The 95% CL upper limits on the inclusive signal strength $ r = \sigma_{HH} /\sigma_{HH} ^\text{SM} $ for each channel and their combination. The inner (green) band and the outer (yellow) band indicate the 68 and 95% CL intervals, respectively, under the background-only hypothesis. The $ b\overline{b}b\overline{b} $ and $ b\overline{b}WW $ contributions have been combined in order to simplify the presentation of results.

The 95$\%$ CL upper limits on the VBF signal strength $r_{VBF HH} = \sigma_{VBF HH}/\sigma_{VBF HH}^{SM}$ for each channel and their combination. The inner (green) band and the outer (yellow) band indicate the 68 and 95$\%$ CL intervals, respectively, under the background-only hypothesis. Not all of the eight channels are used to extract the combined VBF limit. The contributing channels are indicated in the figure. The b\overline{b}b\overline{b} $ and $ b\overline{b}WW $ contributions have been combined in order to simplify the presentation of results.

The 95$\%$ CL upper limits on the inclusive HH cross section as a function of $\kappa_\lambda$. All other couplings are set to the values predicted by the SM. The theoretical uncertainties in the HH GGF and VBF signal cross sections are not considered because here we directly constrain the measured cross section.The inner (green) band and the outer (yellow) band indicate the 68 and 95$\%$ CL intervals, respectively, under the background-only hypothesis. The star shows the limit at the SM value for $\kappa_\lambda$.

The 95$\%$ CL upper limits on the inclusive HH cross section as a function of $\kappa_{2V}$. All other couplings are set to the values predicted by the SM. The theoretical uncertainties in the HH VBF signal cross sections are not considered because here we directly constrain the measured cross section.The inner (green) band and the outer (yellow) band indicate the 68 and 95$\%$ CL intervals, respectively, under the background-only hypothesis. The star shows the limit at the SM value for $\kappa_{2V}$.

The profile likelihood ratio test statistic $-2\Delta\log(L)$ as a function of coupling modifiers $\kappa_\lambda$ for the combination of all channels, when all the other parameters are fixed to their SM values.

The profile likelihood ratio test statistic $-2\Delta\log(L)$ as a function of coupling modifiers $\kappa_{2V}$ for the combination of all channels, when all the other parameters are fixed to their SM values.

The 68 $\%$ CL expected contours of $-2\Delta\log(L)$ in the ($\kappa_\lambda$, $\kappa_{2V}$) plane for the combination of all channels when all the other parameters are fixed to their SM values.

The 95$\%$ CL expected contours of $-2\Delta\log(L)$ in the ($\kappa_\lambda$, $\kappa_{2V}$) plane for the combination of all channels when all the other parameters are fixed to their SM values.

The 68 $\%$ CL observed contours of $-2\Delta\log(L)$ in the ($\kappa_\lambda$, $\kappa_{2V}$) plane for the combination of all channels when all the other parameters are fixed to their SM values.

The 95$\%$ observed CL contours of $-2\Delta\log(L)$ in the ($\kappa_\lambda$, $\kappa_{2V}$) plane for the combination of all channels when all the other parameters are fixed to their SM values.

The 5 standard deviation expected contours of $-2\Delta\log(L)$ in the ($\kappa_\lambda$, $\kappa_{2V}$) plane for the combination of all channels when all the other parameters are fixed to their SM values.

The 5 standard deviation observed contours of $-2\Delta\log(L)$ in the ($\kappa_\lambda$, $\kappa_{2V}$) plane for the combination of all channels when all the other parameters are fixed to their SM values.

The observed best-fit values in the ($\kappa_\lambda$, $\kappa_{2V}$) plane for the combination of all channels when all the other parameters are fixed to their SM values.

The 68 $\%$ expected CL contours of $-2\Delta\log(L)$ in the ($\kappa_{V}$, $\kappa_{2V}$) plane for the combination of all channels when all the other parameters are fixed to their SM values.

The 68$\%$ expected CL contours of $-2\Delta\log(L)$ in the ($\kappa_{V}$, $\kappa_{2V}$) plane for the combination of all channels when all the other parameters are fixed to their SM values.

The 95$\%$ CL expected contours of $-2\Delta\log(L)$ in the ($\kappa_{V}$, $\kappa_{2V}$) plane for the combination of all channels when all the other parameters are fixed to their SM values.

The 95$\%$ CL observed contours of $-2\Delta\log(L)$ in the ($\kappa_{V}$, $\kappa_{2V}$) plane for the combination of all channels when all the other parameters are fixed to their SM values.

The 5 standard deviation expected contours of $-2\Delta\log(L)$ in the ($\kappa_{V}$, $\kappa_{2V}$) plane for the combination of all channels when all the other parameters are fixed to their SM values.

The 5 standard deviation observed contours of $-2\Delta\log(L)$ in the ($\kappa_{V}$, $\kappa_{2V}$) plane for the combination of all channels when all the other parameters are fixed to their SM values.

The observed best-fit values in the ($\kappa_{V}$, $\kappa_{2V}$) plane for the combination of all channels when all the other parameters are fixed to their SM values.

The 68 $\%$ CL expected contours of $-2\Delta\log(L)$ in the ($\kappa_\lambda$, $\kappa_t$) plane for the combination of all channels when all the other parameters are fixed to their SM values.

The 68 $\%$ CL observed contours of $-2\Delta\log(L)$ in the ($\kappa_\lambda$, $\kappa_t$) plane for the combination of all channels when all the other parameters are fixed to their SM values.

The 95$\%$ CL expected contours of $-2\Delta\log(L)$ in the ($\kappa_\lambda$, $\kappa_t$) plane for the combination of all channels when all the other parameters are fixed to their SM values.

The 95$\%$ CL observed contours of $-2\Delta\log(L)$ in the ($\kappa_\lambda$, $\kappa_t$) plane for the combination of all channels when all the other parameters are fixed to their SM values.

The observed best-fit values in the ($\kappa_\lambda$, $\kappa_t$) plane for the combination of all channels when all the other parameters are fixed to their SM values.

Upper limits on the HH production cross section at 95$\%$ CL for the two sets of HEFT benchmarks. The theoretical uncertainties in the HH GGF signal cross section are not considered because we directly constrain the measured cross section.

Upper limits on the HH cross section as a function of the $C_2$ coupling modifier. The theoretical uncertainties in the HH GGF signal cross section are not considered because we directly constrain the measured cross section.

The profile likelihood ratio test statistic $-2\Delta\log(L)$ as a function of the $c_2$ coupling modifier.

The 68$\%$CL expected contours of $-2\Delta\log(L)$ in the ($c_2$,$\kappa_t$) for the combination of all channels when all the other parameters are fixed to their SM value.

The 68$\%$CL observed contours of $-2\Delta\log(L)$ in the ($c_2$,$\kappa_t$) for the combination of all channels when all the other parameters are fixed to their SM value.

The 95$\%$CL expected contours of $-2\Delta\log(L)$ in the ($c_2$,$\kappa_t$) for the combination of all channels when all the other parameters are fixed to their SM value.

The 95$\%$CL observed contours of $-2\Delta\log(L)$ in the ($c_2$,$\kappa_t$) for the combination of all channels when all the other parameters are fixed to their SM value.

The 68 $\%$ CL expected contours of $-2\Delta\log(L)$ in the ($c_2$, $\kappa_\lambda$) for the combination of all channels when all the other parameters are fixed to their SM value.

The 68 $\%$ CL observed contours of $-2\Delta\log(L)$ in the ($c_2$, $\kappa_\lambda$) for the combination of all channels when all the other parameters are fixed to their SM value.

The 95 $\%$ CL expected contours of $-2\Delta\log(L)$ in the ($c_2$, $\kappa_\lambda$) for the combination of all channels when all the other parameters are fixed to their SM value.

The 95 $\%$ CL observed contours of $-2\Delta\log(L)$ in the ($c_2$, $\kappa_\lambda$) for the combination of all channels when all the other parameters are fixed to their SM value.

