The predicted CC1$\pi^{-}$ background in units of fb/GeV $(10^{-39}~\mbox{cm}^2)/\mbox{GeV}$ . This background corresponds to an empirical adjustment of the Rein-Sehgal calculation based on the MiniBooNE CC1$\pi^{+}$ data.

The MiniBooNE numub single differential cross section $\frac{d\sigma}{dQ^2_{QE}}$ on mineral oil, shape error, and the predicted CCQE-like and CC1$\pi^{-}$ backgrounds in units of fb $(10^{-39} \mbox{cm}^2)$. Not included in the table is the total normalization error of 13.0$\%$.

The MiniBooNE $\bar{\nu}_\mu$ CCQE total cross section on mineral oil, total and shape errors, and predicted CCQE-like and CC1$\pi^{-}$ backgrounds in bins of $E_\nu^{\textrm{QE,RFG}}$ and units of fb $(10^{-39} \mbox{cm}^2)$. The total error includes both the shape and normalization uncertainties. Note that the total error is incorrectly quoted as a power of 10 too low in the paper and the preprint. It is corrected in the resource file from which these data here are taken.

The MiniBooNE $\bar{\nu}_\mu$ CCQE double-differential cross section, with the shape uncertainty, on carbon. The units are fb/GeV $(10^{-39} \mbox{cm}^2/\mbox{GeV})$. Not included in the table is the total normalization uncertainty of 17.4%.

The QE-like $\bar{\nu}_\mu$ background subtracted from the double-differential cross section on carbon. The $\bar{\nu}_\mu$ CCQE interactions with hydrogen are treated as background in this calculation, and so their contribution is included here. The units are fb/GeV $(10^{-39} \mbox{cm}^2/\mbox{GeV})$ .

The MiniBooNE $\bar{\nu}_\mu$ CCQE single differential cross section $\frac{d\sigma}{dQ^2_{QE}}$ on carbon, shape error, and CCQE-like background in units of fb/GeV$^2$ $(10^{-39} \mbox{cm}^2/\mbox{GeV}^2)$ . The $\bar{\nu}_\mu$ CCQE content is treated as background. Not included in the table is the total normalization error of 17.4%.

The MiniBooNE $\bar{\nu}_\mu$ CCQE total cross section on carbon, total and shape errors, and predicted CCQE-like background in bins of $E_\nu^{\textrm{QE,RFG}}$ and units of fb $(10^{-39} \mbox{cm}^2)$. The total error includes both the shape and normalization uncertainties.

The frequentist $3\sigma$ confidence region in $\sin^2(2\theta)$ $\Delta m^2$ for a 2-neutrino muon-to-electron oscillation fit.

The test-statistic $-2\ln\mathcal{L}$ as a function of $\Delta m^2$ and $\sin^2(2\theta)$ for a 2-neutrino muon-to-electron oscillation fit.

Observed NuE data and background prediction for arXiv:2006.16883

Observed NuMu data and prediction for arXiv:2006.16883

NuMu to NuE oscillation simulation for arXiv:2006.16883. Used used for the combined fit and the neutrino-mode analysis. ntuple has 17,204 predicted muon-to-electron neutrino and antineutrino full transmutation events simulated for the neutrino-mode beam, and contains information on reconstructed neutrino energy ($E_\text{vis}$), true neutrino energy, neutrino baseline, and event weight for each event.

Observed NuEBar data and background prediction for arXiv:2006.16883

Observed NuMuBar data and prediction for arXiv:2006.16883

NuMuBar to NuEBar oscillation simulation for arXiv:2006.16883. Used only for the combined fit. ntuple has 117,949 predicted muon-to-electron neutrino and antineutrino full transmutation events simulated for the antineutrino-mode beam, and contains information on reconstructed neutrino energy ($E_\text{vis}$), true neutrino energy, neutrino baseline, and event weight for each event. This simulation is only used for the combined fit.

NuMuBar to NuEBar oscillation simulation for arXiv:1207.4809. Used only for the antineutrino-mode analysis. ntuple has 86,403 predicted muon-to-electron neutrino and antineutrino full transmutation events simulated for the antineutrino-mode beam, and contains information on reconstructed neutrino energy ($E_\text{vis}$), true neutrino energy, neutrino baseline, and event weight for each event. This simulation is only used for the antineutrino-mode analysis.

The combined fractional covariance matrix for arXiv:2006:16883 includes bins for six classes of events in the following order: 1) neutrino-mode muon-to-electron full transmutation events, 2) neutrino-mode electron neutrino background events, 3) neutrino-mode muon neutrino CCQE events, 4) antineutrino-mode muon-to-electron full transmutation events, 5) antineutrino-mode electron antineutrino background events, 6) antineutrino-mode muon antineutrino CCQE events. Of these categories, the fractional covariance matrix includes the data statistical and systematic errors for four categories: (anti)neutrino-mode electron (anti)neutrino background events, and (anti)neutrino-mode muon (anti)neutrino CCQE events. The (anti)neutrino-mode muon-to-electron full transmutation event portions of the fractional covariance matrix only include systematic errors. The six event classes map to four observable event classifications: 1) NuE-like which includes classes 1 and 2, 2) NuMu-like which includes class 3, 3) NuEBar-like which includes classes 4 and 5, and 4) NuMuBar-like which includes class 6.

The neutrino-mode fractional covariance matrix for arXiv:2006:16883 includes bins for three classes of events in the following order: 1) neutrino-mode muon-to-electron full transmutation events, 2) neutrino-mode electron neutrino background events, 3) neutrino-mode muon neutrino CCQE events. Of these categories, the fractional covariance matrix includes the data statistical and systematic errors for two categories: neutrino-mode electron neutrino background events, and neutrino-mode muon neutrino CCQE events. The neutrino-mode muon-to-electron full transmutation event portion of the fractional covariance matrix only includes systematic errors. The three event classes map to two observable event classifications: 1) NuE-like which includes classes 1 and 2, 2) NuMu-like which includes class 3.

