &sigma; variations including all uncertainties, respectively.

Combined observed and expected limits at 95&percnt; CL on the cross-section (&sigma;) as a function of the VLL mass for the (a) VLL_e^D, (b) VLL_&mu;^D, (c) VLL_e^S, (d) VLL_&mu;^S models, and on the plane of the S_ji mass versus the VLL mass for the (e) flavourful VLL_e, and (f) flavourful VLL_&mu; models. The expected limits from the dedicated ATLAS search [<a href=" https://doi.org/10.1007/JHEP05%282025%29075">JHEP05(2025)075</a>], considering only the 4&#8467; channel, are overlaid in dashed grey lines in (a-d). The inner and outer bands around the expected limit are the &plusmn;1 &sigma; and &plusmn;2 &sigma; variations including all uncertainties, respectively.

Combined observed and expected limits at 95&percnt; CL for the (a) wino-like chargino and neutralino, and (b) smuon models, as a function of the masses of &chi;&#771;^&plusmn;₁ / &chi;&#771;⁰₂ and &chi;&#771;⁰₁, and &mu;_L,R and &Delta;m (&mu;_L,R, &chi;&#771;⁰₁), respectively. The expected limits from the dedicated ATLAS searches [<a href=" https://doi.org/10.1007/JHEP07%282021%29167">JHEP07(2021)167</a>, <a href=" https://doi.org/10.1007/JHEP12%282023%29081">JHEP12(2023)081</a>] are overlaid in dashed grey lines. The inner and outer bands around the expected limit are the &plusmn;1 &sigma; and &plusmn;2 &sigma; variations including all uncertainties, respectively.

Combined observed and expected limits at 95&percnt; CL for the (a) wino-like chargino and neutralino, and (b) smuon models, as a function of the masses of &chi;&#771;^&plusmn;₁ / &chi;&#771;⁰₂ and &chi;&#771;⁰₁, and &mu;_L,R and &Delta;m (&mu;_L,R, &chi;&#771;⁰₁), respectively. The expected limits from the dedicated ATLAS searches [<a href=" https://doi.org/10.1007/JHEP07%282021%29167">JHEP07(2021)167</a>, <a href=" https://doi.org/10.1007/JHEP12%282023%29081">JHEP12(2023)081</a>] are overlaid in dashed grey lines. The inner and outer bands around the expected limit are the &plusmn;1 &sigma; and &plusmn;2 &sigma; variations including all uncertainties, respectively.

Combined observed and expected limits at 95&percnt; CL for the (a) wino-like chargino and neutralino, and (b) smuon models, as a function of the masses of &chi;&#771;^&plusmn;₁ / &chi;&#771;⁰₂ and &chi;&#771;⁰₁, and &mu;_L,R and &Delta;m (&mu;_L,R, &chi;&#771;⁰₁), respectively. The expected limits from the dedicated ATLAS searches [<a href=" https://doi.org/10.1007/JHEP07%282021%29167">JHEP07(2021)167</a>, <a href=" https://doi.org/10.1007/JHEP12%282023%29081">JHEP12(2023)081</a>] are overlaid in dashed grey lines. The inner and outer bands around the expected limit are the &plusmn;1 &sigma; and &plusmn;2 &sigma; variations including all uncertainties, respectively.

Combined observed and expected limits at 95&percnt; CL for the (a) wino-like chargino and neutralino, and (b) smuon models, as a function of the masses of &chi;&#771;^&plusmn;₁ / &chi;&#771;⁰₂ and &chi;&#771;⁰₁, and &mu;_L,R and &Delta;m (&mu;_L,R, &chi;&#771;⁰₁), respectively. The expected limits from the dedicated ATLAS searches [<a href=" https://doi.org/10.1007/JHEP07%282021%29167">JHEP07(2021)167</a>, <a href=" https://doi.org/10.1007/JHEP12%282023%29081">JHEP12(2023)081</a>] are overlaid in dashed grey lines. The inner and outer bands around the expected limit are the &plusmn;1 &sigma; and &plusmn;2 &sigma; variations including all uncertainties, respectively.

Combined observed and expected limits at 95&percnt; CL for the (a) wino-like chargino and neutralino, and (b) smuon models, as a function of the masses of &chi;&#771;^&plusmn;₁ / &chi;&#771;⁰₂ and &chi;&#771;⁰₁, and &mu;_L,R and &Delta;m (&mu;_L,R, &chi;&#771;⁰₁), respectively. The expected limits from the dedicated ATLAS searches [<a href=" https://doi.org/10.1007/JHEP07%282021%29167">JHEP07(2021)167</a>, <a href=" https://doi.org/10.1007/JHEP12%282023%29081">JHEP12(2023)081</a>] are overlaid in dashed grey lines. The inner and outer bands around the expected limit are the &plusmn;1 &sigma; and &plusmn;2 &sigma; variations including all uncertainties, respectively.

Combined observed and expected limits at 95&percnt; CL for the (a) wino-like chargino and neutralino, and (b) smuon models, as a function of the masses of &chi;&#771;^&plusmn;₁ / &chi;&#771;⁰₂ and &chi;&#771;⁰₁, and &mu;_L,R and &Delta;m (&mu;_L,R, &chi;&#771;⁰₁), respectively. The expected limits from the dedicated ATLAS searches [<a href=" https://doi.org/10.1007/JHEP07%282021%29167">JHEP07(2021)167</a>, <a href=" https://doi.org/10.1007/JHEP12%282023%29081">JHEP12(2023)081</a>] are overlaid in dashed grey lines. The inner and outer bands around the expected limit are the &plusmn;1 &sigma; and &plusmn;2 &sigma; variations including all uncertainties, respectively.

Combined observed and expected limits at 95&percnt; CL for the (a) wino-like chargino and neutralino, and (b) smuon models, as a function of the masses of &chi;&#771;^&plusmn;₁ / &chi;&#771;⁰₂ and &chi;&#771;⁰₁, and &mu;_L,R and &Delta;m (&mu;_L,R, &chi;&#771;⁰₁), respectively. The expected limits from the dedicated ATLAS searches [<a href=" https://doi.org/10.1007/JHEP07%282021%29167">JHEP07(2021)167</a>, <a href=" https://doi.org/10.1007/JHEP12%282023%29081">JHEP12(2023)081</a>] are overlaid in dashed grey lines. The inner and outer bands around the expected limit are the &plusmn;1 &sigma; and &plusmn;2 &sigma; variations including all uncertainties, respectively.

Combined observed and expected limits at 95&percnt; CL for the (a) wino-like chargino and neutralino, and (b) smuon models, as a function of the masses of &chi;&#771;^&plusmn;₁ / &chi;&#771;⁰₂ and &chi;&#771;⁰₁, and &mu;_L,R and &Delta;m (&mu;_L,R, &chi;&#771;⁰₁), respectively. The expected limits from the dedicated ATLAS searches [<a href=" https://doi.org/10.1007/JHEP07%282021%29167">JHEP07(2021)167</a>, <a href=" https://doi.org/10.1007/JHEP12%282023%29081">JHEP12(2023)081</a>] are overlaid in dashed grey lines. The inner and outer bands around the expected limit are the &plusmn;1 &sigma; and &plusmn;2 &sigma; variations including all uncertainties, respectively.

