The p--$\Omega^{-}$ $\oplus$ $\overline{\mathrm{p}}$--$\overline{\Omega}^{+}$ correlation function.

C(k*)/(quadratic baseline) for K0s K+ and all kT, systematic uncertainties negligible for k*>0.06 GeV/c

C(k*)/(quadratic baseline) for K0s K+ and kT < 0.85 GeV/c, systematic uncertainties negligible for k*>0.06 GeV/c

C(k*)/(quadratic baseline) for K0s K+ and kT > 0.85 GeV/c, systematic uncertainties negligible for k*>0.06 GeV/c

C(k*)/(quadratic baseline) for K0s K- and all kT, systematic uncertainties negligible for k*>0.06 GeV/c

C(k*)/(quadratic baseline) for K0s K- and kT < 0.85 GeV/c, systematic uncertainties negligible for k*>0.06 GeV/c

C(k*)/(quadratic baseline) for K0s K- and kT > 0.85 GeV/c, systematic uncertainties negligible for k*>0.06 GeV/c

R vs. kT for 7 TeV pp averaged over K0s K+ and K0s K- with Achasov2 parameters

R vs. kT for 2.76 TeV/nucleon Pb Pb averaged over K0s K+ and K0s K- with Achasov2 parameters

lambda/purity vs. kT for 7 TeV pp averaged over K0s K+ and K0s K- with Achasov2 parameters

lambda/purity vs. kT for 2.76 TeV/nucleon Pb Pb averaged over K0s K+ and K0s K- with Achasov2 parameters

R vs. kT for 7 TeV pp averaged over K0s K+ and K0s K- and with Achasov2 parameters

R vs. kT for 7 TeV pp --> K0s K0s averaged over event multiplicity

R vs. kT for 7 TeV pp --> K+- K+- averaged over event multiplicity and averaged between K+ and K-

lambda/purity vs. kT for 7 TeV pp averaged over K0s K+ and K0s K- and with Achasov2 parameters

lambda/purity vs. kT for 7 TeV pp --> K0s K0s averaged over event multiplicity

lambda/purity vs. kT for 7 TeV pp --> K+- K+- averaged over event multiplicity and averaged between K+ and K-

THERMINATOR 2 simulation correlation function for the $\Lambda\mathrm{K^{+}}\oplus\overline{\Lambda}\mathrm{K^{-}}$ system in the 0--10\% centrality interval.

Measured correlation function for the $\Lambda\mathrm{K^{-}}\oplus\overline{\Lambda}\mathrm{K^{+}}$ system in the 0--10\% centrality interval.

THERMINATOR 2 simulation correlation function for the $\Lambda\mathrm{K^{-}}\oplus\overline{\Lambda}\mathrm{K^{+}}$ system in the 0--10\% centrality interval.

Measured correlation function for the $\Lambda\mathrm{K^{0}_{S}}\oplus\overline{\Lambda}\mathrm{K^{0}_{S}}$ system in the 0--10\% centrality interval.

THERMINATOR 2 simulation correlation function for the $\Lambda\mathrm{K^{0}_{S}}\oplus\overline{\Lambda}\mathrm{K^{0}_{S}}$ system in the 0--10\% centrality interval.

Measured correlation function for the $\Lambda\mathrm{K^{+}}\oplus\overline{\Lambda}\mathrm{K^{-}}$ system in the 10--30\% centrality interval.

THERMINATOR 2 simulation correlation function for the $\Lambda\mathrm{K^{+}}\oplus\overline{\Lambda}\mathrm{K^{-}}$ system in the 10--30\% centrality interval.

Measured correlation function for the $\Lambda\mathrm{K^{-}}\oplus\overline{\Lambda}\mathrm{K^{+}}$ system in the 10--30\% centrality interval.

THERMINATOR 2 simulation correlation function for the $\Lambda\mathrm{K^{-}}\oplus\overline{\Lambda}\mathrm{K^{+}}$ system in the 10--30\% centrality interval.

Measured correlation function for the $\Lambda\mathrm{K^{0}_{S}}\oplus\overline{\Lambda}\mathrm{K^{0}_{S}}$ system in the 10--30\% centrality interval.

THERMINATOR 2 simulation correlation function for the $\Lambda\mathrm{K^{0}_{S}}\oplus\overline{\Lambda}\mathrm{K^{0}_{S}}$ system in the 10--30\% centrality interval.