The antineutrino fractional covariance matrix for arXiv:1207.4809 includes bins for three classes of events in the following order: 1) antineutrino-mode muon-to-electron full transmutation events, 2) antineutrino-mode electron antineutrino background events, 3) antineutrino-mode muon antineutrino CCQE events. Of these categories, the fractional covariance matrix includes the data statistical and systematic errors for two categories: antineutrino-mode electron antineutrino background events, and antineutrino-mode muon antineutrino CCQE events. The antineutrino-mode muon-to-electron full transmutation event portions of the fractional covariance matrix only include systematic errors. The three event classes map to two observable event classifications: 1) NuEBar-like which includes classes 1 and 2, and 2) NuMuBar-like which includes class 3.

Values of the pp $\to$ H $\to \gamma\gamma$ differential cross sections as a function of $\Delta \phi^{\gamma\gamma}$ as measured in data. For each observable the fit to $m_{\gamma\gamma}$ is performed simultaneously in all the bins. Since the signal mass is profiled for each observable, the best fit $\hat{m}_{\rm{H}}$ varies from observable to observable.

Values of the pp $\to$ H $\to \gamma\gamma$ differential cross sections as a function of ||$y^{\gamma\gamma}$|| as measured in data. For each observable the fit to $m_{\gamma\gamma}$ is performed simultaneously in all the bins. Since the signal mass is profiled for each observable, the best fit $\hat{m}_{\rm{H}}$ varies from observable to observable.

Values of the pp $\to$ H $\to \gamma\gamma$ differential cross sections as a function of $N_\rm{jets}$ as measured in data. For each observable the fit to $m_{\gamma\gamma}$ is performed simultaneously in all the bins. Since the signal mass is profiled for each observable, the best fit $\hat{m}_{\rm{H}}$ varies from observable to observable.

Values of the pp $\to$ H $\to \gamma\gamma$ differential cross sections as a function of $p_\rm{T}^\rm{j1}$ as measured in data. For each observable the fit to $m_{\gamma\gamma}$ is performed simultaneously in all the bins. Since the signal mass is profiled for each observable, the best fit $\hat{m}_{\rm{H}}$ varies from observable to observable.

Values of the pp $\to$ H $\to \gamma\gamma$ differential cross sections as a function of |$y^{\gamma\gamma}-y^{\rm{j1}}$| as measured in data. For each observable the fit to $m_{\gamma\gamma}$ is performed simultaneously in all the bins. Since the signal mass is profiled for each observable, the best fit $\hat{m}_{\rm{H}}$ varies from observable to observable.

Values of the pp $\to$ H $\to \gamma\gamma$ differential cross sections as a function of $m_\rm{jj}$ as measured in data. For each observable the fit to $m_{\gamma\gamma}$ is performed simultaneously in all the bins. Since the signal mass is profiled for each observable, the best fit $\hat{m}_{\rm{H}}$ varies from observable to observable.

Values of the pp $\to$ H $\to \gamma\gamma$ differential cross sections as a function of $\Delta \eta^{\rm{jj}}$ as measured in data. For each observable the fit to $m_{\gamma\gamma}$ is performed simultaneously in all the bins. Since the signal mass is profiled for each observable, the best fit $\hat{m}_{\rm{H}}$ varies from observable to observable.

Values of the pp $\to$ H $\to \gamma\gamma$ differential cross sections as a function of $\Delta \phi^{\gamma\gamma,\rm{jj}}$ as measured in data. For each observable the fit to $m_{\gamma\gamma}$ is performed simultaneously in all the bins. Since the signal mass is profiled for each observable, the best fit $\hat{m}_{\rm{H}}$ varies from observable to observable.

Values of the pp $\to$ H $\to \gamma\gamma$ differential cross sections as a function of $\Delta \phi^{\rm{jj}}$ as measured in data. For each observable the fit to $m_{\gamma\gamma}$ is performed simultaneously in all the bins. Since the signal mass is profiled for each observable, the best fit $\hat{m}_{\rm{H}}$ varies from observable to observable.

Values of the pp $\to$ H $\to \gamma\gamma$ differential cross sections as a function of |$\eta^{\gamma\gamma}-(\eta^{\rm{j1}}+\eta^{\rm{j2}})/2$| as measured in data. For each observable the fit to $m_{\gamma\gamma}$ is performed simultaneously in all the bins. Since the signal mass is profiled for each observable, the best fit $\hat{m}_{\rm{H}}$ varies from observable to observable.

Observed event yields and estimated backgrounds in the low- and high-mass control regions. The uncertainty in the background yield is the sum in quadrature of the statistical and systematic uncertainties.

Summary of the relative systematic uncertainties in heavy Majorana neutrino signal yields and the background from prompt same-sign leptons, both estimated from simulation. The relative systematic uncertainties assigned to the data-driven backgrounds for the misidentified lepton background and mismeasured charge background are also shown. The uncertainties are given for the low-mass selections.

Summary of the relative systematic uncertainties in heavy Majorana neutrino signal yields and the background from prompt same-sign leptons, both estimated from simulation. The relative systematic uncertainties assigned to the data-driven backgrounds for the misidentified lepton background and mismeasured charge background are also shown. The uncertainties are given for the high-mass selections.

Summary of contributions to the systematic uncertainty related to the prompt same-sign leptons background, misidentified lepton background, and mismeasured charge background on the total background uncertainty for the case of $m_{\rm N}$ = 100 and 500 GeV.

Observed event yields and estimated backgrounds after the application of all selection, except for the final optimization. The background predictions from prompt same-sign leptons (Prompt bkgd.), misidentified leptons (Misid. bkgd.), mismeasured charge (Charge mismeas. bkgd.) and the total background (Total bkgd.) are shown together withthe number of events observed in data. The uncertainties shown are the statistical and systematic components, respectively.

Dielectron channel results after final optimization. The background predictions from prompt same-sign leptons, misidentified leptons, and mismeasured charge are shown along with the total background estimate and the number of events observed in data. The uncertainties shown are the statistical and systematic components, respectively.

Electron-muon channel results after final optimization. The background predictions from prompt same-sign leptons and misidentified leptons are shown along with the total background estimate and the number of events observed in data. The uncertainties shown are the statistical and systematic components, respectively.

The azimuthal dependence of $R_{out}^{2}$ as a function of $\Delta\varphi=\varphi_{\mathrm{pair}}-\Psi_{\mathrm EP,2}$ for the centrality 20-30% and different $k_{\mathrm{T}}$ ranges.