Comparison between data and the background prediction for the distribution of the b-jet multiplicity in the WZ/ttZ CR after the VV jet multiplicity correction. The background contributions after the likelihood fit to data (&apos;post-fit&apos;) for the background-only hypothesis are shown as filled histograms. The lower panel shows the ratio of data to the background estimate (&apos;Bkg.&apos;). The &apos;tt+X&apos; background component includes the tt&#772;W, tt&#772;Z, and tt&#772;H processes. The &apos;Other&apos; contribution is dominated by the tZq production. The size of the combined statistical and systematic uncertainty in the background prediction is indicated by the blue hatched band. The last bin contains the overflow.

Comparison between data and the background prediction for the event yields in the HF_e CR, HF_&mu;, Conversions, and LF_e CRs, after a background-only fit to data (&apos;Post-fit&apos;). The lower panel shows the ratio of data to the background estimate (&apos;Bkg.&apos;). The &apos;tt+X&apos; background component includes the tt&#772;W, tt&#772;Z, and tt&#772;H processes. The &apos;Other&apos; contribution is dominated by the ZZ+LF process. The size of the combined statistical and systematic uncertainty in the background prediction is indicated by the blue hatched band.

Comparison between data and the background prediction for the discovery regions included in the model-independent fit, before any fit to data (&apos;pre-fit&apos;). All signal bins are shown (&apos;SR&apos;) together with the low-anomaly score discovery regions (&apos;CR&apos;). The various requirements on the anomaly score corresponding to the specified background rejection cuts (99.9/99/90/50&percnt;) are shown for all the applicable SRs and CRs. The lower panels show the ratio of data to the background estimate (&apos;Bkg&apos;). The &apos;tt+X&apos; background component includes the tt&#772;Z (4&#8467; only) and tt&#772;H processes. The &apos;Other&apos; contribution is dominated by the VH process. The size of the combined statistical and systematic uncertainty in the background prediction is indicated by the blue hatched band. The upward-pointing blue arrows indicate points for which the data-to-background (&apos;Data/Bkg.’) ratio exceeds the vertical range of the figure.

Comparison between data and the background estimate for the anomaly score distribution used in different benchmark regions before any fit to data (&apos;pre-fit&apos;): (a) 4&#8467; Q=0 0Z 0b 2SFOS e&gt;&mu;, (b) 4&#8467; Q=0 0Z &ge;1b 2SFOS e&gt;&mu;, (c) 4&#8467; Q=0 1Z 0b 2SFOS &mu;&gt;e, (d) 4&#8467; Q=&plusmn;2 0b e&gt;&mu;, (e) 4&#8467; Q=&plusmn;2 &ge;1b &mu;&gt;e, and (f) the three &ge;5&#8467; regions: 0Z 0b &mu;&gt;e, 0Z 0b e&ge;&mu;, and 0Z &ge;1b, defined without AD. Distributions for one flavourful VLL_e signal point for a VLL mass of 1 TeV and scalar of 550 GeV, a wino-like chargino and neutralino signal point of mass 1.3 TeV, and a smuon signal point of mass 350 GeV and neutralino mass of 250 GeV are overlaid for comparison. The lower panels show the ratio of data to the background estimate (&apos;Bkg.&apos;). The &apos;tt+X&apos; background component includes the tt&#772;Z (4&#8467; only) and tt&#772;H processes. The &apos;Other&apos; contribution is dominated by the VH process. The size of the combined statistical and systematic uncertainty in the signal-plus-background prediction is indicated by the blue hatched band. The upward-pointing blue arrow indicates a point for which the data-to-background (&apos;Data/Bkg.’) ratio exceeds the vertical range of the figure.

Comparison between data and the background estimate for the anomaly score distribution used in different benchmark regions before any fit to data (&apos;pre-fit&apos;): (a) 4&#8467; Q=0 0Z 0b 2SFOS e&gt;&mu;, (b) 4&#8467; Q=0 0Z &ge;1b 2SFOS e&gt;&mu;, (c) 4&#8467; Q=0 1Z 0b 2SFOS &mu;&gt;e, (d) 4&#8467; Q=&plusmn;2 0b e&gt;&mu;, (e) 4&#8467; Q=&plusmn;2 &ge;1b &mu;&gt;e, and (f) the three &ge;5&#8467; regions: 0Z 0b &mu;&gt;e, 0Z 0b e&ge;&mu;, and 0Z &ge;1b, defined without AD. Distributions for one flavourful VLL_e signal point for a VLL mass of 1 TeV and scalar of 550 GeV, a wino-like chargino and neutralino signal point of mass 1.3 TeV, and a smuon signal point of mass 350 GeV and neutralino mass of 250 GeV are overlaid for comparison. The lower panels show the ratio of data to the background estimate (&apos;Bkg.&apos;). The &apos;tt+X&apos; background component includes the tt&#772;Z (4&#8467; only) and tt&#772;H processes. The &apos;Other&apos; contribution is dominated by the VH process. The size of the combined statistical and systematic uncertainty in the signal-plus-background prediction is indicated by the blue hatched band. The upward-pointing blue arrow indicates a point for which the data-to-background (&apos;Data/Bkg.’) ratio exceeds the vertical range of the figure.

Comparison between data and the background estimate for the anomaly score distribution used in different benchmark regions before any fit to data (&apos;pre-fit&apos;): (a) 4&#8467; Q=0 0Z 0b 2SFOS e&gt;&mu;, (b) 4&#8467; Q=0 0Z &ge;1b 2SFOS e&gt;&mu;, (c) 4&#8467; Q=0 1Z 0b 2SFOS &mu;&gt;e, (d) 4&#8467; Q=&plusmn;2 0b e&gt;&mu;, (e) 4&#8467; Q=&plusmn;2 &ge;1b &mu;&gt;e, and (f) the three &ge;5&#8467; regions: 0Z 0b &mu;&gt;e, 0Z 0b e&ge;&mu;, and 0Z &ge;1b, defined without AD. Distributions for one flavourful VLL_e signal point for a VLL mass of 1 TeV and scalar of 550 GeV, a wino-like chargino and neutralino signal point of mass 1.3 TeV, and a smuon signal point of mass 350 GeV and neutralino mass of 250 GeV are overlaid for comparison. The lower panels show the ratio of data to the background estimate (&apos;Bkg.&apos;). The &apos;tt+X&apos; background component includes the tt&#772;Z (4&#8467; only) and tt&#772;H processes. The &apos;Other&apos; contribution is dominated by the VH process. The size of the combined statistical and systematic uncertainty in the signal-plus-background prediction is indicated by the blue hatched band. The upward-pointing blue arrow indicates a point for which the data-to-background (&apos;Data/Bkg.’) ratio exceeds the vertical range of the figure.