The $-2\Delta\log(L)$ scan for the combination of all channels as a function of $|\cos{\alpha}|$ for singlet extensions of the SM with spontaneous $Z_2$ symmetry breaking. The $|\cos{\alpha}|$ is constrained at 95\% CL between 0.79 and 1. The ranges of $|\cos{\alpha}|$ and $\lambda_\text{eff}$ are chosen to guarantee the validity of the models. The excluded regions are below the curves shown.

The 95$\%$ CL expected contour of $-2\Delta\log(L)$ in the ($|\cos{\alpha}|$, $\lambda_{eff}$) plane, where $\lambda_{eff}$=$\lambda_\alpha$-$\tan{(\alpha)\frac{m_{2}}{\nu}}$. The ranges of $|\cos{\alpha}|$ and $\lambda_{eff}$ are chosen to guarantee the validity of the models. The excluded regions are to the left of the curves shown.

The 95$\%$ CL observed contour of $-2\Delta\log(L)$ in the ($|\cos{\alpha}|$, $\lambda_{eff}$) plane, where $\lambda_{eff}$=$\lambda_\alpha$-$\tan{(\alpha)\frac{m_{2}}{\nu}}$. The ranges of $|\cos{\alpha}|$ and $\lambda_{eff}$ are chosen to guarantee the validity of the models. The excluded regions are to the left of the curves shown.

The 95% CL expected contour of $-2\Delta\log(L)$ for the combination of all channels in the ($m_{H}$, $\tan\beta$) plane for a fixed value of $|\cos(\beta-\alpha)|=0.2$ in the 2HDM-I model. In these and all other cases considered in this paper, $m_H$ = $m_A$. The ranges of $m_{H}$ and $\tan\beta$ are chosen to guarantee the validity of the models. The excluded regions are below the curves shown. The value $\tan\beta$ = 0.5 is excluded for $m_{H}$ > 800 GeV for all models considered.

The 95$\%$ CL observed contour of $-2\Delta\log(L)$ for the combination of all channels in the ($m_{H}$, $\tan\beta$) plane for a fixed value of $|\cos(\beta-\alpha)|=0.2$ in the 2HDM-I model. In these and all other cases considered in this paper, $m_H$ = $m_A$. The ranges of $m_{H}$ and $\tan\beta$ are chosen to guarantee the validity of the models. The excluded regions are below the curves shown. The value $\tan\beta$ = 0.5 is excluded for $m_{H}$ > 800 GeV for all models considered.

The 95$\%$ CL contour of $-2\Delta\log(L)$ for the combination of all channels in the ($m_{H}$, $\tan\beta$) plane for a fixed value of $|\cos(\beta-\alpha)|=0.2$ for the 2HDM I models. In these and all other cases considered in this paper, $m_H$ = $m_A$. The ranges of $m_{H}$ and $\tan\beta$ are chosen to guarantee the validity of the models. The excluded regions are below the curves shown. The value $\tan\beta$ = 0.5 is excluded for $m_{H}$ > 800 GeV for all models considered.

The 95$\%$ CL contour of $-2\Delta\log(L)$ for the combination of all channels in the ($m_{H}$, $\tan\beta$) plane for a fixed value of $|\cos(\beta-\alpha)|=0.2$ for the 2HDM II models. In these and all other cases considered in this paper, $m_H$ = $m_A$. The ranges of $m_{H}$ and $\tan\beta$ are chosen to guarantee the validity of the models. The excluded regions are below the curves shown. The value $\tan\beta$ = 0.5 is excluded for $m_{H}$ > 800 GeV for all models considered.

The 95$\%$ CL contour of $-2\Delta\log(L)$ for the combination of all channels in the ($m_{H}$, $\tan\beta$) plane for a fixed value of $|\cos(\beta-\alpha)|=0.2$ for the 2HDM X models. In these and all other cases considered in this paper, $m_H$ = $m_A$. The ranges of $m_{H}$ and $\tan\beta$ are chosen to guarantee the validity of the models. The excluded regions are below the curves shown. The value $\tan\beta$ = 0.5 is excluded for $m_{H}$ > 800 GeV for all models considered.

The 95$\%$ CL contour of $-2\Delta\log(L)$ for the combination of all channels in the ($m_{H}$, $\tan\beta$) plane for a fixed value of $|\cos(\beta-\alpha)|=0.2$ for the 2HDM Y models. In these and all other cases considered in this paper, $m_H$ = $m_A$. The ranges of $m_{H}$ and $\tan\beta$ are chosen to guarantee the validity of the models. The excluded regions are below the curves shown. The value $\tan\beta$ = 0.5 is excluded for $m_{H}$ > 800 GeV for all models considered.

The 95$\%$ CL expected contour of $-2\Delta\log(L)$ for the combination of all channels in the ($|\cos(\beta-\alpha)|$, $\tan\beta$) plane for a fixed value of $m_{H}=1000GeV$ in the 2HDM-I model. In these and all other cases considered in this paper, $m_H$ = $m_A$. The ranges of $|\cos(\beta-\alpha)|$ and $\tan\beta$ are chosen to guarantee the validity of the models. The excluded regions are below the curves shown. The value $\tan\beta$ = 0.5 is excluded for $|\cos(\beta-\alpha)|$ > 0.16 and $|\cos(\beta-\alpha)|$ < -0.13 for all models considered.

The 95$\%$ CL observed contour of $-2\Delta\log(L)$ for the combination of all channels in the ($|\cos(\beta-\alpha)|$, $\tan\beta$) plane for a fixed value of $m_{H}=1000GeV$ in the 2HDM-I model. In these and all other cases considered in this paper, $m_H$ = $m_A$. The ranges of $|\cos(\beta-\alpha)|$ and $\tan\beta$ are chosen to guarantee the validity of the models. The excluded regions are below the curves shown. The value $\tan\beta$ = 0.5 is excluded for $|\cos(\beta-\alpha)|$ > 0.16 and $|\cos(\beta-\alpha)|$ < -0.13 for all models considered.

The 95% CL contour of $-2\Delta\log(L)$ for the combination of all channels in the ($|\cos(\beta-\alpha)|$, $\tan\beta$) plane for a fixed value of $m_{H}=1000GeV$ for the 2HDM I models. In these and all other cases considered in this paper, $m_H$ = $m_A$. The ranges of $|\cos(\beta-\alpha)|$ and $\tan\beta$ are chosen to guarantee the validity of the models. The excluded regions are below the curves shown. The value $\tan\beta$ = 0.5 is excluded for $|\cos(\beta-\alpha)|$ > 0.16 and $|\cos(\beta-\alpha)|$ < -0.13 for all models considered.

The 95% CL contour of $-2\Delta\log(L)$ for the combination of all channels in the ($|\cos(\beta-\alpha)|$, $\tan\beta$) plane for a fixed value of $m_{H}=1000GeV$ for the 2HDM II models. In these and all other cases considered in this paper, $m_H$ = $m_A$. The ranges of $|\cos(\beta-\alpha)|$ and $\tan\beta$ are chosen to guarantee the validity of the models. The excluded regions are below the curves shown. The value $\tan\beta$ = 0.5 is excluded for $|\cos(\beta-\alpha)|$ > 0.16 and $|\cos(\beta-\alpha)|$ < -0.13 for all models considered.

The 95% CL contour of $-2\Delta\log(L)$ for the combination of all channels in the ($|\cos(\beta-\alpha)|$, $\tan\beta$) plane for a fixed value of $m_{H}=1000GeV$ for the 2HDM X models. In these and all other cases considered in this paper, $m_H$ = $m_A$. The ranges of $|\cos(\beta-\alpha)|$ and $\tan\beta$ are chosen to guarantee the validity of the models. The excluded regions are below the curves shown. The value $\tan\beta$ = 0.5 is excluded for $|\cos(\beta-\alpha)|$ > 0.16 and $|\cos(\beta-\alpha)|$ < -0.13 for all models considered.