The azimuthal dependence of $R_{side}^{2}$ as a function of $\Delta\varphi=\varphi_{\mathrm{pair}}-\Psi_{\mathrm EP,2}$ for the centrality 20--30% and different $k_{\mathrm{T}}$ ranges.

The azimuthal dependence of $R_{side}^{2}$ as a function of $\Delta\varphi=\varphi_{\mathrm{pair}}-\Psi_{\mathrm EP,2}$ for the centrality 20--30% and different $k_{\mathrm{T}}$ ranges.

The azimuthal dependence of $R_{side}^{2}$ as a function of $\Delta\varphi=\varphi_{\mathrm{pair}}-\Psi_{\mathrm EP,2}$ for the centrality 20--30% and different $k_{\mathrm{T}}$ ranges.

The azimuthal dependence of $R_{side}^{2}$ as a function of $\Delta\varphi=\varphi_{\mathrm{pair}}-\Psi_{\mathrm EP,2}$ for the centrality 20--30% and different $k_{\mathrm{T}}$ ranges.

The azimuthal dependence of $R_{long}^{2}$ as a function of $\Delta\varphi=\varphi_{\mathrm{pair}}-\Psi_{\mathrm EP,2}$ for the centrality 20--30% and different $k_{\mathrm{T}}$ ranges.

The azimuthal dependence of $R_{long}^{2}$ as a function of $\Delta\varphi=\varphi_{\mathrm{pair}}-\Psi_{\mathrm EP,2}$ for the centrality 20--30% and different $k_{\mathrm{T}}$ ranges.

The azimuthal dependence of $R_{long}^{2}$ as a function of $\Delta\varphi=\varphi_{\mathrm{pair}}-\Psi_{\mathrm EP,2}$ for the centrality 20--30% and different $k_{\mathrm{T}}$ ranges.

The azimuthal dependence of $R_{os}^{2}$ as a function of $\Delta\varphi=\varphi_{\mathrm{pair}}-\Psi_{\mathrm EP,2}$ for the centrality 20--30% and different $k_{\mathrm{T}}$ ranges.

The azimuthal dependence of $R_{os}^{2}$ as a function of $\Delta\varphi=\varphi_{\mathrm{pair}}-\Psi_{\mathrm EP,2}$ for the centrality 20--30% and different $k_{\mathrm{T}}$ ranges.

The azimuthal dependence of $R_{os}^{2}$ as a function of $\Delta\varphi=\varphi_{\mathrm{pair}}-\Psi_{\mathrm EP,2}$ for the centrality 20--30% and different $k_{\mathrm{T}}$ ranges.

The average radii $R_{out,0}^{2}$ as a function of centrality for different $k_{\mathrm{T}}$ ranges.

The average radii $R_{out,0}^{2}$ as a function of centrality for different $k_{\mathrm{T}}$ ranges.

The average radii $R_{out,0}^{2}$ as a function of centrality for different $k_{\mathrm{T}}$ ranges.

The average radii $R_{out,0}^{2}$ as a function of centrality for different $k_{\mathrm{T}}$ ranges.

The average radii $R_{side,0}^{2}$ as a function of centrality for different $k_{\mathrm{T}}$ ranges.

The average radii $R_{side,0}^{2}$ as a function of centrality for different $k_{\mathrm{T}}$ ranges.

The average radii $R_{side,0}^{2}$ as a function of centrality for different $k_{\mathrm{T}}$ ranges.

The average radii $R_{side,0}^{2}$ as a function of centrality for different $k_{\mathrm{T}}$ ranges.

The average radii $R_{long,0}^{2}$ as a function of centrality for different $k_{\mathrm{T}}$ ranges.

The average radii $R_{long,0}^{2}$ as a function of centrality for different $k_{\mathrm{T}}$ ranges.

The average radii $R_{long,0}^{2}$ as a function of centrality for different $k_{\mathrm{T}}$ ranges.

The average radii $R_{long,0}^{2}$ as a function of centrality for different $k_{\mathrm{T}}$ ranges.

The average radii $R_{os,0}^{2}$ as a function of centrality for different $k_{\mathrm{T}}$ ranges.

The average radii $R_{os,0}^{2}$ as a function of centrality for different $k_{\mathrm{T}}$ ranges.

The average radii $R_{os,0}^{2}$ as a function of centrality for different $k_{\mathrm{T}}$ ranges.

The average radii $R_{os,0}^{2}$ as a function of centrality for different $k_{\mathrm{T}}$ ranges.

Amplitudes of the relative radius oscillations~$R^{2}_{\mathrm out,2}/R^{2}_{\mathrm side,0}$ versus centrality for different $k_{\mathrm T}$ ranges.

Amplitudes of the relative radius oscillations~$R^{2}_{\mathrm out,2}/R^{2}_{\mathrm side,0}$ versus centrality for different $k_{\mathrm T}$ ranges.

Amplitudes of the relative radius oscillations~$R^{2}_{\mathrm out,2}/R^{2}_{\mathrm side,0}$ versus centrality for different $k_{\mathrm T}$ ranges.

Amplitudes of the relative radius oscillations~$R^{2}_{\mathrm out,2}/R^{2}_{\mathrm side,0}$ versus centrality for different $k_{\mathrm T}$ ranges.

Amplitudes of the relative radius oscillations~$R^{2}_{\mathrm side,2}/R^{2}_{\mathrm side,0}$ versus centrality for different $k_{\mathrm T}$ ranges.

Amplitudes of the relative radius oscillations~$R^{2}_{\mathrm side,2}/R^{2}_{\mathrm side,0}$ versus centrality for different $k_{\mathrm T}$ ranges.

Amplitudes of the relative radius oscillations~$R^{2}_{\mathrm side,2}/R^{2}_{\mathrm side,0}$ versus centrality for different $k_{\mathrm T}$ ranges.

Amplitudes of the relative radius oscillations~$R^{2}_{\mathrm side,2}/R^{2}_{\mathrm side,0}$ versus centrality for different $k_{\mathrm T}$ ranges.

Amplitudes of the relative radius oscillations~$R^{2}_{\mathrm long,2}/R^{2}_{\mathrm long,0}$ versus centrality for different $k_{\mathrm T}$ ranges.

Amplitudes of the relative radius oscillations~$R^{2}_{\mathrm long,2}/R^{2}_{\mathrm long,0}$ versus centrality for different $k_{\mathrm T}$ ranges.