Comparison between data and the background estimate for the anomaly score distribution used in different benchmark regions before any fit to data (&apos;pre-fit&apos;): (a) 4&#8467; Q=0 0Z 0b 2SFOS e&gt;&mu;, (b) 4&#8467; Q=0 0Z &ge;1b 2SFOS e&gt;&mu;, (c) 4&#8467; Q=0 1Z 0b 2SFOS &mu;&gt;e, (d) 4&#8467; Q=&plusmn;2 0b e&gt;&mu;, (e) 4&#8467; Q=&plusmn;2 &ge;1b &mu;&gt;e, and (f) the three &ge;5&#8467; regions: 0Z 0b &mu;&gt;e, 0Z 0b e&ge;&mu;, and 0Z &ge;1b, defined without AD. Distributions for one flavourful VLL_e signal point for a VLL mass of 1 TeV and scalar of 550 GeV, a wino-like chargino and neutralino signal point of mass 1.3 TeV, and a smuon signal point of mass 350 GeV and neutralino mass of 250 GeV are overlaid for comparison. The lower panels show the ratio of data to the background estimate (&apos;Bkg.&apos;). The &apos;tt+X&apos; background component includes the tt&#772;Z (4&#8467; only) and tt&#772;H processes. The &apos;Other&apos; contribution is dominated by the VH process. The size of the combined statistical and systematic uncertainty in the signal-plus-background prediction is indicated by the blue hatched band. The upward-pointing blue arrow indicates a point for which the data-to-background (&apos;Data/Bkg.’) ratio exceeds the vertical range of the figure.

Comparison between data and the background estimate for the anomaly score distribution used in different benchmark regions before any fit to data (&apos;pre-fit&apos;): (a) 4&#8467; Q=0 0Z 0b 2SFOS e&gt;&mu;, (b) 4&#8467; Q=0 0Z &ge;1b 2SFOS e&gt;&mu;, (c) 4&#8467; Q=0 1Z 0b 2SFOS &mu;&gt;e, (d) 4&#8467; Q=&plusmn;2 0b e&gt;&mu;, (e) 4&#8467; Q=&plusmn;2 &ge;1b &mu;&gt;e, and (f) the three &ge;5&#8467; regions: 0Z 0b &mu;&gt;e, 0Z 0b e&ge;&mu;, and 0Z &ge;1b, defined without AD. Distributions for one flavourful VLL_e signal point for a VLL mass of 1 TeV and scalar of 550 GeV, a wino-like chargino and neutralino signal point of mass 1.3 TeV, and a smuon signal point of mass 350 GeV and neutralino mass of 250 GeV are overlaid for comparison. The lower panels show the ratio of data to the background estimate (&apos;Bkg.&apos;). The &apos;tt+X&apos; background component includes the tt&#772;Z (4&#8467; only) and tt&#772;H processes. The &apos;Other&apos; contribution is dominated by the VH process. The size of the combined statistical and systematic uncertainty in the signal-plus-background prediction is indicated by the blue hatched band. The upward-pointing blue arrow indicates a point for which the data-to-background (&apos;Data/Bkg.’) ratio exceeds the vertical range of the figure.

Comparison between data and the background estimate for the anomaly score distribution used in different benchmark regions before any fit to data (&apos;pre-fit&apos;): (a) 4&#8467; Q=0 0Z 0b 2SFOS e&gt;&mu;, (b) 4&#8467; Q=0 0Z &ge;1b 2SFOS e&gt;&mu;, (c) 4&#8467; Q=0 1Z 0b 2SFOS &mu;&gt;e, (d) 4&#8467; Q=&plusmn;2 0b e&gt;&mu;, (e) 4&#8467; Q=&plusmn;2 &ge;1b &mu;&gt;e, and (f) the three &ge;5&#8467; regions: 0Z 0b &mu;&gt;e, 0Z 0b e&ge;&mu;, and 0Z &ge;1b, defined without AD. Distributions for one flavourful VLL_e signal point for a VLL mass of 1 TeV and scalar of 550 GeV, a wino-like chargino and neutralino signal point of mass 1.3 TeV, and a smuon signal point of mass 350 GeV and neutralino mass of 250 GeV are overlaid for comparison. The lower panels show the ratio of data to the background estimate (&apos;Bkg.&apos;). The &apos;tt+X&apos; background component includes the tt&#772;Z (4&#8467; only) and tt&#772;H processes. The &apos;Other&apos; contribution is dominated by the VH process. The size of the combined statistical and systematic uncertainty in the signal-plus-background prediction is indicated by the blue hatched band. The upward-pointing blue arrow indicates a point for which the data-to-background (&apos;Data/Bkg.’) ratio exceeds the vertical range of the figure.

Observed profile likelihood scans of $\kappa_\lambda$. The scans are performed by varying only the coupling modifier of interest, while all other relevant coupling modifiers are fixed to unity.

Expected profile likelihood scans of $\kappa_\lambda$. The scans are performed by varying only the coupling modifier of interest, while all other relevant coupling modifiers are fixed to unity.

Observed profile likelihood scans of $\kappa_{2V}$. The scans are performed by varying only the coupling modifier of interest, while all other relevant coupling modifiers are fixed to unity.

Expected profile likelihood scans of $\kappa_{2V}$. The scans are performed by varying only the coupling modifier of interest, while all other relevant coupling modifiers are fixed to unity.

Confidence level contours at 68% (solid line) and 95% (dashed line) in the $(\kappa_\lambda, \kappa_{2V})$ parameter space, when all other coupling modifiers are fixed to their SM predictions. The corresponding expected contours are shown by the inner and outer shaded regions The SM prediction is indicated by the star, while the best-fit value is denoted by the cross.

Confidence level contours at 68% (solid line) and 95% (dashed line) in the $(\kappa_\lambda, \kappa_{2V})$ parameter space, when all other coupling modifiers are fixed to their SM predictions. The corresponding expected contours are shown by the inner and outer shaded regions The SM prediction is indicated by the star, while the best-fit value is denoted by the cross.

Observed $m_{\gamma\gamma}$ distributions for the high-mass categories in Run 2. The lines show the fit results for the continuum background only (light dotted), adding the single Higgs boson background (black dotted) and the full fit (solid).

Observed $m_{\gamma\gamma}$ distributions for the high-mass categories in Run 3. The lines show the fit results for the continuum background only (light dotted), adding the single Higgs boson background (black dotted) and the full fit (solid).

Observed $m_{\gamma\gamma}$ distributions for the high-mass categories in Run 2. The lines show the fit results for the continuum background only (light dotted), adding the single Higgs boson background (black dotted) and the full fit (solid).

Observed $m_{\gamma\gamma}$ distributions for the high-mass categories in Run 3. The lines show the fit results for the continuum background only (light dotted), adding the single Higgs boson background (black dotted) and the full fit (solid).

Observed $m_{\gamma\gamma}$ distributions for the high-mass categories in Run 2. 3he lines show the fit results for the continuum background only (light dotted), adding the single Higgs boson background (black dotted) and the full fit (solid).

Observed $m_{\gamma\gamma}$ distributions for the high-mass categories in Run 3. The lines show the fit results for the continuum background only (light dotted), adding the single Higgs boson background (black dotted) and the full fit (solid).

Observed $m_{\gamma\gamma}$ distributions for the low-mass categories in Run 2. The lines show the fit results for the continuum background only (light dotted), adding the single Higgs boson background (black dotted) and the full fit (solid).