The 95% CL contour of $-2\Delta\log(L)$ for the combination of all channels in the ($|\cos(\beta-\alpha)|$, $\tan\beta$) plane for a fixed value of $m_{H}=1000GeV$ for the 2HDM Y models. In these and all other cases considered in this paper, $m_H$ = $m_A$. The ranges of $|\cos(\beta-\alpha)|$ and $\tan\beta$ are chosen to guarantee the validity of the models. The excluded regions are below the curves shown. The value $\tan\beta$ = 0.5 is excluded for $|\cos(\beta-\alpha)|$ > 0.16 and $|\cos(\beta-\alpha)|$ < -0.13 for all models considered.

The $-2\Delta\log(L)$ scan for the combination of all channels as a function of $\xi$ for MCHM$_4$. The range of $\xi$ is chosen to guarantee the validity of the model. At 95% CL, $\xi$ is constrained to be between 0 and 0.45 in MCHM$_4$.

The $-2\Delta\log(L)$ scan for the combination of all channels as a function of $\xi$ for MCHM$_5$. The range of $\xi$ is chosen to guarantee the validity of the model. At 95% CL, $\xi$ is constrained to be between 0 and 0.26 in MCHM$_5$.

Treatment of most important common systematic uncertainties in the S2 scenario.

The expected upper limits at 95% CL on the HH signal strength from the combination of all the considered channels at different integrated luminosities for the S2 scenario.

The expected upper limits at 95% CL on the HH signal strength from the combination of all the considered channels under different assumptions on the systematic uncertainties for an integrated luminosity of 3000fb$^{-1}$ (right).

The expected $-2\Delta\log(L)$ scan as a function of coupling modifier $\kappa_\lambda$ for the combination of all contributing channels, projected to different integrated luminosities. All other parameters are fixed to their SM values.

The expected $-2\Delta\log(L)$ scan as a function of coupling modifier $\kappa_\lambda$ for the combination of all contributing channels, projected under different assumptions on the systematic uncertainties for an integrated luminosity of 3000fb$^{-1}$. All other parameters are fixed to their SM values.

Expected significance for the HH signal projected to 2000 or 3000 fb$^{-1}$ under different assumptions of systematic uncertainties.

The expected signal significance as a function of integrated luminosity for the nominal scenario of systematic uncertainties S2 and for the scenario with statistical uncertainties only.

The expected signal significance as a function of $\kappa_\lambda$ under different assumptions on the systematic uncertainties for an integrated luminosity of 3000fb$^{-1}$.

The 95$\%$ CL upper limits on the inclusive HH signal strenngth as a function of $\kappa_{\lambda}$ coupling modifier. All other couplings are set to the values predicted by the SM. The theoretical uncertainties in the HH VBF signal cross sections are not considered because here we directly constrain the measured cross section.The inner (green) band and the outer (yellow) band indicate the 68 and 95$\%$ CL intervals, respectively, under the background-only hypothesis.

The 95$\%$ CL upper limits on the inclusive HH signal strenngth as a function of $\kappa_{2V}$ coupling modifier. All other couplings are set to the values predicted by the SM. The theoretical uncertainties in the HH VBF signal cross sections are not considered because here we directly constrain the measured cross section.The inner (green) band and the outer (yellow) band indicate the 68 and 95$\%$ CL intervals, respectively, under the background-only hypothesis.

The $-2\Delta\log(L)$ scan as a function of $\kappa_\lambda$ for all channels, when all the other parameters are fixed to their SM value.

The $-2\Delta\log(L)$ scan as a function of $\kappa_{2V}$ for all channels, when all the other parameters are fixed to their SM value.

The $-2\Delta\log(L)$ scan as a function of $\kappa_\lambda$ for all channels, when all the other parameters are fixed to their SM value.

The 95$\%$ CL upper limits on the inclusive HH cross section as a function of $\kappa_\lambda$ coupling modifier for all channels. All other couplings are set to the values predicted by the SM. The theoretical uncertainties in the HH GGF and VBF signal cross sections are not considered because here we directly constrain the measured cross section.

The 95$\%$ CL upper limits on the inclusive VBF HH cross section as a function of $\kappa_{2V}$ coupling modifier for all channels. All other couplings are set to the values predicted by the SM. The theoretical uncertainties in the HH GGF and VBF signal cross sections are not considered because here we directly constrain the measured cross section.

The 95$\%$ CL upper limits on the inclusive HH signal strength as a function of $\kappa_\lambda$ coupling modifier for all channels. All other couplings are set to the values predicted by the SM. The theoretical uncertainties in the HH GGF and VBF signal cross sections are not considered because here we directly constrain the measured cross section.

The 95$\%$ CL upper limits on the inclusive VBF HH signal strength as a function of $\kappa_{2V}$ coupling modifier for all channels. All other couplings are set to the values predicted by the SM. The theoretical uncertainties in the HH GGF and VBF signal cross sections are not considered because here we directly constrain the measured cross section.

The best fit value for $\kappa_\lambda$ compared to the SM expectation for all channels and their combination, when all the other parameters are fixed to their SM values.

The best fit value for $\kappa_2V$ compared to the SM expectation for all channels and their combination, when all the other parameters are fixed to their SM values.

The 68$\%$ CL expected contours of $-2\Delta\log(L)$ in the ($\kappa_{V}$, $\kappa_{2V}$) plane for the combination of all channels when all the other parameters are fixed to their SM values.

The 68$\%$ CL observed contours of $-2\Delta\log(L)$ in the ($\kappa_{V}$, $\kappa_{2V}$) plane for the combination of all channels when all the other parameters are fixed to their SM values.

The 95$\%$ CL expected contours of $-2\Delta\log(L)$ in the ($\kappa_{V}$, $\kappa_{2V}$) plane for the combination of all channels when all the other parameters are fixed to their SM values.

The 95$\%$ CL observed contours of $-2\Delta\log(L)$ in the ($\kappa_{V}$, $\kappa_{2V}$) plane for the combination of all channels when all the other parameters are fixed to their SM values.

The 5 $\sigma$ expected contours of $-2\Delta\log(L)$ in the ($\kappa_{V}$, $\kappa_{2V}$) plane for the combination of all channels when all the other parameters are fixed to their SM values.

The 5 $\sigma$ observed contours of $-2\Delta\log(L)$ in the ($\kappa_{V}$, $\kappa_{2V}$) plane for the combination of all channels when all the other parameters are fixed to their SM values.

The best-fit values of ($\kappa_{V}$, $\kappa_{2V}$) for the combination of all channels when all the other parameters are fixed to their SM values.

The 95$\%$ CL upper limits on the inclusive VBF HH signal strength as a function of $\kappa_{2V}$ coupling modifier for all channels. All other couplings are set to the values predicted by the SM. The theoretical uncertainties in the HH GGF and VBF signal cross sections are not considered because here we directly constrain the measured cross section. The inner (green) band and the outer (yellow) band indicate the 68 and 95% CL intervals, respectively, under the background-only hypothesis.

The $-2\Delta\log(L)$ scan as a function of the $c_2$ coupling modifier for all channels, when all the other parameters are fixed to their SM values.

The 95% CL upper limits on the inclusive HH cross section as a function of the $c_2$ coupling modifier for all channels. All other couplings are set to the values predicted by the SM. The theoretical uncertainties in the HH ggF signal cross sections are not considered because we directly constrain the measured cross section.

The 95% CL upper limits on the inclusive HH signal strength as a function of the $c_2$ coupling modifier for all channels. All other couplings are set to the values predicted by the SM. The theoretical uncertainties in the HH ggF signal cross sections are considered in this case

The best fit value for the $c_2$ coupling modifier compared to the SM expectation for all channels and their combination, when all the other parameters are fixed to their SM values.

The observed 68 $\%$ CL observed contours ($\kappa_\lambda$ =1.0) of $-2\Delta\log(L)$ in the ($c_2$, $\kappa_t$) plane for the combination of all channels when $\kappa_t$ is allowed to vary. The range of $\kappa_t$ is set between 0.5 and 1.5 to avoid unphysical areas of the phase space. All the other parameters are fixed to their SM values.