Amplitudes of the relative radius oscillations~$R^{2}_{\mathrm long,2}/R^{2}_{\mathrm long,0}$ versus centrality for different $k_{\mathrm T}$ ranges.

Amplitudes of the relative radius oscillations~$R^{2}_{\mathrm long,2}/R^{2}_{\mathrm long,0}$ versus centrality for different $k_{\mathrm T}$ ranges.

Amplitudes of the relative radius oscillations~$R^{2}_{\mathrm os,2}/R^{2}_{\mathrm side,0}$ versus centrality for different $k_{\mathrm T}$ ranges.

Amplitudes of the relative radius oscillations~$R^{2}_{\mathrm os,2}/R^{2}_{\mathrm side,0}$ versus centrality for different $k_{\mathrm T}$ ranges.

Amplitudes of the relative radius oscillations~$R^{2}_{\mathrm os,2}/R^{2}_{\mathrm side,0}$ versus centrality for different $k_{\mathrm T}$ ranges.

Amplitudes of the relative radius oscillations~$R^{2}_{\mathrm os,2}/R^{2}_{\mathrm side,0}$ versus centrality for different $k_{\mathrm T}$ ranges.

An estimate of freeze-out eccentricity $2 R^{2}_{\mathrm side,2}/R^{2}_{\mathrm side,0}$ for different $k_{\mathrm T}$ ranges vs. initial state eccentricity from Monte Carlo Glauber model for six centrality ranges, 0-5%, 5-10%, 10-20%, 20-30%, 30-40%, and 40-50%.

An estimate of freeze-out eccentricity $2 R^{2}_{\mathrm side,2}/R^{2}_{\mathrm side,0}$ for different $k_{\mathrm T}$ ranges vs. initial state eccentricity from Monte Carlo Glauber model for six centrality ranges, 0-5%, 5-10%, 10-20%, 20-30%, 30-40%, and 40-50%.

An estimate of freeze-out eccentricity $2 R^{2}_{\mathrm side,2}/R^{2}_{\mathrm side,0}$ for different $k_{\mathrm T}$ ranges vs. initial state eccentricity from Monte Carlo Glauber model for six centrality ranges, 0-5%, 5-10%, 10-20%, 20-30%, 30-40%, and 40-50%.

An estimate of freeze-out eccentricity $2 R^{2}_{\mathrm side,2}/R^{2}_{\mathrm side,0}$ for different $k_{\mathrm T}$ ranges vs. initial state eccentricity from Monte Carlo Glauber model for six centrality ranges, 0-5%, 5-10%, 10-20%, 20-30%, 30-40%, and 40-50%.

Invariant yields of the $\eta$ meson in the centrality class 20-50% in Pb-Pb collisions at sqrt{s_NN} = 2.76 TeV at mid-rapidity.

Nuclear modification factor R_AA of $\pi^{0}$ produced in 0-10% central Pb-Pb collisions at sqrt{s_NN} = 2.76 TeV at mid-rapidity, T_AA uncertainty of 3.25% and uncertainty of \sigma_{inel} of 3.9% included in systematic uncertainties.

Nuclear modification factor R_AA of $\pi^{0}$ produced in 20-50% central Pb-Pb collisions at sqrt{s_NN} = 2.76 TeV at mid-rapidity, T_AA uncertainty of 3.3% and uncertainty of \sigma_{inel} of 3.9% included in systematic uncertainties.

Nuclear modification factor R_AA of $\eta$ produced in 0-10% central Pb-Pb collisions at sqrt{s_NN} = 2.76 TeV at mid-rapidity, T_AA uncertainty of 3.25% and uncertainty of \sigma_{inel} of 3.9% included in systematic uncertainties.

Nuclear modification factor R_AA of $\eta$ produced in 20-50% central Pb-Pb collisions at sqrt{s_NN} = 2.76 TeV at mid-rapidity, T_AA uncertainty of 3.3% and uncertainty of \sigma_{inel} of 3.9% included in systematic uncertainties.

Ratio of the $\eta$ to $\pi^{0}$ invariant yields in 0-10% central Pb-Pb collisions at sqrt{s_NN} = 2.76 TeV at mid-rapidity.

Ratio of the $\eta$ to $\pi^{0}$ invariant yields in 20-50% central Pb-Pb collisions at sqrt{s_NN} = 2.76 TeV at mid-rapidity.

Normalized DPhi(Z, j2) distributions for Njets >= 3.

Normalized DPhi(Z, j3) distributions for Njets >= 3.

Normalized DPhi(j1, j2) distributions for Njets >= 3.

Normalized DPhi(j1, j3) distributions for Njets >= 3.

Normalized DPhi(j2, j3) distributions for Njets >= 3.

Normalized DPhi(Z, j1) distributions for Njets >= 1 and PT(Z) >= 150 GeV.

Normalized DPhi(Z, j1) distributions for Njets >= 2 and PT(Z) >= 150 GeV.

Normalized DPhi(Z, j1) distributions for Njets >= 3 and PT(Z) >= 150 GeV.

Normalized DPhi(Z, j2) distributions for Njets >= 3 and PT(Z) >= 150 GeV.

Normalized DPhi(Z, j3) distributions for Njets >= 3 and PT(Z) >= 150 GeV.

Normalized DPhi(j1, j2) distributions for Njets >= 3 and PT(Z) >= 150 GeV.

Normalized DPhi(j1, j3) distributions for Njets >= 3 and PT(Z) >= 150 GeV.

Normalized DPhi(j2, j3) distributions for Njets >= 3 and PT(Z) >= 150 GeV.

Normalized distributions in ln(tauT) for all PT(Z) and Njets >=1.

Normalized distributions in ln(tauT) for PT(Z) > 150 GeV and Njets >=1.

pT-differential nuclear modification factor of heavy-flavour decay muons at forward rapidity (proton-going side)

pT-differential nuclear modification factor of heavy-flavour decay muons at backward rapidity (Pb-going side)

pT-differential forward-to-backward ratio of heavy-flavour decay muons

Azimuthal correlation of D mesons (${\rm D}^{0}$, ${\rm D}^{+}$, ${\rm D}^{*+}$ average) with $5 < p_{\rm T} < 8~{\rm GeV}/c$ and $|y_{\rm cms}| < 0.5$ ($-0.96 < y_{\rm cms} < 0.04$) and charged particles with $p_{\rm T} > 0.3~{\rm GeV}/c$ for $|\Delta\eta| = |\eta_{\rm ch}-\eta_{\rm D}| < 1$ measured in pp (p-Pb) collisions at $\sqrt{s} = 7~{\rm TeV}$ ($\sqrt{s_{\rm NN}} = 5.02~{\rm TeV}$).