Observed $m_{\gamma\gamma}$ distributions for the low-mass categories in Run 3. The lines show the fit results for the continuum background only (light dotted), adding the single Higgs boson background (black dotted) and the full fit (solid).

Observed $m_{\gamma\gamma}$ distributions for the low-mass categories in Run 2. The lines show the fit results for the continuum background only (light dotted), adding the single Higgs boson background (black dotted) and the full fit (solid).

Observed $m_{\gamma\gamma}$ distributions for the low-mass categories in Run 3. The lines show the fit results for the continuum background only (light dotted), adding the single Higgs boson background (black dotted) and the full fit (solid).

Observed $m_{\gamma\gamma}$ distributions for the low-mass categories in Run 2. The lines show the fit results for the continuum background only (light dotted), adding the single Higgs boson background (black dotted) and the full fit (solid).

Observed $m_{\gamma\gamma}$ distributions for the low-mass categories in Run 3. The lines show the fit results for the continuum background only (light dotted), adding the single Higgs boson background (black dotted) and the full fit (solid).

Observed $m_{\gamma\gamma}$ distributions for the low-mass categories in Run 2. The lines show the fit results for the continuum background only (light dotted), adding the single Higgs boson background (black dotted) and the full fit (solid).

Observed $m_{\gamma\gamma}$ distributions for the low-mass categories in Run 3. The lines show the fit results for the continuum background only (light dotted), adding the single Higgs boson background (black dotted) and the full fit (solid).

Observed and expected profiled likelihood scans on $\kappa_\lambda$ for the low-mass (LM) and high-mass (HM) regions separately and for their combination. The scan is performed by floating the indicated parameter of interest while fixing all the others to their SM value.

Observed and expected profiled likelihood scans on $\kappa_\lambda$ for the low-mass (LM) and high-mass (HM) regions separately and for their combination. The scan is performed by floating the indicated parameter of interest while fixing all the others to their SM value.

Observed and expected profiled likelihood scans on $\kappa_\lambda$ for the low-mass (LM) and high-mass (HM) regions separately and for their combination. The scan is performed by floating the indicated parameter of interest while fixing all the others to their SM value.

Observed and expected profiled likelihood scans on $\kappa_\lambda$ for the low-mass (LM) and high-mass (HM) regions separately and for their combination. The scan is performed by floating the indicated parameter of interest while fixing all the others to their SM value.

Observed and expected profiled likelihood scans on $\kappa_\lambda$ for the low-mass (LM) and high-mass (HM) regions separately and for their combination. The scan is performed by floating the indicated parameter of interest while fixing all the others to their SM value.

Observed and expected profiled likelihood scans on $\kappa_\lambda$ for the low-mass (LM) and high-mass (HM) regions separately and for their combination. The scan is performed by floating the indicated parameter of interest while fixing all the others to their SM value.

The expected number of events (estimated by using simulation) from the SM HH signals and single Higgs boson production, and the expected number of events from the continuum background, evaluated in the 120 GeV < $m_{\gamma\gamma}$ < 130 GeV window in Run 3 for the different low-mass (LM) and high-mass (HM) categories. For comparison, the number of data events is also shown. The uncertainties in the HH signals and single Higgs boson backgrounds include the systematic uncertainties discussed in Section 6. Asymmetric uncertainties arise primarily from the theory calculation of the SM ggF HH cross section and the large uncertainty in the yield of single Higgs bosons produced in ggF events in association with heavy-flavour jets. The uncertainty in the continuum background is given by the sum in quadrature of the statistical uncertainty from the fit to the data and the spurious signal uncertainty.

Data (dots) and post-fit SM distribution (histograms) of m_&#8467;j in (a, b) SR-1L-ej and (c, d) SR-2L-ej of the e+light-jet channel obtained by a CR+SR background-only fit for Run&nbsp;2 and Run&nbsp;3, respectively. The lower panel shows the ratio of observed data to the total post- and pre-fit SM prediction. The last bin includes the overflow. Uncertainties in the background estimates include both the statistical and systematic uncertainties, with correlations between uncertainties taken into account. The dashed lines show the predicted yields for two benchmark signal models corresponding to S&#771;₁ (m, y_de) = (2.0&nbsp;TeV, 1.0) and S&#771;₁ (m, y_de) = (3.0&nbsp;TeV, 1.0), respectively. Note: the values in the table are normalized by the width of corresponding bin

Data (dots) and post-fit SM distribution (histograms) of m_&#8467;j in (a, b) SR-1L-&mu;j and (c, d) SR-2L-&mu;j of the &mu;+light-jet channel obtained by a CR+SR background-only fit for Run&nbsp;2 and Run&nbsp;3, respectively. The lower panel shows the ratio of observed data to the total post- and pre-fit SM prediction. The last bin includes the overflow. Uncertainties in the background estimates include both the statistical and systematic uncertainties, with correlations between uncertainties taken into account. The dashed lines show the predicted yields for two benchmark signal models corresponding to S&#771;₁ (m, y_s&mu;) = (2.0&nbsp;TeV, 1.5) and S&#771;₁ (m, y_s&mu;) = (3.0&nbsp;TeV, 1.5), respectively. Note: the values in the table are normalized by the width of corresponding bin

Data (dots) and post-fit SM distribution (histograms) of m_&#8467;j in (a, b) SR-1L-&mu;j and (c, d) SR-2L-&mu;j of the &mu;+light-jet channel obtained by a CR+SR background-only fit for Run&nbsp;2 and Run&nbsp;3, respectively. The lower panel shows the ratio of observed data to the total post- and pre-fit SM prediction. The last bin includes the overflow. Uncertainties in the background estimates include both the statistical and systematic uncertainties, with correlations between uncertainties taken into account. The dashed lines show the predicted yields for two benchmark signal models corresponding to S&#771;₁ (m, y_s&mu;) = (2.0&nbsp;TeV, 1.5) and S&#771;₁ (m, y_s&mu;) = (3.0&nbsp;TeV, 1.5), respectively. Note: the values in the table are normalized by the width of corresponding bin

Data (dots) and post-fit SM distribution (histograms) of m_&#8467;j in (a, b) SR-1L-&mu;j and (c, d) SR-2L-&mu;j of the &mu;+light-jet channel obtained by a CR+SR background-only fit for Run&nbsp;2 and Run&nbsp;3, respectively. The lower panel shows the ratio of observed data to the total post- and pre-fit SM prediction. The last bin includes the overflow. Uncertainties in the background estimates include both the statistical and systematic uncertainties, with correlations between uncertainties taken into account. The dashed lines show the predicted yields for two benchmark signal models corresponding to S&#771;₁ (m, y_s&mu;) = (2.0&nbsp;TeV, 1.5) and S&#771;₁ (m, y_s&mu;) = (3.0&nbsp;TeV, 1.5), respectively. Note: the values in the table are normalized by the width of corresponding bin