The observed 68 $\%$ CL observed contours (floating $\kappa_\lambda$) of $-2\Delta\log(L)$ in the ($c_2$, $\kappa_t$) plane for the combination of all channels when $\kappa_t$ is allowed to vary. The range of $\kappa_t$ is set between 0.5 and 1.5 to avoid unphysical areas of the phase space. All the other parameters are fixed to their SM values.

The observed 95 $\%$ CL observed contours ($\kappa_\lambda$ =1.0) of $-2\Delta\log(L)$ in the ($c_2$, $\kappa_t$) plane for the combination of all channels when $\kappa_t$ is allowed to vary. The range of $\kappa_t$ is set between 0.5 and 1.5 to avoid unphysical areas of the phase space. All the other parameters are fixed to their SM values.

The observed 95 $\%$ CL observed contours (floating $\kappa_\lambda$) of $-2\Delta\log(L)$ in the ($c_2$, $\kappa_t$) plane for the combination of all channels when $\kappa_t$ is allowed to vary. The range of $\kappa_t$ is set between 0.5 and 1.5 to avoid unphysical areas of the phase space. All the other parameters are fixed to their SM values.

The best fit values ($\kappa_\lambda$ =1.0) of ($c_2$, $\kappa_t$) for the combination of all channels when $\kappa_t$ is allowed to vary. The range of $\kappa_t$ is set between 0.5 and 1.5 to avoid unphysical areas of the phase space. All the other parameters are fixed to their SM values.

The best fit values (floating $\kappa_\lambda$) of ($c_2$, $\kappa_t$) for the combination of all channels when $\kappa_t$ is allowed to vary. The range of $\kappa_t$ is set between 0.5 and 1.5 to avoid unphysical areas of the phase space. All the other parameters are fixed to their SM values.

The observed 68$\%$ CL cobsevred contours ($\kappa_{t}$ =1.0 (SM)) of $-2\Delta\log(L)$ in the ($c_2$, $\kappa_\lambda$) plane for the combination of all channels when $\kappa_\lambda$ is allowed to vary. The range of $\kappa_\lambda$ is set between -15 and 15 to avoid unphysical areas of the phase space. All the other parameters are fixed to their SM values.

The observed 68$\%$ CL cobsevred contours (floating $\kappa_{t}$) of $-2\Delta\log(L)$ in the ($c_2$, $\kappa_\lambda$) plane for the combination of all channels when $\kappa_\lambda$ is allowed to vary. The range of $\kappa_\lambda$ is set between -15 and 15 to avoid unphysical areas of the phase space. All the other parameters are fixed to their SM values.

The observed 95$\%$ CL cobsevred contours ($\kappa_{t}$ =1.0 (SM)) of $-2\Delta\log(L)$ in the ($c_2$, $\kappa_\lambda$) plane for the combination of all channels when $\kappa_\lambda$ is allowed to vary. The range of $\kappa_\lambda$ is set between -15 and 15 to avoid unphysical areas of the phase space. All the other parameters are fixed to their SM values.

The observed 95$\%$ CL cobsevred contours (floating $\kappa_{t}$) of $-2\Delta\log(L)$ in the ($c_2$, $\kappa_\lambda$) plane for the combination of all channels when $\kappa_\lambda$ is allowed to vary. The range of $\kappa_\lambda$ is set between -15 and 15 to avoid unphysical areas of the phase space. All the other parameters are fixed to their SM values.

The best fit values ($\kappa_{t}$ =1.0 (SM)) of ($c_2$, $\kappa_\lambda$) for the combination of all channels when $\kappa_\lambda$ is allowed to vary. The range of $\kappa_\lambda$ is set between -15 and 15 to avoid unphysical areas of the phase space. All the other parameters are fixed to their SM values.

The best fit values (floating $\kappa_{t}$) for ($c_2$, $\kappa_\lambda$) for the combination of all channels when $\kappa_\lambda$ is allowed to vary. The range of $\kappa_\lambda$ is set between -15 and 15 to avoid unphysical areas of the phase space. All the other parameters are fixed to their SM values.

The observed 68% CL contours of $-2\Delta\log(L)$ in the ($c_2$, $\kappa_\lambda$) plane for the combination of all channels when all the other parameters are fixed to their SM value. The best fit value and 68% CL contour for the $b\bar{b}\tau\tau$ channel are not within the range of the figure.

The observed best fit values in the ($c_2$, $\kappa_\lambda$) plane for the combination of all channels when all the other parameters are fixed to their SM value. The best fit value and 68% CL contour for the $b\bar{b}\tau\tau$ channel are not within the range of the figure.

The observed 68% CL contours of $-2\Delta\log(L)$ in the ($c_2$, $\kappa_\lambda$) plane for the $b\bar{b}b\bar{b}$ resolved channel when all the other parameters are fixed to their SM value. The best fit value and 68% CL contour for the $b\bar{b}\tau\tau$ channel are not within the range of the figure.

The observed best fit values in the ($c_2$, $\kappa_\lambda$) plane for the $b\bar{b}b\bar{b}$ resolved channel when all the other parameters are fixed to their SM value. The best fit value and 68% CL contour for the $b\bar{b}\tau\tau$ channel are not within the range of the figure.

The observed 68% CL contours of $-2\Delta\log(L)$ in the ($c_2$, $\kappa_\lambda$) plane for the $b\bar{b}b\bar{b}$ merged channel when all the other parameters are fixed to their SM value. The best fit value and 68% CL contour for the $b\bar{b}\tau\tau$ channel are not within the range of the figure.

The observed best fit values in the ($c_2$, $\kappa_\lambda$) plane for the $b\bar{b}b\bar{b}$ merged channel when all the other parameters are fixed to their SM value. The best fit value and 68% CL contour for the $b\bar{b}\tau\tau$ channel are not within the range of the figure.

The observed 68% CL contours of $-2\Delta\log(L)$ in the ($c_2$, $\kappa_\lambda$) plane for the $b\bar{b}\gamma\gamma$ channel when all the other parameters are fixed to their SM value. The best fit value and 68% CL contour for the $b\bar{b}\tau\tau$ channel are not within the range of the figure.

The observed best fit values in the ($c_2$, $\kappa_\lambda$) plane for the $b\bar{b}\gamma\gamma$ channel when all the other parameters are fixed to their SM value. The best fit value and 68% CL contour for the $b\bar{b}\tau\tau$ channel are not within the range of the figure.

The observed 68% CL contours of $-2\Delta\log(L)$ in in the ($c_2$, $\kappa_\lambda$) plane for the $b\bar{b}W^{+}W^{-}$ channel when all the other parameters are fixed to their SM value. The best fit value and 68% CL contour for the $b\bar{b}\tau\tau$ channel are not within the range of the figure.

The best fit values in in the ($c_2$, $\kappa_\lambda$) plane for the $b\bar{b}W^{+}W^{-}$ channel when all the other parameters are fixed to their SM value. The best fit value and 68% CL contour for the $b\bar{b}\tau\tau$ channel are not within the range of the figure.

The observed 68% CL contours of $-2\Delta\log(L)$ in in the ($c_2$, $\kappa_\lambda$) plane for the multilepton channel when all the other parameters are fixed to their SM value. The best fit value and 68% CL contour for the $b\bar{b}\tau\tau$ channel are not within the range of the figure.

The best fit values in in the ($c_2$, $\kappa_\lambda$) plane for the multilepton channel when all the other parameters are fixed to their SM value. The best fit value and 68% CL contour for the $b\bar{b}\tau\tau$ channel are not within the range of the figure.

The observed 68% CL contours of $-2\Delta\log(L)$ in in the ($c_2$, $\kappa_\lambda$) plane for the $W^{+}W^{-}\gamma\gamma$ channel when all the other parameters are fixed to their SM value. The best fit value and 68% CL contour for the $b\bar{b}\tau\tau$ channel are not within the range of the figure.

The best fit values in in the ($c_2$, $\kappa_\lambda$) plane for the $W^{+}W^{-}\gamma\gamma$ channel when all the other parameters are fixed to their SM value. The best fit value and 68% CL contour for the $b\bar{b}\tau\tau$ channel are not within the range of the figure.

