The 95% CL expected upper limits on the production cross sections for $m_{\tilde{g}}$ in T5bbbbZg.

Gluino - neutralino mass points lying on the expected exclusion contour of T5bbbbZg model.

The 95% CL observed upper limits on the production cross sections for $m_{\tilde{g}}$ in T5qqqqHg.

Gluino - neutralino mass points lying on the observed exclusion contour of T5qqqqHg model.

The 95% CL expected upper limits on the production cross sections for $m_{\tilde{g}}$ in T5qqqqHg.

Gluino - neutralino mass points lying on the expected exclusion contour of T5qqqqHg model.

The 95% CL observed upper limits on the production cross sections for $m_{\tilde{g}}$ in T5ttttZg.

Gluino - neutralino mass points lying on the observed exclusion contour of T5ttttZg model.

The 95% CL expected upper limits on the production cross sections for $m_{\tilde{g}}$ in T5ttttZg.

Gluino - neutralino mass points lying on the expected exclusion contour of T5ttttZg model.

The 95% CL observed upper limits on the production cross sections for $m_{\tilde{t}}$ in T6ttZg.

Stop - neutralino mass points lying on the observed exclusion contour of T6ttZg model.

The 95% CL expected upper limits on the production cross sections for $m_{\tilde{t}}$ in T6ttZg.

Stop - neutralino mass points lying on the expected exclusion contour of T6ttZg model.

observed exclusion limit on the neutralino mass points in the TChiNGnn model.

expected exclusion limit on the neutralino mass points in the TChiNGnn model.

observed exclusion limit on the neutralino mass points in the TChiNG model.

expected exclusion limit on the neutralino mass points in the TChiNG model.

observed exclusion limit on the neutralino mass points in the TChiWG model.

expected exclusion limit on the neutralino mass points in the TChiWG model.

Acceptance times efficiency values with statistical uncertainties for T5bbbbZg in the SR region.

Acceptance times efficiency values with statistical uncertainties for T5qqqqHg in the SR region.

Acceptance times efficiency values with statistical uncertainties for T5ttttZg in the SR region.

Acceptance times efficiency values with statistical uncertainties for T6ttZg in the SR region.

Acceptance times efficiency values with statistical uncertainties for T5bbbbZg inclusive in the 45 bins.

Acceptance times efficiency values with statistical uncertainties for T5qqqqHg inclusive in the 45 bins.

Acceptance times efficiency values with statistical uncertainties for T5ttttZg inclusive in the 45 bins.

Acceptance times efficiency values with statistical uncertainties for T6ttZg inclusive in the 45 bins.

Acceptance times efficiency values with statistical uncertainties for TChiWG in the 45 optimised bins region.

Acceptance times efficiency values with statistical uncertainties for TChiNG in the 45 optimised bins region.

Event yield for T5bbbbZg and T5qqqqHg for each bin after SR baseline selections.

Event yield for T5ttttZg and T6ttZg for each bin after SR baseline selections.

Event yield for TChiWg and TChiNg for each bin after SR baseline selections.

Post-fit $m_\text{T}(\gamma, E_\text{T}^\text{miss})$ distribution in the inclusive signal region for the dark-photon search with the 125 GeV mass $\mathcal{B}(H \to \gamma \gamma_\text{d})$ signal normalization set to zero. A $H \to \gamma \gamma_\text{d}$ decay signal is shown for two different mass hypotheses, 125 GeV and 500 GeV, and scaled to a $\mathcal{B}(H \to \gamma \gamma_\text{d})$ of 2% and 1%, respectively. Events with $m_\text{T}(\gamma, E_\text{T}^\text{miss})$ larger than the rightmost bin boundary are added to that bin.

The 95% CL upper limit on the Higgs boson production cross-section times branching ratio to $\gamma \gamma_\text{d}$ is shown for different VBF-produced scalar-mediator-mass hypotheses in the NWA. The theoretically predicted cross-section of a Higgs boson produced via VBF and with the $\mathcal{B}(H \to \gamma \gamma_\text{d}) =$ 5% is superimposed on the $\pm 1\sigma$ and $\pm 2\sigma$ NNLO QCD + NLO EW uncertainty band of the expected production cross-section limit.

Post-fit $m_\text{jj}$ distribution in the inclusive signal region. The Higgs boson invisible decay signal is scaled to a $\mathcal{B}_\text{inv}$ of 37%. Events with $m_\text{jj}$ larger than the rightmost bin boundary are added to that bin.

Post-fit $m_\text{jj}$ distribution in the one-lepton control region $W_{\ell \nu}^\gamma$ CR. Events with $m_\text{jj}$ larger than the rightmost bin boundary are added to that bin.

Post-fit $m_\text{T}$ distribution in the one lepton control region. Events with $m_\text{T}$ larger than the rightmost bin boundary are added to that bin.

Post-fit photon centrality distribution in the zero lepton signal plus control region with the $\mathcal{B}_\text{inv}$ signal normalization set to zero in the fit.

Post-fit photon $E_\text{T}$ distribution in the zero lepton signal region with the $\mathcal{B}_\text{inv}$ signal normalization set to zero in the fit.

Post-fit photon centrality distribution in the zero lepton signal plus control region resulting from the fit to the $m_\text{jj}$ distribution for EW $Z \gamma + \text{jets}$. The post-fit uncertainties include statistical, experimental, and theory contributions.

Post-fit photon $E_\text{T}$ distribution in the zero lepton signal region resulting from the fit to the $m_\text{jj}$ distribution for EW $Z \gamma + \text{jets}$. The post-fit uncertainties include statistical, experimental, and theory contributions.

Post-fit DNN output score distribution in the one lepton control region.

Yields for the EW $Z \gamma + \text{jets}$ process are shown after each selection along with relative and absolute signal acceptance efficiencies.

Yields for the 125 GeV Higgs boson with $\mathcal{B}_\text{inv.} =$ 1 signal produced by the vector boson fusion process in association with a final state photon are shown after each selection along with relative and absolute signal acceptance efficiencies.

Yields for the 125 GeV Higgs boson with $\mathcal{B}(H \to \gamma \gamma_\text{d}) =$ 1 signal produced by the vector boson fusion process are shown after each selection along with relative and absolute signal acceptance efficiencies.