Data (dots) and post-fit SM distribution (histograms) of m_&#8467;j in (a, b) SR-1L-&mu;j and (c, d) SR-2L-&mu;j of the &mu;+light-jet channel obtained by a CR+SR background-only fit for Run&nbsp;2 and Run&nbsp;3, respectively. The lower panel shows the ratio of observed data to the total post- and pre-fit SM prediction. The last bin includes the overflow. Uncertainties in the background estimates include both the statistical and systematic uncertainties, with correlations between uncertainties taken into account. The dashed lines show the predicted yields for two benchmark signal models corresponding to S&#771;₁ (m, y_s&mu;) = (2.0&nbsp;TeV, 1.5) and S&#771;₁ (m, y_s&mu;) = (3.0&nbsp;TeV, 1.5), respectively. Note: the values in the table are normalized by the width of corresponding bin

Data (dots) and post-fit SM distribution (histograms) of m_&#8467;j in (a, b) SR-1L-eb and (c, d) SR-2L-eb of the e+b-jet channel obtained by a CR+SR background-only fit for Run&nbsp;2 and Run&nbsp;3, respectively. The lower panel shows the ratio of observed data to the total post- and pre-fit SM prediction. The last bin includes the overflow. Uncertainties in the background estimates include both the statistical and systematic uncertainties, with correlations between uncertainties taken into account. The dashed lines show the predicted yields for two benchmark signal models corresponding to S&#771;₁ (m, y_be) = (1.5&nbsp;TeV, 2.5) and S&#771;₁ (m, y_be) = (2.0&nbsp;TeV, 2.5), respectively. Note: the values in the table are normalized by the width of corresponding bin

Data (dots) and post-fit SM distribution (histograms) of m_&#8467;j in (a, b) SR-1L-eb and (c, d) SR-2L-eb of the e+b-jet channel obtained by a CR+SR background-only fit for Run&nbsp;2 and Run&nbsp;3, respectively. The lower panel shows the ratio of observed data to the total post- and pre-fit SM prediction. The last bin includes the overflow. Uncertainties in the background estimates include both the statistical and systematic uncertainties, with correlations between uncertainties taken into account. The dashed lines show the predicted yields for two benchmark signal models corresponding to S&#771;₁ (m, y_be) = (1.5&nbsp;TeV, 2.5) and S&#771;₁ (m, y_be) = (2.0&nbsp;TeV, 2.5), respectively. Note: the values in the table are normalized by the width of corresponding bin

Data (dots) and post-fit SM distribution (histograms) of m_&#8467;j in (a, b) SR-1L-eb and (c, d) SR-2L-eb of the e+b-jet channel obtained by a CR+SR background-only fit for Run&nbsp;2 and Run&nbsp;3, respectively. The lower panel shows the ratio of observed data to the total post- and pre-fit SM prediction. The last bin includes the overflow. Uncertainties in the background estimates include both the statistical and systematic uncertainties, with correlations between uncertainties taken into account. The dashed lines show the predicted yields for two benchmark signal models corresponding to S&#771;₁ (m, y_be) = (1.5&nbsp;TeV, 2.5) and S&#771;₁ (m, y_be) = (2.0&nbsp;TeV, 2.5), respectively. Note: the values in the table are normalized by the width of corresponding bin

Data (dots) and post-fit SM distribution (histograms) of m_&#8467;j in (a, b) SR-1L-eb and (c, d) SR-2L-eb of the e+b-jet channel obtained by a CR+SR background-only fit for Run&nbsp;2 and Run&nbsp;3, respectively. The lower panel shows the ratio of observed data to the total post- and pre-fit SM prediction. The last bin includes the overflow. Uncertainties in the background estimates include both the statistical and systematic uncertainties, with correlations between uncertainties taken into account. The dashed lines show the predicted yields for two benchmark signal models corresponding to S&#771;₁ (m, y_be) = (1.5&nbsp;TeV, 2.5) and S&#771;₁ (m, y_be) = (2.0&nbsp;TeV, 2.5), respectively. Note: the values in the table are normalized by the width of corresponding bin

Data (dots) and post-fit SM distribution (histograms) of m_&#8467;j in (a, b) SR-1L-&mu;b and (c, d) SR-2L-&mu;b of the &mu;+b-jet channel obtained by a CR+SR background-only fit for Run&nbsp;2 and Run&nbsp;3, respectively. The lower panel shows the ratio of observed data to the total post- and pre-fit SM prediction. The last bin includes the overflow. Uncertainties in the background estimates include both the statistical and systematic uncertainties, with correlations between uncertainties taken into account. The dashed lines show the predicted yields for two benchmark signal models corresponding to S&#771;₁ (m, y_b&mu;) = (1.5&nbsp;TeV, 1.5) and S&#771;₁ (m, y_b&mu;) = (2.0&nbsp;TeV, 1.5), respectively. Note: the values in the table are normalized by the width of corresponding bin

Data (dots) and post-fit SM distribution (histograms) of m_&#8467;j in (a, b) SR-1L-&mu;b and (c, d) SR-2L-&mu;b of the &mu;+b-jet channel obtained by a CR+SR background-only fit for Run&nbsp;2 and Run&nbsp;3, respectively. The lower panel shows the ratio of observed data to the total post- and pre-fit SM prediction. The last bin includes the overflow. Uncertainties in the background estimates include both the statistical and systematic uncertainties, with correlations between uncertainties taken into account. The dashed lines show the predicted yields for two benchmark signal models corresponding to S&#771;₁ (m, y_b&mu;) = (1.5&nbsp;TeV, 1.5) and S&#771;₁ (m, y_b&mu;) = (2.0&nbsp;TeV, 1.5), respectively. Note: the values in the table are normalized by the width of corresponding bin

Data (dots) and post-fit SM distribution (histograms) of m_&#8467;j in (a, b) SR-1L-&mu;b and (c, d) SR-2L-&mu;b of the &mu;+b-jet channel obtained by a CR+SR background-only fit for Run&nbsp;2 and Run&nbsp;3, respectively. The lower panel shows the ratio of observed data to the total post- and pre-fit SM prediction. The last bin includes the overflow. Uncertainties in the background estimates include both the statistical and systematic uncertainties, with correlations between uncertainties taken into account. The dashed lines show the predicted yields for two benchmark signal models corresponding to S&#771;₁ (m, y_b&mu;) = (1.5&nbsp;TeV, 1.5) and S&#771;₁ (m, y_b&mu;) = (2.0&nbsp;TeV, 1.5), respectively. Note: the values in the table are normalized by the width of corresponding bin

Data (dots) and post-fit SM distribution (histograms) of m_&#8467;j in (a, b) SR-1L-&mu;b and (c, d) SR-2L-&mu;b of the &mu;+b-jet channel obtained by a CR+SR background-only fit for Run&nbsp;2 and Run&nbsp;3, respectively. The lower panel shows the ratio of observed data to the total post- and pre-fit SM prediction. The last bin includes the overflow. Uncertainties in the background estimates include both the statistical and systematic uncertainties, with correlations between uncertainties taken into account. The dashed lines show the predicted yields for two benchmark signal models corresponding to S&#771;₁ (m, y_b&mu;) = (1.5&nbsp;TeV, 1.5) and S&#771;₁ (m, y_b&mu;) = (2.0&nbsp;TeV, 1.5), respectively. Note: the values in the table are normalized by the width of corresponding bin

Exclusion limits for minimal models of S&#771;₁ production with only y_de being non-zero obtained from a simultaneous fit to SR-1L and SR-2L of the e+light-jet channel combining Run-2 and Run-3 data. All limits are computed at 95&percnt; CL and the observed (red solid lines) and expected (black dashed lines) exclusion limits are shown in the m(S&#771;₁) &ndash; y_de plane. The observed exclusion should be interpreted as the region above the red line. The yellow inner (green outer) shaded band around the expected limits corresponds to the &plusmn;1 &sigma; (&plusmn;2 &sigma;) variations of the expected limit, accounting for all uncertainties. The observed limit obtained from ATLAS searches for LQ pair production is also shown as dark blue line [13]. Constraints from weak charge measurements of protons and nuclei on y_de couplings derived by Ref. [10] are shown as light magenta line.