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

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

The 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.

Observed profile likelihood as a function of $\sigma\times\mathcal{B}_{H\rightarrow WW^{*}}$ normalised by the SM expectation for the single-channel measurements

Two-dimensional likelihood scan of the measured values of $\sigma_{ZH}\times\mathcal{B}_{H\rightarrow WW^{*}}$ vs. $\sigma_{WH}\times\mathcal{B}_{H\rightarrow WW^{*}}$.

The observed values of the background normalisation factors for the combined 2-POI fit. The uncertainties correspond to the total of all statistical and systematic sources.

Measured cross sections times the $H\rightarrow WW^{*}$ branching ratio for the $p_T^V$ scheme.

Measured cross sections times the $H\rightarrow WW^{*}$ branching ratio for the STXS scheme. Note: the uncertainties of "-0" are due to the confidence interval reaching the minimum allowed value of the POI.

Correlation matrix of the POIs and normalisation factors for the 2-POI inclusive analysis

Correlation matrix of the parameters of interest, normalisation factors and nuissance parameters for the $p_T^V$ scheme

Correlation matrix of the parameters of interest, normalisation factors and nuissance parameters for the STXS scheme

Event data from Z-dominated SR

The nuclear suppression factor $S^{\mathrm{J}/\psi}$ of incoherent $\mathrm{J}/\psi$ meson photoproduction as a function of Bjorken $x$ in PbPb ultra-peripheral collisions at $\sqrt{s_{\mathrm{NN}}}$ = 5.02 TeV. The $x$ values are evaluated at the centers of their corresponding rapidity ranges. The theoretical uncertainties are due to the uncertainties in the photon flux.

The ratio between incoherent and coherent $\mathrm{J}/\psi$ meson photoproduction cross section as a function of photon-nuclear center-of-mass energy per nucleon $W_{\gamma \mathrm{N}}^{\mathrm{Pb}}$, measured in PbPb ultra-peripheral collisions at $\sqrt{s_{\mathrm{NN}}}$ = 5.02 TeV. The $W_{\gamma \mathrm{N}}^{\mathrm{Pb}}$ values used correspond to the center of each rapidity range. The theoretical uncertainties is due to the uncertainties in the photon flux.

The total covariance matrix of the total incoherent photoproduction cross section as a function of photon-nuclear center-of-mass energy per nucleon $W_{\gamma \mathrm{N}}^{\mathrm{Pb}}$. The covariance matrix includes both the experimental and theoretical (photon flux) uncertainties. The bins are ordered as increasing in $W_{\gamma \mathrm{N}}^{\mathrm{Pb}}$.

The experimental covariance matrix of the total incoherent photoproduction cross section as a function of photon-nuclear center-of-mass energy per nucleon $W_{\gamma \mathrm{N}}^{\mathrm{Pb}}$. The bins are ordered as increasing in $W_{\gamma \mathrm{N}}^{\mathrm{Pb}}$.

The theoretical (photon flux) covariance matrix of the total incoherent photoproduction cross section as a function of photon-nuclear center-of-mass energy per nucleon $W_{\gamma \mathrm{N}}^{\mathrm{Pb}}$. The bins are ordered as increasing in $W_{\gamma \mathrm{N}}^{\mathrm{Pb}}$.

Breakdown of relative systematic uncertainties in the measured ${t\bar{t}}$ cross-section. The quoted uncertainties are obtained by repeating the fit with a group of nuisance parameters fixed to their fitted values and subtracting in quadrature the resulting total uncertainty from the uncertainty of the complete fit. However, the total uncertainty is not the quadratic sum of the grouped impacts, as this approach neglects the correlation among the different groups.

The figure shows the measurement of the top quark pair production cross-section, $\sigma_{t\bar{t}}$, in lead-lead (Pb+Pb) collisions at a center-of-mass energy of $\sqrt{s_{\mathrm{NN}}} = 5.02$ TeV, based on 1.9 nb$^{-1}$ of data.

Distributions in $S_T$ in the SR for the electron channel, after a background-only fit to the data. The signal distributions are scaled to the cross section predicted by the theory. The hatched bands show the post-fit uncertainty band, combining all sources of uncertainty. The ratio of data to the background predictions is shown in the panels below the distributions.

Post-fit agreement between data and MC prediction for the $SR_{\mathrm{loose}}^{2\ell3j}$ signal region, which uses the invariant mass of the c-tagged jet and the geometrically closest b-tagged jet, $m_{\mathit{cb}}^{\mathrm{min}\Delta R}$, as an observable. The hatched uncertainty bands include all uncertainties and their correlations. The last bins contain overflow events. "Other Top" includes single-top-quark production and associated production of $t\bar{t}$ and single top quarks with bosons. "Non-Top" includes W+jets, Z+jets, and diboson processes.

Post-fit agreement between data and MC prediction for the $SR_{\mathrm{loose}}^{1\ell6ji}$ signal region, which uses the jet multiplicity, $N_{\mathrm{jets}}$, as an observable. The hatched uncertainty bands include all uncertainties and their correlations. The last bins contain overflow events. "Other Top" includes single-top-quark production and associated production of $t\bar{t}$ and single top quarks with bosons. "Non-Top" includes W+jets, Z+jets, and diboson processes.

Post-fit agreement between data and MC prediction for the $SR_{\mathrm{tight}}^{1\ell6ji}$ signal region, which uses the jet multiplicity, $N_{\mathrm{jets}}$, as an observable. The hatched uncertainty bands include all uncertainties and their correlations. The last bins contain overflow events. "Other Top" includes single-top-quark production and associated production of $t\bar{t}$ and single top quarks with bosons. "Non-Top" includes W+jets, Z+jets, and diboson processes.

Post-fit agreement between data and MC prediction for the $SR_{\mathrm{loose}}^{2\ell4ji}$ signal region, which uses the jet multiplicity, $N_{\mathrm{jets}}$, as an observable. The hatched uncertainty bands include all uncertainties and their correlations. The last bins contain overflow events. "Other Top" includes single-top-quark production and associated production of $t\bar{t}$ and single top quarks with bosons. "Non-Top" includes W+jets, Z+jets, and diboson processes.

Post-fit agreement between data and MC prediction for the $SR_{\mathrm{tight}}^{2\ell4ji}$ signal region, which uses the jet multiplicity, $N_{\mathrm{jets}}$, as an observable. The hatched uncertainty bands include all uncertainties and their correlations. The last bins contain overflow events. "Other Top" includes single-top-quark production and associated production of $t\bar{t}$ and single top quarks with bosons. "Non-Top" includes W+jets, Z+jets, and diboson processes.

Jet multiplicity and tagging criteria for the SRs and CRs in the single-lepton and dilepton channels. All single-lepton regions are defined in the 5-jet-exclusive and 6-jet-inclusive jet selections, all dilepton regions in the 3-jet-exclusive and 4-jet-inclusive jet selections. By construction, $\mathrm{SR}^{2\ell}_{\mathrm{tight}}$ only exists for the 4-jet-inclusive selection. Identical requirements on inclusive and exclusive working points, e.g., one c@22% and one c@11% in the $\mathrm{CR}_1^{1\ell}$, indicate a veto of additional tags at the inclusive working point.

Breakdown of the fiducial $t\bar{t}+{\geq}2c$ and $t\bar{t}+1c$ cross-section uncertainties. Systematic uncertainties are grouped into signal and background modeling, instrumental, and MC statistics categories. The table lists the fractional uncertainty in the measured cross-sections in percent and is estimated from the covariance matrix of the profile likelihood fit, following EPJC 84 (2024) 593. Individual groups of uncertainties can be added in quadrature to obtain the total uncertainty. JES and JER denote the jet energy scale and resolution uncertainties, respectively. The fractional uncertainties in the fitted $t\bar{t}+{\geq}1c$ and $t\bar{t}+\text{light}$ normalization factors are included in the data statistics category. For presentation purposes, all uncertainties are symmetrized.