Measured correlation function for the $\Lambda\mathrm{K^{+}}\oplus\overline{\Lambda}\mathrm{K^{-}}$ system in the 30--50\% centrality interval.

THERMINATOR 2 simulation correlation function for the $\Lambda\mathrm{K^{+}}\oplus\overline{\Lambda}\mathrm{K^{-}}$ system in the 30--50\% centrality interval.

Measured correlation function for the $\Lambda\mathrm{K^{-}}\oplus\overline{\Lambda}\mathrm{K^{+}}$ system in the 30--50\% centrality interval.

THERMINATOR 2 simulation correlation function for the $\Lambda\mathrm{K^{-}}\oplus\overline{\Lambda}\mathrm{K^{+}}$ system in the 30--50\% centrality interval.

Measured correlation function for the $\Lambda\mathrm{K^{0}_{S}}\oplus\overline{\Lambda}\mathrm{K^{0}_{S}}$ system in the 30--50\% centrality interval.

THERMINATOR 2 simulation correlation function for the $\Lambda\mathrm{K^{0}_{S}}\oplus\overline{\Lambda}\mathrm{K^{0}_{S}}$ system in the 30--50\% centrality interval.

Measured correlation function for the $\Lambda\mathrm{K^{+}}\oplus\overline{\Lambda}\mathrm{K^{-}}$ system in the 0--10\% centrality interval.

Measured correlation function for the $\Lambda\mathrm{K^{-}}\oplus\overline{\Lambda}\mathrm{K^{+}}$ system in the 0--10\% centrality interval.

Measured correlation function for the $\Lambda\mathrm{K^{0}_{S}}\oplus\overline{\Lambda}\mathrm{K^{0}_{S}}$ system in the 0--10\% centrality interval.

Measured correlation function for the $\Lambda\mathrm{K^{+}}\oplus\overline{\Lambda}\mathrm{K^{-}}$ system in the 10--30\% centrality interval.

Measured correlation function for the $\Lambda\mathrm{K^{-}}\oplus\overline{\Lambda}\mathrm{K^{+}}$ system in the 10--30\% centrality interval.

Measured correlation function for the $\Lambda\mathrm{K^{0}_{S}}\oplus\overline{\Lambda}\mathrm{K^{0}_{S}}$ system in the 10--30\% centrality interval.

Measured correlation function for the $\Lambda\mathrm{K^{+}}\oplus\overline{\Lambda}\mathrm{K^{-}}$ system in the 30--50\% centrality interval.

Measured correlation function for the $\Lambda\mathrm{K^{-}}\oplus\overline{\Lambda}\mathrm{K^{+}}$ system in the 30--50\% centrality interval.

Measured correlation function for the $\Lambda\mathrm{K^{0}_{S}}\oplus\overline{\Lambda}\mathrm{K^{0}_{S}}$ system in the 30--50\% centrality interval.

Extracted imaginary and real components of the complex scattering length, $\Im f_{0}$ and $\Re f_{0}$, for the $\Lambda\mathrm{K^{0}_{S}}$ system.

Extracted imaginary and real components of the complex scattering length, $\Im f_{0}$ and $\Re f_{0}$, for the $\Lambda\mathrm{K^{-}}$ system.

Extracted imaginary and real components of the complex scattering length, $\Im f_{0}$ and $\Re f_{0}$, for the $\Lambda\mathrm{K^{+}}$ system.

Extracted effective range of the interaction, $d_{0}$, for the $\Lambda\mathrm{K^{0}_{S}}$ system.

Extracted effective range of the interaction, $d_{0}$, for the $\Lambda\mathrm{K^{-}}$ system.

Extracted effective range of the interaction, $d_{0}$, for the $\Lambda\mathrm{K^{+}}$ system.

The extracted $\lambda_{\mathrm{Fit}}$ and radius parameter for the $\Lambda$K system in the 0--10\% centrality interval.

The extracted $\lambda_{\mathrm{Fit}}$ and radius parameter for the $\Lambda$K system in the 10--30\% centrality interval.

The extracted $\lambda_{\mathrm{Fit}}$ and radius parameter for the $\Lambda$K system in the 30--50\% centrality interval.

Extracted fit $R_{\mathrm{inv}}$ parameters as a function of pair transverse mass ($m_{\mathrm{T}}$) for the $\Lambda$K system in the 0--10\% centrality interval.

Extracted fit $R_{\mathrm{inv}}$ parameters as a function of pair transverse mass ($m_{\mathrm{T}}$) for the $\Lambda$K system in the 10--30\% centrality interval.

