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.

Multiplicative $N_\mathrm{tracks}$-dependent corrections to the $\tau_\mathrm{h}$ MFs, in the $\mathrm{e}\tau_\mathrm{h}$ final state in the high-$m_\mathrm{T}$ CR, for the $h^{\pm} + \pi^0$(s) DM.

Multiplicative $N_\mathrm{tracks}$-dependent corrections to the $\tau_\mathrm{h}$ MFs, in the $\mathrm{e}\tau_\mathrm{h}$ final state in the SS CR, for the $h^{\pm} + \pi^0$(s) DM.

Observed and predicted $m_\mathrm{vis}$ distributions in the $\mathrm{e}\mu$ final state for events with $N_\mathrm{tracks} = 0$. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution is normalized to its best fit signal strength. The uncertainty band accounts for all sources of background and signal uncertainty, systematic as well as statistical, after the global fit.

Observed and predicted $m_\mathrm{vis}$ distributions in the $\mathrm{e}\tau_\mathrm{h}$ final state for events with $N_\mathrm{tracks} = 0$. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution is normalized to its best fit signal strength. The uncertainty band accounts for all sources of background and signal uncertainty, systematic as well as statistical, after the global fit.

Observed and predicted $m_\mathrm{vis}$ distributions in the $\mu\tau_\mathrm{h}$ final state for events with $N_\mathrm{tracks} = 0$. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution is normalized to its best fit signal strength. The uncertainty band accounts for all sources of background and signal uncertainty, systematic as well as statistical, after the global fit.

Observed and predicted $m_\mathrm{vis}$ distributions in the $\tau_\mathrm{h}\tau_\mathrm{h}$ final state for events with $N_\mathrm{tracks} = 0$. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution is normalized to its best fit signal strength. The uncertainty band accounts for all sources of background and signal uncertainty, systematic as well as statistical, after the global fit.

Observed and predicted $m_\mathrm{vis}$ distributions in the $\mathrm{e}\mu$ final state for events with $N_\mathrm{tracks} = 1$. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution is normalized to its best fit signal strength. The uncertainty band accounts for all sources of background and signal uncertainty, systematic as well as statistical, after the global fit.

Observed and predicted $m_\mathrm{vis}$ distributions in the $\mathrm{e}\tau_\mathrm{h}$ final state for events with $N_\mathrm{tracks} = 1$. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution is normalized to its best fit signal strength. The uncertainty band accounts for all sources of background and signal uncertainty, systematic as well as statistical, after the global fit.

Observed and predicted $m_\mathrm{vis}$ distributions in the $\mu\tau_\mathrm{h}$ final state for events with $N_\mathrm{tracks} = 1$. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution is normalized to its best fit signal strength. The uncertainty band accounts for all sources of background and signal uncertainty, systematic as well as statistical, after the global fit.

Observed and predicted $m_\mathrm{vis}$ distributions in the $\tau_\mathrm{h}\tau_\mathrm{h}$ final state for events with $N_\mathrm{tracks} = 1$. The normalization of the predicted background distributions corresponds to the result of the global fit. The signal distribution is normalized to its best fit signal strength. The uncertainty band accounts for all sources of background and signal uncertainty, systematic as well as statistical, after the global fit.

Observed and predicted $N_\mathrm{tracks}$ distributions for events passing the SR selection but with the relaxed requirement $N_\mathrm{tracks} < 10$ and the additional requirement $m_\mathrm{vis}>100\,\mathrm{GeV}$, combining all the final states together. The acoplanarity requirement $A < 0.015$ is applied. The inclusive diboson background contribution is drawn together with the ttbar process. The predicted distributions are adjusted to the result of the global fit performed with the mvis distributions in the SRs, and the signal distribution is normalized to its best fit signal strength. The lower panel shows the difference between the observed events and the backgrounds, as well as the signal contribution. Systematic uncertainties are assumed to be uncorrelated between final states to draw the uncertainty band.

Expected and observed negative log-likelihood scans as a function of $a_{\tau}$, for the combination of all SRs in all data-taking periods.

Expected and observed negative log-likelihood scans as a function of $d_{\tau}$, for the combination of all SRs in all data-taking periods.

Expected and observed 95% CL constraints on the real part of the Wilson coefficients $C_{\tau B}$ and $C_{\tau W}$ divided by $\Lambda^2$.

Expected and observed 95% CL constraints on the imaginary part of the Wilson coefficients $C_{\tau B}$ and $C_{\tau W}$ divided by $\Lambda^2$.

Event weights applied to simulations in the 2016 (pre-VFP) data-taking period as a function of the dilepton vertex position along the $z$ axis and the pileup track multiplicity in a 0.1 cm-wide window around the dilepton vertex ($N_\mathrm{tracks}^\mathrm{PU}$), where VFP stands for preamplifier feedback bias corrections due to inefficiencies in the strip modules of the tracker during the 2016 data-taking period. This correction is derived as a ratio between data and Drell-Yan simulation in a sample of dimuon events with $|m_{\mu\mu}-m_\mathrm{Z}|<15\,\mathrm{GeV}$ (see Fig. 3).

Event weights applied to simulations in the 2016 (post-VFP) data-taking period as a function of the dilepton vertex position along the $z$ axis and the pileup track multiplicity in a 0.1 cm-wide window around the dilepton vertex ($N_\mathrm{tracks}^\mathrm{PU}$), where VFP stands for preamplifier feedback bias corrections due to inefficiencies in the strip modules of the tracker during the 2016 data-taking period. This correction is derived as a ratio between data and Drell-Yan simulation in a sample of dimuon events with $|m_{\mu\mu}-m_\mathrm{Z}|<15\,\mathrm{GeV}$ (see Fig. 3).

Event weights applied to simulations in the 2017 data-taking period as a function of the dilepton vertex position along the $z$ axis and the pileup track multiplicity in a 0.1 cm-wide window around the dilepton vertex ($N_\mathrm{tracks}^\mathrm{PU}$), where VFP stands for preamplifier feedback bias corrections due to inefficiencies in the strip modules of the tracker during the 2016 data-taking period. This correction is derived as a ratio between data and Drell-Yan simulation in a sample of dimuon events with $|m_{\mu\mu}-m_\mathrm{Z}|<15\,\mathrm{GeV}$ (see Fig. 3).

Event weights applied to simulations in the 2018 data-taking period as a function of the dilepton vertex position along the $z$ axis and the pileup track multiplicity in a 0.1 cm-wide window around the dilepton vertex ($N_\mathrm{tracks}^\mathrm{PU}$), where VFP stands for preamplifier feedback bias corrections due to inefficiencies in the strip modules of the tracker during the 2016 data-taking period. This correction is derived as a ratio between data and Drell-Yan simulation in a sample of dimuon events with $|m_{\mu\mu}-m_\mathrm{Z}|<15\,\mathrm{GeV}$ (see Fig. 3).