Exclusion limits for minimal models of S&#771;₁ production with only y_s&mu; being non-zero obtained from a simultaneous fit to SR-1L and SR-2L of the &mu;+light-jet channel combining Run-2 and Run-3 data. All limits are computed at 95&percnt; CL and the observed (red solid lines) and expected (black dashed lines) exclusion limits are shown in the m(S&#771;₁) &ndash; y_s&mu; plane. The observed exclusion should be interpreted as the region above the red line. The yellow inner (green outer) shaded band around the expected limits corresponds to the &plusmn;1 &sigma; (&plusmn;2 &sigma;) variations of the expected limit, accounting for all uncertainties. The observed limit obtained from ATLAS searches for LQ pair production is also shown as dark blue line [13].

Exclusion limits for minimal models of S&#771;₁ production with only y_be being non-zero obtained from a simultaneous fit to SR-1L and SR-2L of the e+b-jet channel combining Run-2 and Run-3 data. All limits are computed at 95&percnt; CL and the observed (red solid lines) and expected (black dashed lines) exclusion limits are shown in the m(S&#771;₁) &ndash; y_be plane. The observed exclusion should be interpreted as the region above the red line. The yellow inner (green outer) shaded band around the expected limits corresponds to the &plusmn;1 &sigma; (&plusmn;2 &sigma;) variations of the expected limit, accounting for all uncertainties. The observed limit obtained from ATLAS searches for LQ pair production is also shown as dark blue line [13].

Exclusion limits for minimal models of S&#771;₁ production with only y_b&mu; being non-zero obtained from a simultaneous fit to SR-1L and SR-2L of the &mu;+b-jet channel combining Run-2 and Run-3 data. All limits are computed at 95&percnt; CL and the observed (red solid lines) and expected (black dashed lines) exclusion limits are shown in the m(S&#771;₁) &ndash; y_b&mu; plane. The observed exclusion should be interpreted as the region above the red line. The yellow inner (green outer) shaded band around the expected limits corresponds to the &plusmn;1 &sigma; (&plusmn;2 &sigma;) variations of the expected limit, accounting for all uncertainties. The observed limit obtained from ATLAS searches for LQ pair production is also shown as dark blue line [13].

Exclusion limits for minimal models of S&#771;₁ production obtained from a fit to SR-1L, SR-2L and their combination of (a) the e+light-jet, (b) the &mu;+light-jet, (c) the e+b-jet and (d) the &mu;+b-jet channel using Run-2 and Run-3 data. All limits are computed at 95&percnt; CL and the observed (solid lines) and expected (dashed lines) exclusion limits are shown in the m(S&#771;₁) &ndash; y plane. The observed exclusion regions should be interpreted as the region above the solid lines. Constraints from weak charge measurements of protons and nuclei&nbsp; and ATLAS searches for LQ pair production&nbsp; are shown as light magenta and dark blue areas, respectively.

Exclusion limits for minimal models of S&#771;₁ production obtained from a fit to SR-1L, SR-2L and their combination of (a) the e+light-jet, (b) the &mu;+light-jet, (c) the e+b-jet and (d) the &mu;+b-jet channel using Run-2 and Run-3 data. All limits are computed at 95&percnt; CL and the observed (solid lines) and expected (dashed lines) exclusion limits are shown in the m(S&#771;₁) &ndash; y plane. The observed exclusion regions should be interpreted as the region above the solid lines. Constraints from weak charge measurements of protons and nuclei&nbsp; and ATLAS searches for LQ pair production&nbsp; are shown as light magenta and dark blue areas, respectively.

Exclusion limits for minimal models of S&#771;₁ production obtained from a fit to SR-1L, SR-2L and their combination of (a) the e+light-jet, (b) the &mu;+light-jet, (c) the e+b-jet and (d) the &mu;+b-jet channel using Run-2 and Run-3 data. All limits are computed at 95&percnt; CL and the observed (solid lines) and expected (dashed lines) exclusion limits are shown in the m(S&#771;₁) &ndash; y plane. The observed exclusion regions should be interpreted as the region above the solid lines. Constraints from weak charge measurements of protons and nuclei&nbsp; and ATLAS searches for LQ pair production&nbsp; are shown as light magenta and dark blue areas, respectively.