Azimuthal correlation of D mesons (${\rm D}^{0}$, ${\rm D}^{+}$, ${\rm D}^{*+}$ average) with $8 < p_{\rm T} < 16~{\rm GeV}/c$ and $|y_{\rm cms}| < 0.5$ ($-0.96 < y_{\rm cms} < 0.04$) and charged particles with $p_{\rm T} > 0.3~{\rm GeV}/c$ for $|\Delta\eta| = |\eta_{\rm ch}-\eta_{\rm D}| < 1$ measured in pp (p-Pb) collisions at $\sqrt{s} = 7~{\rm TeV}$ ($\sqrt{s_{\rm NN}} = 5.02~{\rm TeV}$).

Azimuthal correlation of D mesons (${\rm D}^{0}$, ${\rm D}^{+}$, ${\rm D}^{*+}$ average) with $3 < p_{\rm T} < 5~{\rm GeV}/c$ and $|y_{\rm cms}| < 0.5$ and charged particles with $0.3 < p_{\rm T} < 1~{\rm GeV}/c$ for $|\Delta\eta| = |\eta_{\rm ch}-\eta_{\rm D}| < 1$ measured in pp collisions at $\sqrt{s} = 7~{\rm TeV}$.

Azimuthal correlation of D mesons (${\rm D}^{0}$, ${\rm D}^{+}$, ${\rm D}^{*+}$ average) with $5 < p_{\rm T} < 8~{\rm GeV}/c$ and $|y_{\rm cms}| < 0.5$ ($-0.96 < y_{\rm cms} < 0.04$) and charged particles with $0.3 < p_{\rm T} < 1~{\rm GeV}/c$ for $|\Delta\eta| = |\eta_{\rm ch}-\eta_{\rm D}| < 1$ measured in pp (p-Pb) collisions at $\sqrt{s} = 7~{\rm TeV}$ ($\sqrt{s_{\rm NN}} = 5.02~{\rm TeV}$).

Azimuthal correlation of D mesons (${\rm D}^{0}$, ${\rm D}^{+}$, ${\rm D}^{*+}$ average) with $8 < p_{\rm T} < 16~{\rm GeV}/c$ and $|y_{\rm cms}| < 0.5$ ($-0.96 < y_{\rm cms} < 0.04$) and charged particles with $0.3 < p_{\rm T} < 1~{\rm GeV}/c$ for $|\Delta\eta| = |\eta_{\rm ch}-\eta_{\rm D}| < 1$ measured in pp (p-Pb) collisions at $\sqrt{s} = 7~{\rm TeV}$ ($\sqrt{s_{\rm NN}} = 5.02~{\rm TeV}$).

Azimuthal correlation of D mesons (${\rm D}^{0}$, ${\rm D}^{+}$, ${\rm D}^{*+}$ average) with $3 < p_{\rm T} < 5~{\rm GeV}/c$ and $|y_{\rm cms}| < 0.5$ and charged particles with $p_{\rm T} > 1~{\rm GeV}/c$ for $|\Delta\eta| = |\eta_{\rm ch}-\eta_{\rm D}| < 1$ measured in pp collisions at $\sqrt{s} = 7~{\rm TeV}$.

Azimuthal correlation of D mesons (${\rm D}^{0}$, ${\rm D}^{+}$, ${\rm D}^{*+}$ average) with $5 < p_{\rm T} < 8~{\rm GeV}/c$ and $|y_{\rm cms}| < 0.5$ ($-0.96 < y_{\rm cms} < 0.04$) and charged particles with $p_{\rm T} > 1~{\rm GeV}/c$ for $|\Delta\eta| = |\eta_{\rm ch}-\eta_{\rm D}| < 1$ measured in pp (p-Pb) collisions at $\sqrt{s} = 7~{\rm TeV}$ ($\sqrt{s_{\rm NN}} = 5.02~{\rm TeV}$).

Azimuthal correlation of D mesons (${\rm D}^{0}$, ${\rm D}^{+}$, ${\rm D}^{*+}$ average) with $8 < p_{\rm T} < 16~{\rm GeV}/c$ and $|y_{\rm cms}| < 0.5$ ($-0.96 < y_{\rm cms} < 0.04$) and charged particles with $p_{\rm T} > 1~{\rm GeV}/c$ for $|\Delta\eta| = |\eta_{\rm ch}-\eta_{\rm D}| < 1$ measured in pp (p-Pb) collisions at $\sqrt{s} = 7~{\rm TeV}$ ($\sqrt{s_{\rm NN}} = 5.02~{\rm TeV}$).

Comparison of the azimuthal-correlation distributions of D mesons (average of D$^{0}$, D$^{+}$, D$^{*+}$) with $5 < p_{\rm T} < 8$ GeV/$c$ and charged particles with $p_{\rm T} > 0.3$ GeV/$c$, in pp collisions at $\sqrt{s} = 7$ TeV and p-Pb collisions at $\sqrt{s_{NN}} = 5.02$ TeV. Rapidity range for the D mesons are $|y^{\rm D}_{\rm cms}| < 0.5$ in pp, $-0.96 < y^{\rm D}_{\rm cms} < 0.04$ in p-Pb. Correlations are integrated for $|\Delta\eta|=|\eta_{\rm ch}-\eta_{\rm D}| < 1$. The azimuthal-correlation distributions are reported in the range $0 < \Delta\varphi < \pi$.