Measured fiducial cross-section values in comparison with various NLO+PS predictions. The uncertainties in the predictions include independent and simultaneous variations of the $\mu_R$ and $\mu_F$ scales and uncertainties in the choice of the PDF set, but no uncertainties in the parton shower or hadronization. The uncertainties in the measured values include all statistical and systematic uncertainties. For presentation purposes, the quoted measurement and prediction uncertainties are symmetrized.

Measured and predicted values for the $t\bar{t}+{\geq}1b$, $t\bar{t}+{\geq}2c$, and $t\bar{t}+1c$ cross-sections and for the cross-section ratios of these processes to total $t\bar{t}+\text{jets}$ production. The quoted uncertainties in the measurements include statistical and systematic uncertainties. The predictions are taken from the nominal setup using inclusive $t\bar{t}$ Powheg+Pythia8 predictions for the $t\bar{t}+{\geq}2c$, $t\bar{t}+1c$, and $t\bar{t}+\text{light}$ processes, and $t\bar{t}+b\bar{b}$ Powheg+Pythia8 predictions for the $t\bar{t}+{\geq}1b$ process. The first use the 5FS, the latter the 4FS, where the $b$-quarks are treated as massive particles and are included in the matrix element calculation. The uncertainties in the predictions include independent and simultaneous variations of the $\mu_R$ and $\mu_F$ scales and uncertainties in the choice of the PDF set.

Nuisance parameters with a large impact on the fiducial measurement: ranking of the ten most impactful nuisance parameters for the $t\bar{t}+{\geq}2c$ cross-section measurement. The colored boxes indicate the impact of the nuisance parameters, $\Delta\mu$ (top axis), on the corresponding parameter of interest, $\mu$. They are calculated from the covariance matrix using the post-fit up (down) uncertainties of the parameter of interest and the nuisance parameter, $\sigma_{\mathrm{POI}}^{\mathrm{up}}$ and $\sigma_{\mathrm{NP}}^{\mathrm{up}}$ ($\sigma_{\mathrm{POI}}^{\mathrm{down}}$ and $\sigma_{\mathrm{NP}}^{\mathrm{down}}$), and their linear correlation coefficient, $\rho$, following EPJC 84 (2024) 593. The data points and error bars indicate the post-fit values and uncertainties of the nuisance parameters relative to their pre-fit values, $\theta_0$, in units of their pre-fit uncertainties, $\Delta \theta$ (bottom axis). A hollow circle indicates that the nuisance parameter has a Poisson constraint.

Nuisance parameters with a large impact on the fiducial measurement: ranking of the ten most impactful nuisance parameters for the $t\bar{t}+1c$ cross-section measurement. The colored boxes indicate the impact of the nuisance parameters, $\Delta\mu$ (top axis), on the corresponding parameter of interest, $\mu$. They are calculated from the covariance matrix using the post-fit up (down) uncertainties of the parameter of interest and the nuisance parameter, $\sigma_{\mathrm{POI}}^{\mathrm{up}}$ and $\sigma_{\mathrm{NP}}^{\mathrm{up}}$ ($\sigma_{\mathrm{POI}}^{\mathrm{down}}$ and $\sigma_{\mathrm{NP}}^{\mathrm{down}}$), and their linear correlation coefficient, $\rho$, following EPJC 84 (2024) 593. The data points and error bars indicate the post-fit values and uncertainties of the nuisance parameters relative to their pre-fit values, $\theta_0$, in units of their pre-fit uncertainties, $\Delta \theta$ (bottom axis). A hollow circle indicates that the nuisance parameter has a Poisson constraint.

Nuisance parameters with a large impact on the fiducial measurement: ranking of the ten most impactful nuisance parameters for the $t\bar{t}+{\geq}2c$ ratio to total $t\bar{t}+\text{jets}$ production. The colored boxes indicate the impact of the nuisance parameters, $\Delta\mu$ (top axis), on the corresponding parameter of interest, $\mu$. They are calculated from the covariance matrix using the post-fit up (down) uncertainties of the parameter of interest and the nuisance parameter, $\sigma_{\mathrm{POI}}^{\mathrm{up}}$ and $\sigma_{\mathrm{NP}}^{\mathrm{up}}$ ($\sigma_{\mathrm{POI}}^{\mathrm{down}}$ and $\sigma_{\mathrm{NP}}^{\mathrm{down}}$), and their linear correlation coefficient, $\rho$, following EPJC 84 (2024) 593. The data points and error bars indicate the post-fit values and uncertainties of the nuisance parameters relative to their pre-fit values, $\theta_0$, in units of their pre-fit uncertainties, $\Delta \theta$ (bottom axis). A hollow circle indicates that the nuisance parameter has a Poisson constraint.

Nuisance parameters with a large impact on the fiducial measurement: ranking of the ten most impactful nuisance parameters for the $t\bar{t}+1c$ ratio to total $t\bar{t}+\text{jets}$ production. The colored boxes indicate the impact of the nuisance parameters, $\Delta\mu$ (top axis), on the corresponding parameter of interest, $\mu$. They are calculated from the covariance matrix using the post-fit up (down) uncertainties of the parameter of interest and the nuisance parameter, $\sigma_{\mathrm{POI}}^{\mathrm{up}}$ and $\sigma_{\mathrm{NP}}^{\mathrm{up}}$ ($\sigma_{\mathrm{POI}}^{\mathrm{down}}$ and $\sigma_{\mathrm{NP}}^{\mathrm{down}}$), and their linear correlation coefficient, $\rho$, following EPJC 84 (2024) 593. The data points and error bars indicate the post-fit values and uncertainties of the nuisance parameters relative to their pre-fit values, $\theta_0$, in units of their pre-fit uncertainties, $\Delta \theta$ (bottom axis). A hollow circle indicates that the nuisance parameter has a Poisson constraint.

Efficiencies and rejection rates for the $b$- and $c$-jet tagging working points of the $b/c$-tagger, as well as the selection cuts on the discriminants, $\mathcal{D}_b'$ and $\mathcal{D}_c'$ that define the tagging bins. The primes indicate that a standard logistic function is applied to the discriminants. The b@70% and c@22% working points are inclusive of their respective tighter working points. The values were estimated from single-lepton and dilepton $t\bar{t}$ events simulated with Powheg + Pythia 8.

Efficiencies and rejection rates for the $b$- and $c$-jet tagging working points of the $b/c$-tagger, as well as the selection cuts on the discriminants, $\mathcal{D}_b'$ and $\mathcal{D}_c'$ that define the tagging bins. The primes indicate that a standard logistic function is applied to the discriminants. The b@70% and c@22% working points are inclusive of their respective tighter working points. The values were estimated from single-lepton and dilepton $t\bar{t}$ events simulated with Powheg + Pythia 8.

Pre-fit event yields in the twelve single-lepton and dilepton control regions (CRs) of the analysis. The quoted uncertainties include both statistical and systematic components, but all normalization factors are fixed to their pre-fit values with no uncertainties. All uncertainties are assumed to be uncorrelated. "Other Top" includes single-top-quark production and associated production of $t\bar{t}$ and single top quarks with bosons. "Non-Top" includes W+jets, Z+jets, and diboson processes. The "Fakes" category includes events from misidentified leptons and non-prompt leptons, estimated through the data-driven matrix method in the single-lepton channel and through MC predictions in the dilepton channel.

Pre-fit event yields in the seven signal regions (SRs) of the analysis. The quoted uncertainties include both statistical and systematic components, but all normalization factors are fixed to their pre-fit values with no uncertainties. All uncertainties are assumed to be uncorrelated. "Other Top" includes single-top-quark production and associated production of $t\bar{t}$ and single top quarks with bosons. "Non-Top" includes W+jets, Z+jets, and diboson processes. The "Fakes" category includes events from misidentified leptons and non-prompt leptons, estimated through the data-driven matrix method in the single-lepton channel and through MC predictions in the dilepton channel.