Exclusion limits for minimal models of S&#771;₁ production obtained from a fit to SR-1L, SR-2L and their combination of (a) the e+light-jet, (b) the &mu;+light-jet, (c) the e+b-jet and (d) the &mu;+b-jet channel using Run-2 and Run-3 data. All limits are computed at 95&percnt; CL and the observed (solid lines) and expected (dashed lines) exclusion limits are shown in the m(S&#771;₁) &ndash; y plane. The observed exclusion regions should be interpreted as the region above the solid lines. Constraints from weak charge measurements of protons and nuclei&nbsp; and ATLAS searches for LQ pair production&nbsp; are shown as light magenta and dark blue areas, respectively.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for resonant production of $\tilde{S}$ in (a) Run 2 SR-1L-$ej$ and (b) Run 2 SR-2L-$ej$ and (c) Run 3 SR-1-$ej$ and (d) Run 3 SR-2-$ej$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for resonant production of $\tilde{S}$ in (a) Run 2 SR-1L-$ej$ and (b) Run 2 SR-2L-$ej$ and (c) Run 3 SR-1-$ej$ and (d) Run 3 SR-2-$ej$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for resonant production of $\tilde{S}$ in (a) Run 2 SR-1L-$ej$ and (b) Run 2 SR-2L-$ej$ and (c) Run 3 SR-1-$ej$ and (d) Run 3 SR-2-$ej$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for resonant production of $\tilde{S}$ in (a) Run 2 SR-1L-$ej$ and (b) Run 2 SR-2L-$ej$ and (c) Run 3 SR-1-$ej$ and (d) Run 3 SR-2-$ej$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for DY+SP production of $\tilde{S}$ in (a) Run 2 SR-1L-$ej$ and (b) Run 2 SR-2L-$ej$ and (c) Run 3 SR-1-$ej$ and (d) Run 3 SR-2-$ej$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for DY+SP production of $\tilde{S}$ in (a) Run 2 SR-1L-$ej$ and (b) Run 2 SR-2L-$ej$ and (c) Run 3 SR-1-$ej$ and (d) Run 3 SR-2-$ej$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for DY+SP production of $\tilde{S}$ in (a) Run 2 SR-1L-$ej$ and (b) Run 2 SR-2L-$ej$ and (c) Run 3 SR-1-$ej$ and (d) Run 3 SR-2-$ej$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for DY+SP production of $\tilde{S}$ in (a) Run 2 SR-1L-$ej$ and (b) Run 2 SR-2L-$ej$ and (c) Run 3 SR-1-$ej$ and (d) Run 3 SR-2-$ej$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for resonant production of $\tilde{S}$ in (a) Run 2 SR-1L-$\mu j$ and (b) Run 2 SR-2L-$\mu j$ and (c) Run 3 SR-1L-$\mu j$ and (d) Run 3 SR-2L-$\mu j$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for resonant production of $\tilde{S}$ in (a) Run 2 SR-1L-$\mu j$ and (b) Run 2 SR-2L-$\mu j$ and (c) Run 3 SR-1L-$\mu j$ and (d) Run 3 SR-2L-$\mu j$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for resonant production of $\tilde{S}$ in (a) Run 2 SR-1L-$\mu j$ and (b) Run 2 SR-2L-$\mu j$ and (c) Run 3 SR-1L-$\mu j$ and (d) Run 3 SR-2L-$\mu j$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for resonant production of $\tilde{S}$ in (a) Run 2 SR-1L-$\mu j$ and (b) Run 2 SR-2L-$\mu j$ and (c) Run 3 SR-1L-$\mu j$ and (d) Run 3 SR-2L-$\mu j$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for DY+SP production of $\tilde{S}$ in (a) Run 2 SR-1L-$\mu j$ and (b) Run 2 SR-2L-$\mu j$ and (c) Run 3 SR-1L-$\mu j$ and (d) Run 3 SR-2L-$\mu j$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for DY+SP production of $\tilde{S}$ in (a) Run 2 SR-1L-$\mu j$ and (b) Run 2 SR-2L-$\mu j$ and (c) Run 3 SR-1L-$\mu j$ and (d) Run 3 SR-2L-$\mu j$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for DY+SP production of $\tilde{S}$ in (a) Run 2 SR-1L-$\mu j$ and (b) Run 2 SR-2L-$\mu j$ and (c) Run 3 SR-1L-$\mu j$ and (d) Run 3 SR-2L-$\mu j$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for DY+SP production of $\tilde{S}$ in (a) Run 2 SR-1L-$\mu j$ and (b) Run 2 SR-2L-$\mu j$ and (c) Run 3 SR-1L-$\mu j$ and (d) Run 3 SR-2L-$\mu j$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for resonant production of $\tilde{S}$ in (a) Run 2 SR-1L-$eb$ and (b) Run 2 SR-2L-$eb$ and (c) Run 3 SR-1L-$eb$ and (d) Run 3 SR-2L-$eb$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for resonant production of $\tilde{S}$ in (a) Run 2 SR-1L-$eb$ and (b) Run 2 SR-2L-$eb$ and (c) Run 3 SR-1L-$eb$ and (d) Run 3 SR-2L-$eb$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for resonant production of $\tilde{S}$ in (a) Run 2 SR-1L-$eb$ and (b) Run 2 SR-2L-$eb$ and (c) Run 3 SR-1L-$eb$ and (d) Run 3 SR-2L-$eb$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for resonant production of $\tilde{S}$ in (a) Run 2 SR-1L-$eb$ and (b) Run 2 SR-2L-$eb$ and (c) Run 3 SR-1L-$eb$ and (d) Run 3 SR-2L-$eb$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for DY+SP of $\tilde{S}$ in (a) Run 2 SR-1L-$eb$ and (b) Run 2 SR-2L-$eb$ and (c) Run 3 SR-1L-$eb$ and (d) Run 3 SR-2L-$eb$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for DY+SP of $\tilde{S}$ in (a) Run 2 SR-1L-$eb$ and (b) Run 2 SR-2L-$eb$ and (c) Run 3 SR-1L-$eb$ and (d) Run 3 SR-2L-$eb$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for DY+SP of $\tilde{S}$ in (a) Run 2 SR-1L-$eb$ and (b) Run 2 SR-2L-$eb$ and (c) Run 3 SR-1L-$eb$ and (d) Run 3 SR-2L-$eb$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for DY+SP of $\tilde{S}$ in (a) Run 2 SR-1L-$eb$ and (b) Run 2 SR-2L-$eb$ and (c) Run 3 SR-1L-$eb$ and (d) Run 3 SR-2L-$eb$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for resonant production of $\tilde{S}$ in (a) Run 2 SR-1L-$\mu b$ and (b) Run 2 SR-2L-$\mu b$ and (c) Run 3 SR-1L-$\mu b$ and (d) Run 3 SR-2L-$\mu b$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for resonant production of $\tilde{S}$ in (a) Run 2 SR-1L-$\mu b$ and (b) Run 2 SR-2L-$\mu b$ and (c) Run 3 SR-1L-$\mu b$ and (d) Run 3 SR-2L-$\mu b$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for resonant production of $\tilde{S}$ in (a) Run 2 SR-1L-$\mu b$ and (b) Run 2 SR-2L-$\mu b$ and (c) Run 3 SR-1L-$\mu b$ and (d) Run 3 SR-2L-$\mu b$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for resonant production of $\tilde{S}$ in (a) Run 2 SR-1L-$\mu b$ and (b) Run 2 SR-2L-$\mu b$ and (c) Run 3 SR-1L-$\mu b$ and (d) Run 3 SR-2L-$\mu b$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for DY+SP production of $\tilde{S}$ in (a) Run 2 SR-1L-$\mu b$ and (b) Run 2 SR-2L-$\mu b$ and (c) Run 3 SR-1L-$\mu b$ and (d) Run 3 SR-2L-$\mu b$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for DY+SP production of $\tilde{S}$ in (a) Run 2 SR-1L-$\mu b$ and (b) Run 2 SR-2L-$\mu b$ and (c) Run 3 SR-1L-$\mu b$ and (d) Run 3 SR-2L-$\mu b$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for DY+SP production of $\tilde{S}$ in (a) Run 2 SR-1L-$\mu b$ and (b) Run 2 SR-2L-$\mu b$ and (c) Run 3 SR-1L-$\mu b$ and (d) Run 3 SR-2L-$\mu b$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Values of the signal acceptance multiplied by the selection efficiency ($A\times\epsilon$) for DY+SP production of $\tilde{S}$ in (a) Run 2 SR-1L-$\mu b$ and (b) Run 2 SR-2L-$\mu b$ and (c) Run 3 SR-1L-$\mu b$ and (d) Run 3 SR-2L-$\mu b$. The $A \times \epsilon$ values are calculated as the number of events of reconstructed-level signal simulation divided by the total cross-section of the signal process times the integrated luminosity.

Event selection cutflows of SR-1L-$eb$ for the signal sample with $m(\tilde{S}) = 2$ TeV and $y_{be} = 1.0$ individually for resonant production (RP) and combined Drell-Yan plus single production (DY+SP). The first number in the column for each mass points corresponds to the signal event yield after applying the associated cut while the second number in parentheses represents the efficiency with respect to the previous cut.