Comparison of the azimuthal-correlation distributions of D mesons (average of D$^{0}$, D$^{+}$, D$^{*+}$) with $8 < p_{\rm T} < 16$ GeV/$c$ and charged particles with $p_{\rm T} > 0.3$ GeV/$c$, in pp collisions at $\sqrt{s} = 7$ TeV and p-Pb collisions at $\sqrt{s_{NN}} = 5.02$ TeV. Rapidity range for the D mesons are $|y^{\rm D}_{\rm cms}| < 0.5$ in pp, $-0.96 < y^{\rm D}_{\rm cms} < 0.04$ in p-Pb. Correlations are integrated for $|\Delta\eta|=|\eta_{\rm ch}-\eta_{\rm D}| < 1$. The azimuthal-correlation distributions are reported in the range $0 < \Delta\varphi < \pi$.

Comparison of the azimuthal-correlation distributions of D mesons (average of D$^{0}$, D$^{+}$, D$^{*+}$) with $5 < p_{\rm T} < 8$ GeV/$c$ and charged particles with $0.3 < p_{\rm T} < 1$ GeV/$c$, in pp collisions at $\sqrt{s} = 7$ TeV and p-Pb collisions at $\sqrt{s_{NN}} = 5.02$ TeV. Rapidity range for the D mesons are $|y^{\rm D}_{\rm cms}| < 0.5$ in pp, $-0.96 < y^{\rm D}_{\rm cms} < 0.04$ in p-Pb. Correlations are integrated for $|\Delta\eta|=|\eta_{\rm ch}-\eta_{\rm D}| < 1$. The azimuthal-correlation distributions are reported in the range $0 < \Delta\varphi < \pi$.

Comparison of the azimuthal-correlation distributions of D mesons (average of D$^{0}$, D$^{+}$, D$^{*+}$) with $8 < p_{\rm T} < 16$ GeV/$c$ and charged particles with $0.3 < p_{\rm T} < 1$ GeV/$c$, in pp collisions at $\sqrt{s} = 7$ TeV and p-Pb collisions at $\sqrt{s_{NN}} = 5.02$ TeV. Rapidity range for the D mesons are $|y^{\rm D}_{\rm cms}| < 0.5$ in pp, $-0.96 < y^{\rm D}_{\rm cms} < 0.04$ in p-Pb. Correlations are integrated for $|\Delta\eta|=|\eta_{\rm ch}-\eta_{\rm D}| < 1$. The azimuthal-correlation distributions are reported in the range $0 < \Delta\varphi < \pi$.

Comparison of the azimuthal-correlation distributions of D mesons (average of D$^{0}$, D$^{+}$, D$^{*+}$) with $5 < p_{\rm T} < 8$ GeV/$c$ and charged particles with $p_{\rm T} > 1$ GeV/$c$, in pp collisions at $\sqrt{s} = 7$ TeV and p-Pb collisions at $\sqrt{s_{NN}} = 5.02$ TeV. Rapidity range for the D mesons are $|y^{\rm D}_{\rm cms}| < 0.5$ in pp, $-0.96 < y^{\rm D}_{\rm cms} < 0.04$ in p-Pb. Correlations are integrated for $|\Delta\eta| = |\eta_{\rm ch}-\eta_{\rm D}| < 1$. The azimuthal-correlation distributions are reported in the range $0 < \Delta\varphi < \pi$.

Comparison of the azimuthal-correlation distributions of D mesons (average of D$^{0}$, D$^{+}$, D$^{*+}$) with $8 < p_{\rm T} < 16$ GeV/$c$ and charged particles with $p_{\rm T} > 1$ GeV/$c$, in pp collisions at $\sqrt{s} = 7$ TeV and p-Pb collisions at $\sqrt{s_{NN}} = 5.02$ TeV. Rapidity range for the D mesons are $|y^{\rm D}_{\rm cms}| < 0.5$ in pp, $-0.96 < y^{\rm D}_{\rm cms} < 0.04$ in p-Pb. Correlations are integrated for $|\Delta\eta| = |\eta_{\rm ch}-\eta_{\rm D}| < 1$. The azimuthal-correlation distributions are reported in the range $0 < \Delta\varphi < \pi$.

Azimuthal correlation of D mesons (${\rm D}^{0}$, ${\rm D}^{+}$, ${\rm D}^{*+}$ average) with $3 < p_{\rm T} < 5~{\rm GeV}/c$ and $|y_{\rm cms}| < 0.5$ and charged particles with $p_{\rm T} > 0.3~{\rm GeV}/c$ for $|\Delta\eta| = |\eta_{\rm ch}-\eta_{\rm D}| < 1$ measured in pp collisions at $\sqrt{s} = 7~{\rm TeV}$. The points are shown after the subtraction of the baseline of the distribution, which is defined as the physical minimum of the distribution and estimated from the weighted average of the points in the transverse region ($\pi/4 < |\Delta\varphi| < \pi/2$).

Azimuthal correlation of D mesons (${\rm D}^{0}$, ${\rm D}^{+}$, ${\rm D}^{*+}$ average) with $5 < p_{\rm T} < 8~{\rm GeV}/c$ and $|y_{\rm cms}| < 0.5$ and charged particles with $p_{\rm T} > 0.3~{\rm GeV}/c$ for $|\Delta\eta| = |\eta_{\rm ch}-\eta_{\rm D}| < 1$ measured in pp collisions at $\sqrt{s} = 7~{\rm TeV}$. The points are shown after the subtraction of the baseline of the distribution, which is defined as the physical minimum of the distribution and estimated from the weighted average of the points in the transverse region ($\pi/4 < |\Delta\varphi| < \pi/2$).

Azimuthal correlation of D mesons (${\rm D}^{0}$, ${\rm D}^{+}$, ${\rm D}^{*+}$ average) with $8 < p_{\rm T} < 16~{\rm GeV}/c$ and $|y_{\rm cms}| < 0.5$ and charged particles with $p_{\rm T} > 0.3~{\rm GeV}/c$ for $|\Delta\eta| = |\eta_{\rm ch}-\eta_{\rm D}| < 1$ measured in pp collisions at $\sqrt{s} = 7~{\rm TeV}$. The points are shown after the subtraction of the baseline of the distribution, which is defined as the physical minimum of the distribution and estimated from the weighted average of the points in the transverse region ($\pi/4 < |\Delta\varphi| < \pi/2$).