Post-fit event yields in the twelve single-lepton and dilepton control regions (CRs) of the analysis. The quoted uncertainties include both statistical and systematic components, and post-fit correlations between uncertainties are taken into account. "Other Top" includes single-top-quark production and associated production of $t\bar{t}$ and single top quarks with bosons. "Non-Top" includes W+jets, Z+jets, and diboson processes. The "Fakes" category includes events from misidentified leptons and non-prompt leptons, estimated through the data-driven matrix method in the single-lepton channel and through MC predictions in the dilepton channel.

Post-fit event yields in the seven signal regions (SRs) of the analysis. The quoted uncertainties include both statistical and systematic components, and post-fit correlations between uncertainties are taken into account. "Other Top" includes single-top-quark production and associated production of $t\bar{t}$ and single top quarks with bosons. "Non-Top" includes W+jets, Z+jets, and diboson processes. The "Fakes" category includes events from misidentified leptons and non-prompt leptons, estimated through the data-driven matrix method in the single-lepton channel and through MC predictions in the dilepton channel.

Correlations of the ttH signal-strength modifiers in the different Higgs pT bins of the STXS measurement.

Observed and expected upper 95% CL limit on the tH signal strength modifier $\mu_{tH}$ with $\mu_{ttH}=1$ for different channels and years, where the uncertainties are uncorrelated between the channels and years, and in their combination. The one and two standard deviation confidence intervals on the expected limit are also listed (sigma).

Likelihood-ratio test statistic as a function of the ttH and tH signal strength modifiers $\mu_{ttH}$ and $\mu_{tH}$. The observed best fit point is $(\mu_{tH}, \mu_{ttH}) = (-3.83, +0.35)$.

Observed and expected likelihood ratio test statistic as a function of $\kappa_{t}$ and $\kappa_{V}$. The observed best fit point is $(\kappa_{t}, \kappa_{V}) = (+0.59, +1.40)$.

Observed and expected likelihood ratio test statistic as a function of $\kappa_{t}$ for $\kappa_{V}=1$. The observed best fit point is $\kappa_{t} = +0.54$.

Observed and expected likelihood ratio test statistic as a function of $\kappa_{t}$ and $\tilde{\kappa}_{t}$ with $\kappa_{V}=1$. The observed best fit point is $(\kappa_{t}, \tilde{\kappa}_{t}) = (+0.53, 0.00)$.

Observed and expected likelihood ratio test statistic as a function of $f_{CP}$. The overall modifier of the top-Higgs coupling strength is profiled such that the likelihood attains its minimum at each point in the plane, and $\kappa_{V}$ is set to 1. The observed best fit point is $f_{CP} = 0.00$.

Observed and expected likelihood ratio test statistic as a function of $\cos(\alpha)$. The overall modifier of the top-Higgs coupling strength is profiled such that the likelihood attains its minimum at each point in the plane, and $\kappa_{V}$ is set to 1. The observed best fit point is $\cos(\alpha) = +1.00$.

Observed and expected likelihood ratio test statistic as a function of $\kappa_{t}$ and $\tilde{\kappa}_{t}$ with $\kappa_{V}=1$, in the $H \rightarrow bb$, $H\rightarrow\gamma\gamma$, $H\rightarrow ZZ$, $H\rightarrow WW$, and $H\rightarrow\tau\tau$ decay channels and in their combination.

Observed and expected likelihood ratio test statistic as a function of $f_{CP}$, in the $H \rightarrow bb$, $H\rightarrow\gamma\gamma$, $H\rightarrow ZZ$, $H\rightarrow WW$, and $H\rightarrow\tau\tau$ decay channel and in their combination. The overall modifier of the top-Higgs coupling strength is profiled such that the likelihood attains its minimum at each point in the plane, and $\kappa_{V}$ is set to 1.

Observed and expected likelihood ratio test statistic as a function of $\cos(\alpha)$, in the $H \rightarrow bb$, $H\rightarrow\gamma\gamma$, $H\rightarrow ZZ$, $H\rightarrow WW$, and $H\rightarrow\tau\tau$ decay channels and in their combination. The overall modifier of the top-Higgs coupling strength is profiled such that the likelihood attains its minimum at each point in the plane, and $\kappa_{V}$ is set to 1.

The figure shows the post-fit distribution of events as a function of $H_{\mathrm{T}}^{\ell,j} = \sum_{\ell,j} p_{T}^{\ell,j}$, scalar sum of $p_T$ for all jets and leptons in the $\ell+$jets channel, in proton-lead (p+Pb) collisions at a center-of-mass energy of $\sqrt{s_{\mathrm{NN}}} = 8.16$ TeV, with an integrated luminosity of 165 nb$^{-1}$. The data correspond to the $1\ell 1b$ $\mu$+jets channel in a pre-fit configuration. The stacked histograms represent different processes contributing to the event yield, including top quark pair production ($t\bar{t}$), single top, $W$ boson production with $b$, $c$, and light quarks, $Z$ boson production with $b$, $c$, and light quarks, diboson, and fake lepton backgrounds.

The figure shows the pre-fit distribution of events as a function of $H_{\mathrm{T}}^{\ell,j} = \sum_{\ell,j} p_{T}^{\ell,j}$, scalar sum of $p_T$ for all jets and leptons in the $\ell+$jets channel, in proton-lead (p+Pb) collisions at a center-of-mass energy of $\sqrt{s_{\mathrm{NN}}} = 8.16$ TeV, with an integrated luminosity of 165 nb$^{-1}$. The data correspond to the $1\ell 2bincl$ $e$+jets channel in a pre-fit configuration. The stacked histograms represent different processes contributing to the event yield, including top quark pair production ($t\bar{t}$), single top, $W$ boson production with $b$, $c$, and light quarks, $Z$ boson production with $b$, $c$, and light quarks, diboson, and fake lepton backgrounds.

The figure shows the post-fit distribution of events as a function of $H_{\mathrm{T}}^{\ell,j} = \sum_{\ell,j} p_{T}^{\ell,j}$, scalar sum of $p_T$ for all jets and leptons in the $\ell+$jets channel, in proton-lead (p+Pb) collisions at a center-of-mass energy of $\sqrt{s_{\mathrm{NN}}} = 8.16$ TeV, with an integrated luminosity of 165 nb$^{-1}$. The data correspond to the $1\ell 2bincl$ $e$+jets channel in a pre-fit configuration. The stacked histograms represent different processes contributing to the event yield, including top quark pair production ($t\bar{t}$), single top, $W$ boson production with $b$, $c$, and light quarks, $Z$ boson production with $b$, $c$, and light quarks, diboson, and fake lepton backgrounds.

The figure shows the pre-fit distribution of events as a function of $H_{\mathrm{T}}^{\ell,j} = \sum_{\ell,j} p_{T}^{\ell,j}$, scalar sum of $p_T$ for all jets and leptons in the $\ell+$jets channel, in proton-lead (p+Pb) collisions at a center-of-mass energy of $\sqrt{s_{\mathrm{NN}}} = 8.16$ TeV, with an integrated luminosity of 165 nb$^{-1}$. The data correspond to the $1\ell 2bincl$ $\mu$+jets channel in a pre-fit configuration. The stacked histograms represent different processes contributing to the event yield, including top quark pair production ($t\bar{t}$), single top, $W$ boson production with $b$, $c$, and light quarks, $Z$ boson production with $b$, $c$, and light quarks, diboson, and fake lepton backgrounds.

The figure shows the post-fit distribution of events as a function of $H_{\mathrm{T}}^{\ell,j} = \sum_{\ell,j} p_{T}^{\ell,j}$, scalar sum of $p_T$ for all jets and leptons in the $\ell+$jets channel, in proton-lead (p+Pb) collisions at a center-of-mass energy of $\sqrt{s_{\mathrm{NN}}} = 8.16$ TeV, with an integrated luminosity of 165 nb$^{-1}$. The data correspond to the $1\ell 2bincl$ $\mu$+jets channel in a pre-fit configuration. The stacked histograms represent different processes contributing to the event yield, including top quark pair production ($t\bar{t}$), single top, $W$ boson production with $b$, $c$, and light quarks, $Z$ boson production with $b$, $c$, and light quarks, diboson, and fake lepton backgrounds.