Event selection cutflows of SR-2L-$eb$ for the signal sample with $m(\tilde{S}) = 2$ TeV and $y_{be} = 1.0$ individually for resonant production (RP) and combined Drell-Yan plus single production (DY+SP). The first number in the column for each mass points corresponds to the signal event yield after applying the associated cut while the second number in parentheses represents the efficiency with respect to the previous cut.

Event selection cutflows of SR-1L-$ej$ for the signal sample with $m(\tilde{S}) = 2$ TeV and $y_{de} = 1.0$ individually for resonant production (RP) and combined Drell-Yan plus single production (DY+SP). The first number in the column for each mass points corresponds to the signal event yield after applying the associated cut while the second number in parentheses represents the efficiency with respect to the previous cut.

Event selection cutflows of SR-2L-$ej$ for the signal sample with $m(\tilde{S}) = 2$ TeV and $y_{de} = 1.0$ individually for resonant production (RP) and combined Drell-Yan plus single production (DY+SP). The first number in the column for each mass points corresponds to the signal event yield after applying the associated cut while the second number in parentheses represents the efficiency with respect to the previous cut.

Event selection cutflows of SR-1L-$\mu b$ for the signal sample with $m(\tilde{S}) = 2$ TeV and $y_{b\mu} = 1.0$ individually for resonant production (RP) and combined Drell-Yan plus single production (DY+SP). The first number in the column for each mass points corresponds to the signal event yield after applying the associated cut while the second number in parentheses represents the efficiency with respect to the previous cut.

Event selection cutflows of SR-2L-$\mu b$ for the signal sample with $m(\tilde{S}) = 2$ TeV and $y_{b\mu} = 1.0$ individually for resonant production (RP) and combined Drell-Yan plus single production (DY+SP). The first number in the column for each mass points corresponds to the signal event yield after applying the associated cut while the second number in parentheses represents the efficiency with respect to the previous cut.

Event selection cutflows of SR-1L-$\mu j$ for the signal sample with $m(\tilde{S}) = 2$ TeV and $y_{s\mu} = 1.0$ individually for resonant production (RP) and combined Drell-Yan plus single production (DY+SP). The first number in the column for each mass points corresponds to the signal event yield after applying the associated cut while the second number in parentheses represents the efficiency with respect to the previous cut.

Event selection cutflows of SR-2L-$\mu j$ for the signal sample with $m(\tilde{S}) = 2$ TeV and $y_{s\mu} = 1.0$ individually for resonant production (RP) and combined Drell-Yan plus single production (DY+SP). The first number in the column for each mass points corresponds to the signal event yield after applying the associated cut while the second number in parentheses represents the efficiency with respect to the previous cut.

Unfolded $R(\rho_{s})$ observable in the 2-to-3 measurement (normalized and divided by bin width). The parton level is defined with two stable top-quarks and a jet with $p_{T}>50$ GeV and $|\eta|<2.5$.

Covariance matrix for statistical effects of the measured $R(\rho_{s})$ observable after unfolding, for the 2-to-3 measurement (normalized)

Covariance matrix for statistical and systematic effects of the measured $R(\rho_{s})$ observable after unfolding, for the 2-to-3 measurement (normalized)

Impact of systematic uncertainties on the 2-to-3 unfolded observable. Values are given in percentage of bin content.

Central value and breakdown of the uncertainties affecting the top-quark pole mass extraction from the 2-to-3 unfolded observable.

Unfolded number of events in the 2-to-7measurement (not normalized). The parton level is defined with two neutrinos, one electron and one muon of opposite electric charges, two $b$-jets and an additional jet (extrajet). The four-momentum of the sum of neutrinos has transverse component larger than 30 GeV. The $p_{T}$-leading lepton has $p_{T}>28$ GeV, while the sub-leading has $p_{T}>20$ GeV. The two $b$-jets with have $p_{T}>30$ GeV and the extrajet has $p^\text{extrajet}_{T}>60$ GeV. All the leptons and jets are separated by $\Delta R >0.4$ and have $|\eta|<2.5$.

Covariance matrix for statistical effects of the measured number of events after unfolding, for the 2-to-7 measurement (not normalized)

Covariance matrix for statistical and systematic effects of the measured number of events after unfolding, for the 2-to-7 measurement (not normalized)

Unfolded $R(\rho_{s})$ observable in the 2-to-7 measurement (normalized and divided by bin width). The parton level is defined with two neutrinos, one electron and one muon of opposite electric charges, two $b$-jets and an additional jet (extrajet). The four-momentum of the sum of neutrinos has transverse component larger than 30 GeV. The $p_{T}$-leading lepton has $p_{T}>28$ GeV, while the sub-leading has $p_{T}>20$ GeV. The two $b$-jets with have $p_{T}>30$ GeV and the extrajet has $p^\text{extrajet}_{T}>60$ GeV. All the leptons and jets are separated by $\Delta R >0.4$ and have $|\eta|<2.5$.

Covariance matrix for statistical effects of the measured $R(\rho_{s})$ observable after unfolding, for the 2-to-7 measurement (normalized)

Covariance matrix for statistical and systematic effects of the measured $R(\rho_{s})$ observable after unfolding, for the 2-to-7 measurement (normalized)

Impact of systematic uncertainties on the 2-to-7 unfolded observable. Values are given in percentage of bin content.

Central value and breakdown of the uncertainties affecting the top-quark pole mass extraction from the 2-to-7 unfolded observable.

The 95% CL limits on the cross-section $\sigma(pp \rightarrow Z' \rightarrow \chi \chi$) times branching ratio B in fb with all statistical and systematic uncertainties, for the $R_{\text{inv}}=$0.6 signal points.

Data yield in the PFN signal region.

Yield of data in the ANTELOPE signal region in the binning used for BumpHunter fitting.

Pre-fit MC statistical uncertainties per bin. These values are used to quantify the MC statistical uncertainty contributions to the total uncertainty in $m_t$ based on elements from the covariance matrix obtained in the profile likelihood fit. Each MC statistical contribution is estimated by dividing the relevant covariance matrix entry (see Table 2) by the corresponding pre-fit MC statistical uncertainty for that bin.

The contribution of each source of systematic uncertainty to the total uncertainty in $m_t$ is provided. Each source's contribution is taken directly from the relevant element of the covariance matrix for the profile likelihood fit to $\overline{m_J}$, $m_{jj}$, and $m_{tj}$ using data. The sign of the effect of each uncertainty is included.

The fitted $m_t$ is provided for each replica generated using bootstrapping. Each replica is a 3D histogram of $m_{J}$, $m_{jj}$, and $m_{tj}$, where $m_{J}$ has 50 bins between 145.0 GeV and 205.0 GeV. This method uses the BootstrapGenerator class in ROOT to initialise a pseudo-random number generator for each event, which is seeded by the value of the eventNumber and runNumber variables for a given event in the input dataset. The pseudo-random numbers are drawn from a Poisson distribution with rate parameter equal to 1. These are used to fluctuate the amount by which each replica histogram is filled. There are 1000 replicas, numbered from 0 to 999.