Azimuthal correlation of D mesons (${\rm D}^{0}$, ${\rm D}^{+}$, ${\rm D}^{*+}$ average) with $3 < p_{\rm T} < 5~{\rm GeV}/c$ and $|y_{\rm cms}| < 0.5$ and charged particles with $0.3 < p_{\rm T} < 1~{\rm GeV}/c$ for $|\Delta\eta| = |\eta_{\rm ch}-\eta_{\rm D}| < 1$ measured in pp collisions at $\sqrt{s} = 7~{\rm TeV}$. The points are shown after the subtraction of the baseline of the distribution, which is defined as the physical minimum of the distribution and estimated from the weighted average of the points in the transverse region ($\pi/4 < |\Delta\varphi| < \pi/2$).

Azimuthal correlation of D mesons (${\rm D}^{0}$, ${\rm D}^{+}$, ${\rm D}^{*+}$ average) with $5 < p_{\rm T} < 8~{\rm GeV}/c$ and $|y_{\rm cms}| < 0.5$ and charged particles with $0.3 < p_{\rm T} < 1~{\rm GeV}/c$ for $|\Delta\eta| = |\eta_{\rm ch}-\eta_{\rm D}| < 1$ measured in pp collisions at $\sqrt{s} = 7~{\rm TeV}$. The points are shown after the subtraction of the baseline of the distribution, which is defined as the physical minimum of the distribution and estimated from the weighted average of the points in the transverse region ($\pi/4 < |\Delta\varphi| < \pi/2$).

Azimuthal correlation of D mesons (${\rm D}^{0}$, ${\rm D}^{+}$, ${\rm D}^{*+}$ average) with $8 < p_{\rm T} < 16~{\rm GeV}/c$ and $|y_{\rm cms}| < 0.5$ and charged particles with $0.3 < p_{\rm T} < 1~{\rm GeV}/c$ for $|\Delta\eta| = |\eta_{\rm ch}-\eta_{\rm D}| < 1$ measured in pp collisions at $\sqrt{s} = 7~{\rm TeV}$. The points are shown after the subtraction of the baseline of the distribution, which is defined as the physical minimum of the distribution and estimated from the weighted average of the points in the transverse region ($\pi/4 < |\Delta\varphi| < \pi/2$).

Azimuthal correlation of D mesons (${\rm D}^{0}$, ${\rm D}^{+}$, ${\rm D}^{*+}$ average) with $3 < p_{\rm T} < 5~{\rm GeV}/c$ and $|y_{\rm cms}| < 0.5$ and charged particles with $p_{\rm T} > 1~{\rm GeV}/c$ for $|\Delta\eta| = |\eta_{\rm ch}-\eta_{\rm D}| < 1$ measured in pp collisions at $\sqrt{s} = 7~{\rm TeV}$. The points are shown after the subtraction of the baseline of the distribution, which is defined as the physical minimum of the distribution and estimated from the weighted average of the points in the transverse region ($\pi/4 < |\Delta\varphi| < \pi/2$).

Azimuthal correlation of D mesons (${\rm D}^{0}$, ${\rm D}^{+}$, ${\rm D}^{*+}$ average) with $5 < p_{\rm T} < 8~{\rm GeV}/c$ and $|y_{\rm cms}| < 0.5$ and charged particles with $p_{\rm T} > 1~{\rm GeV}/c$ for $|\Delta\eta| = |\eta_{\rm ch}-\eta_{\rm D}| < 1$ measured in pp collisions at $\sqrt{s} = 7~{\rm TeV}$. The points are shown after the subtraction of the baseline of the distribution, which is defined as the physical minimum of the distribution and estimated from the weighted average of the points in the transverse region ($\pi/4 < |\Delta\varphi| < \pi/2$).

Azimuthal correlation of D mesons (${\rm D}^{0}$, ${\rm D}^{+}$, ${\rm D}^{*+}$ average) with $8 < p_{\rm T} < 16~{\rm GeV}/c$ and $|y_{\rm cms}| < 0.5$ and charged particles with $p_{\rm T} > 1~{\rm GeV}/c$ for $|\Delta\eta| = |\eta_{\rm ch}-\eta_{\rm D}| < 1$ measured in pp collisions at $\sqrt{s} = 7~{\rm TeV}$. The points are shown after the subtraction of the baseline of the distribution, which is defined as the physical minimum of the distribution and estimated from the weighted average of the points in the transverse region ($\pi/4 < |\Delta\varphi| < \pi/2$).

Near-side-peak associated yield values measured in pp collisions at $\sqrt{s} = 7$ TeV, for correlations of D mesons (D$^{0}$, D$^{+}$, D$^{*+}$ average) and charged particles, as a function of the D-meson $p_{\rm T}$, for associated track $p_{\rm T} > 0.3$ GeV/$c$. Rapidity range for the D mesons is $|y^{\rm D}_{\rm cms}| < 0.5$. Correlations are integrated for $|\Delta\eta|=|\eta_{\rm ch}-\eta_{\rm D}| < 1$.

Near-side-peak associated yield values measured in pp collisions at $\sqrt{s} = 7$ TeV, for correlations of D mesons (D$^{0}$, D$^{+}$, D$^{*+}$ average) and charged particles, as a function of the D-meson $p_{\rm T}$, for associated track $0.3 < p_{\rm T} < 1$ GeV/$c$. Rapidity range for the D mesons is $|y^{\rm D}_{\rm cms}| < 0.5$. Correlations are integrated for $|\Delta\eta|=|\eta_{\rm ch}-\eta_{\rm D}| < 1$.

Near-side-peak associated yield values measured in pp collisions at $\sqrt{s} = 7$ TeV, for correlations of D mesons (D$^{0}$, D$^{+}$, D$^{*+}$ average) and charged particles, as a function of the D-meson $p_{\rm T}$, for associated track $p_{\rm T} > 1$ GeV/$c$. Rapidity range for the D mesons is $|y^{\rm D}_{\rm cms}| < 0.5$. Correlations are integrated for $|\Delta\eta|=|\eta_{\rm ch}-\eta_{\rm D}| < 1$.

Near-side-peak width values measured in pp collisions at $\sqrt{s} = 7$ TeV, for correlations of D mesons (D$^{0}$, D$^{+}$, D$^{*+}$ average) and charged particles, as a function of the D-meson $p_{\rm T}$, for associated track $p_{\rm T} > 0.3$ GeV/$c$. Rapidity range for the D mesons is $|y^{\rm D}_{\rm cms}| < 0.5$. Correlations are integrated for $|\Delta\eta|=|\eta_{\rm ch}-\eta_{\rm D}| < 1$.