The figure shows the pre-fit distribution of events as a function of $H_{\mathrm{T}}^{\ell,j} = \sum_{\ell,j} p_{T}^{\ell,j}$, scalar sum of $p_T$ for all jets and leptons in the $\ell+$jets channel, in proton-lead (p+Pb) collisions at a center-of-mass energy of $\sqrt{s_{\mathrm{NN}}} = 8.16$ TeV, with an integrated luminosity of 165 nb\(^{-1}\) in the 2\(\ell\)1b signal region. The histogram represents the number of events per GeV, with the data points shown as black dots and their associated uncertainties. The stacked colored histograms indicate different processes: \(t\bar{t}\) (red), single top (orange), \(Z+b\) (dark blue), \(Z+c\) (medium blue), \(Z+\)light (light blue), diboson (gray), and fake lepton (purple). The hatched area represents the uncertainty in the predictions.

The figure shows the post-fit distribution of events as a function of $H_{\mathrm{T}}^{\ell,j} = \sum_{\ell,j} p_{T}^{\ell,j}$, scalar sum of $p_T$ for all jets and leptons in the $\ell+$jets channel, in proton-lead (p+Pb) collisions at a center-of-mass energy of $\sqrt{s_{\mathrm{NN}}} = 8.16$ TeV, with an integrated luminosity of 165 nb\(^{-1}\) in the 2\(\ell\)1b signal region. The histogram represents the number of events per GeV, with the data points shown as black dots and their associated uncertainties. The stacked colored histograms indicate different processes: \(t\bar{t}\) (red), single top (orange), \(Z+b\) (dark blue), \(Z+c\) (medium blue), \(Z+\)light (light blue), diboson (gray), and fake lepton (purple). The hatched area represents the uncertainty in the predictions.

The figure shows the pre-fit distribution of events as a function of $H_{\mathrm{T}}^{\ell,j} = \sum_{\ell,j} p_{T}^{\ell,j}$, scalar sum of $p_T$ for all jets and leptons in the $\ell+$jets channel, in proton-lead (p+Pb) collisions at a center-of-mass energy of $\sqrt{s_{\mathrm{NN}}} = 8.16$ TeV, with an integrated luminosity of 165 nb\(^{-1}\) in the 2\(\ell\)2bincl signal region. The histogram represents the number of events per GeV, with the data points shown as black dots and their associated uncertainties. The stacked colored histograms indicate different processes: \(t\bar{t}\) (red), single top (orange), \(Z+b\) (dark blue), \(Z+c\) (medium blue), \(Z+\)light (light blue), diboson (gray), and fake lepton (purple). The hatched area represents the uncertainty in the predictions.

The figure shows the post-fit distribution of events as a function of $H_{\mathrm{T}}^{\ell,j} = \sum_{\ell,j} p_{T}^{\ell,j}$, scalar sum of $p_T$ for all jets and leptons in the $\ell+$jets channel, in proton-lead (p+Pb) collisions at a center-of-mass energy of $\sqrt{s_{\mathrm{NN}}} = 8.16$ TeV, with an integrated luminosity of 165 nb\(^{-1}\) in the 2\(\ell\)2bincl signal region. The histogram represents the number of events per GeV, with the data points shown as black dots and their associated uncertainties. The stacked colored histograms indicate different processes: \(t\bar{t}\) (red), single top (orange), \(Z+b\) (dark blue), \(Z+c\) (medium blue), \(Z+\)light (light blue), diboson (gray), and fake lepton (purple). The hatched area represents the uncertainty in the predictions.

The correlation matrix of the fit parameters for the six combined regions, including the signal regions (electron+jets: 1-lepton 1-bjet and 1-lepton 2-bjet inclusive, muon+jets: 1-lepton 1-bjet and 1-lepton 2-bjet inclusive, dilepton: 2-lepton 1-bjet and 2-lepton 2-bjet inclusive) is shown.

The impact of systematic uncertainties on the fitted signal-strength parameter $\hat{\mu}$ for the combined (six signal regions ($e+$jets: $1\ell1b$ and $1\ell2b\mathrm{incl}$, $\mu+$jets: $1\ell1b$ and $1\ell2b\mathrm{incl}$, dilepton: $2\ell1b$ and $2\ell2b\mathrm{incl}$) fit of all channels. Only the 15 most significant systematic uncertainties are shown and listed in decreasing order of their impact on $\mu$ on the $y$-axis. The empty (filled) blue/cyan boxes correspond to the pre-fit (post-fit) impact on $\mu$, referring to the upper $x$-axis. The impact of each systematic uncertainty, $\Delta \mu$, is calculated by comparing the nominal best-fit value of $\mu$ with the result of the fit when fixing the corresponding nuisance parameter $\theta$ to its best-fit value $\hat{\theta}$ shifted by its pre-fit (post-fit) uncertainties $\hat{\theta} \pm \Delta \theta(\hat{\theta} \pm \Delta \hat{\theta})$. The black points, which refer to the lower $x$-axis, show the pulls of the fitted nuisance parameters, i.e., the deviations of the fitted parameters $\hat{\theta}$ from their nominal values $\theta_0$, normalized to their nominal uncertainties $\Delta \theta$. The black lines show the post-fit uncertainties of the nuisance parameters, relative to their nominal uncertainties, which are indicated by the dashed lines.

Breakdown of relative systematic uncertainties in the measured ${t\bar{t}}$ cross-section. The quoted uncertainties are obtained by repeating the fit with a group of nuisance parameters fixed to their fitted values and subtracting in quadrature the resulting total uncertainty from the uncertainty of the complete fit. However, the total uncertainty is not the quadratic sum of the grouped impacts, as this approach neglects the correlation among the different groups.

The signal strength $\mu_{t\bar{t}}$, defined as the ratio of the observed signal for the combined six signal regions ($e+$jets: $1\ell1b$ and $1\ell2b\mathrm{incl}$, $\mu+$jets: $1\ell1b$ and $1\ell2b\mathrm{incl}$, dilepton: $2\ell1b$ and $2\ell2b\mathrm{incl}$.) to the SM expectation with no nPDF effects included, is measured using a binned profile-likelihood method. The parameter $\mu_{t\bar{t}}$ is determined by the fit to the $H_{T}^{\ell,j}$ data distributions in the six signal regions, where the $H_{T}^{\ell,j}$ variable is defined as the scalar sum of the transverse momenta of the leptons and HI jets. Over all 9% uncertainties is observed

The figure shows the measurement of the top quark pair production cross-section, $\sigma_{t\bar{t}}$, in proton-lead (p+Pb) collisions at a center-of-mass energy of $\sqrt{s_{\mathrm{NN}}} = 8.16$ TeV, based on 165 nb$^{-1}$ of data. The central measured value is shown alongside theoretical predictions using various parton distribution functions (PDFs): MCFM TUJU21, MCFM nNNPDF30, MCFM nCTEQ15HQ, and MCFM EPPS21. The green and yellow bands represent the total and statistical uncertainties of the data, respectively. Additional measurements for comparison include the CMS result at 8.16 TeV for p+Pb collisions and an extrapolated ATLAS+CMS result for pp collisions at 8 TeV. Relevant references are indicated: PRL 119 (2017) 242001 and JHEP 07 (2023) 213.

The ATLAS measurement of \( R_{p\text{Pb}} \) as a function of the nuclear modification factor in proton-lead (\( p\) + Pb) collisions at a center-of-mass energy per nucleon pair \( \sqrt{s_{NN}} = 8.16 \) TeV, with an integrated luminosity of 165 nb\(^{-1}\). The black points represent theoretical predictions from various MCFM parton distribution functions (PDFs): TUJU21, nNNPDF30, nCTEQ15HQ, and EPPS21. The green band indicates the total uncertainty of the data, while the yellow band represents the statistical uncertainty. The dashed line at \( R_{p\text{Pb}} = 1 \) shows the expected value in the absence of nuclear modifications.