Near-side-peak width values measured in pp collisions at $\sqrt{s} = 7$ TeV, for correlations of D mesons (D$^{0}$, D$^{+}$, D$^{*+}$ average) and charged particles, as a function of the D-meson $p_{\rm T}$, for associated track $0.3 < p_{\rm T} < 1$ GeV/$c$. Rapidity range for the D mesons is $|y^{\rm D}_{\rm cms}| < 0.5$. Correlations are integrated for $|\Delta\eta|=|\eta_{\rm ch}-\eta_{\rm D}| < 1$.

Near-side-peak width values measured in pp collisions at $\sqrt{s} = 7$ TeV, for correlations of D mesons (D$^{0}$, D$^{+}$, D$^{*+}$ average) and charged particles, as a function of the D-meson $p_{\rm T}$, for associated track $p_{\rm T} > 1$ GeV/$c$. Rapidity range for the D mesons is $|y^{\rm D}_{\rm cms}| < 0.5$. Correlations are integrated for $|\Delta\eta|=|\eta_{\rm ch}-\eta_{\rm D}| < 1$.

Baseline values measured in pp collisions at $\sqrt{s} = 7$ TeV, for correlations of D mesons (D$^{0}$, D$^{+}$, D$^{*+}$ average) and charged particles, as a function of the D-meson $p_{\rm T}$, for associated track $p_{\rm T} > 0.3$ GeV/$c$. Rapidity range for the D mesons is $|y^{\rm D}_{\rm cms}| < 0.5$. Correlations are integrated for $|\Delta\eta|=|\eta_{\rm ch}-\eta_{\rm D}| < 1$.

Baseline values measured in pp collisions at $\sqrt{s} = 7$ TeV, for correlations of D mesons (D$^{0}$, D$^{+}$, D$^{*+}$ average) and charged particles, as a function of the D-meson $p_{\rm T}$, for associated track $0.3 < p_{\rm T} < 1$ GeV/$c$. Rapidity range for the D mesons is $|y^{\rm D}_{\rm cms}| < 0.5$. Correlations are integrated for $|\Delta\eta|=|\eta_{\rm ch}-\eta_{\rm D}| < 1$.

Baseline values measured in pp collisions at $\sqrt{s} = 7$ TeV, for correlations of D mesons (D$^{0}$, D$^{+}$, D$^{*+}$ average) and charged particles, as a function of the D-meson $p_{\rm T}$, for associated track $p_{\rm T} > 1$ GeV/$c$. Rapidity range for the D mesons is $|y^{\rm D}_{\rm cms}| < 0.5$. Correlations are integrated for $|\Delta\eta|=|\eta_{\rm ch}-\eta_{\rm D}| < 1$.

Near-side-peak associated yield values measured in p-Pb collisions at $\sqrt{s_{\rm NN}} = 5.02$ TeV, for correlations of D mesons (D$^{0}$, D$^{+}$, D$^{*+}$ average) and charged particles, as a function of the D-meson $p_{\rm T}$, for associated track $p_{\rm T} > 0.3$ GeV/$c$. Rapidity range for the D mesons is $-0.96 < y^{\rm D}_{\rm cms} < 0.04$. Correlations are integrated for $|\Delta\eta|=|\eta_{\rm ch}-\eta_{\rm D}| < 1$.

Near-side-peak associated yield values measured in p-Pb collisions at $\sqrt{s_{\rm NN}} = 5.02$ TeV, for correlations of D mesons (D$^{0}$, D$^{+}$, D$^{*+}$ average) and charged particles, as a function of the D-meson $p_{\rm T}$, for associated track $0.3 < p_{\rm T} < 1$ GeV/$c$. Rapidity range for the D mesons is $-0.96 < y^{\rm D}_{\rm cms} < 0.04$. Correlations are integrated for $|\Delta\eta|=|\eta_{\rm ch}-\eta_{\rm D}| < 1$.

Near-side-peak associated yield values measured in p-Pb collisions at $\sqrt{s_{\rm NN}} = 5.02$ TeV, for correlations of D mesons (D$^{0}$, D$^{+}$, D$^{*+}$ average) and charged particles, as a function of the D-meson $p_{\rm T}$, for associated track $p_{\rm T} > 1$ GeV/$c$. Rapidity range for the D mesons is $-0.96 < y^{\rm D}_{\rm cms} < 0.04$. Correlations are integrated for $|\Delta\eta|=|\eta_{\rm ch}-\eta_{\rm D}| < 1$.

Near-side-peak width values measured in p-Pb collisions at $\sqrt{s_{\rm NN}} = 5.02$ TeV, for correlations of D mesons (D$^{0}$, D$^{+}$, D$^{*+}$ average) and charged particles, as a function of the D-meson $p_{\rm T}$, for associated track $p_{\rm T} > 0.3$ GeV/$c$. Rapidity range for the D mesons is $-0.96 < y^{\rm D}_{\rm cms} < 0.04$. Correlations are integrated for $|\Delta\eta|=|\eta_{\rm ch}-\eta_{\rm D}| < 1$.

Near-side-peak width values measured in p-Pb collisions at $\sqrt{s_{\rm NN}} = 5.02$ TeV, for correlations of D mesons (D$^{0}$, D$^{+}$, D$^{*+}$ average) and charged particles, as a function of the D-meson $p_{\rm T}$, for associated track $0.3 < p_{\rm T} < 1$ GeV/$c$. Rapidity range for the D mesons is $-0.96 < y^{\rm D}_{\rm cms} < 0.04$. Correlations are integrated for $|\Delta\eta|=|\eta_{\rm ch}-\eta_{\rm D}| < 1$.

Near-side-peak width values measured in p-Pb collisions at $\sqrt{s_{\rm NN}} = 5.02$ TeV, for correlations of D mesons (D$^{0}$, D$^{+}$, D$^{*+}$ average) and charged particles, as a function of the D-meson $p_{\rm T}$, for associated track $p_{\rm T} > 1$ GeV/$c$. Rapidity range for the D mesons is $-0.96 < y^{\rm D}_{\rm cms} < 0.04$. Correlations are integrated for $|\Delta\eta| =|\eta_{\rm ch}-\eta_{\rm D}|< 1$.