Extracted fit $R_{\mathrm{inv}}$ parameters as a function of pair transverse mass ($m_{\mathrm{T}}$) for the $\Lambda$K system in the 30--50\% centrality interval.

Spherical harmonics component $C_{00}$ of the $\Lambda\mathrm{K^{+}}$ correlation function for the 0--10\% centrality interval.

Spherical harmonics component $\Re C_{11}$ of the $\Lambda\mathrm{K^{+}}$ correlation function for the 0--10\% centrality interval.

Correlation functions for the $\Lambda\mathrm{K^{+}}\oplus\overline{\Lambda}\mathrm{K^{-}}$ system built using the normal mixed-event reference distribution for the 0--10\% centrality interval.

Correlation functions for the $\Lambda\mathrm{K^{+}}\oplus\overline{\Lambda}\mathrm{K^{-}}$ system built using the Stavinskiy method for the 0--10\% centrality interval.

Correlation functions for the $\Lambda\mathrm{K^{+}}\oplus\overline{\Lambda}\mathrm{K^{-}}$ system built using the normal mixed-event reference distribution for the 10--30\% centrality interval.

Correlation functions for the $\Lambda\mathrm{K^{+}}\oplus\overline{\Lambda}\mathrm{K^{-}}$ system built using the Stavinskiy method for the 10--30\% centrality interval.

Correlation functions for the $\Lambda\mathrm{K^{+}}\oplus\overline{\Lambda}\mathrm{K^{-}}$ system built using the normal mixed-event reference distribution for the 30--50\% centrality interval.

Correlation functions for the $\Lambda\mathrm{K^{+}}\oplus\overline{\Lambda}\mathrm{K^{-}}$ system built using the Stavinskiy method for the 30--50\% centrality interval.

One-dimensional $\Lambda\mathrm{K^{+}}\oplus\overline{\Lambda}\mathrm{K^{-}}$ correlation function for the experimental data in the 0--10\% centrality interval.

One-dimensional $\Lambda\mathrm{K^{+}}\oplus\overline{\Lambda}\mathrm{K^{-}}$ correlation function for the THERMINATOR 2 simulation with impact parameter b = 2 fm.

$\Re C_{11}$ component of a spherical harmonic decomposition for the experimental data in the 0--10\% centrality interval.

$\Re C_{11}$ component of a spherical harmonic decomposition for the THERMINATOR 2 simulation with impact parameter b = 2 fm.

The pair source distribution from the THERMINATOR 2 simulation in the out direction.

The pair source distribution from the THERMINATOR 2 simulation in the side direction.

The pair source distribution from the THERMINATOR 2 simulation in the long direction.

The temporal characteristics of the pair source distribution from the THERMINATOR 2 simulation.

Probing the effect of varying the source shift in the outward direction, $\mu_{\mathrm{out}}$, within the THERMINATOR 2 framework. To achieve this, particle pairs are formed from the simulation, but with altered spatial characteristics achieved by drawing the out, side, and long components from predetermined Gaussian distributions. The sources in all three directions are Gaussians of width 5 fm. The distributions used for the side and long direction are centered at the origin, while the shift in the outward direction, $\mu_{\mathrm{out}}$, is varied. THERMINATOR 2 simulated correlation functions with $\mu_{\mathrm{out}} = 0$ fm.

Probing the effect of varying the source shift in the outward direction, $\mu_{\mathrm{out}}$, within the THERMINATOR 2 framework. To achieve this, particle pairs are formed from the simulation, but with altered spatial characteristics achieved by drawing the out, side, and long components from predetermined Gaussian distributions. The sources in all three directions are Gaussians of width 5 fm. The distributions used for the side and long direction are centered at the origin, while the shift in the outward direction, $\mu_{\mathrm{out}}$, is varied. THERMINATOR 2 simulated correlation functions with $\mu_{\mathrm{out}} = 1$ fm.

Probing the effect of varying the source shift in the outward direction, $\mu_{\mathrm{out}}$, within the THERMINATOR 2 framework. To achieve this, particle pairs are formed from the simulation, but with altered spatial characteristics achieved by drawing the out, side, and long components from predetermined Gaussian distributions. The sources in all three directions are Gaussians of width 5 fm. The distributions used for the side and long direction are centered at the origin, while the shift in the outward direction, $\mu_{\mathrm{out}}$, is varied. THERMINATOR 2 simulated correlation functions with $\mu_{\mathrm{out}} = 3$ fm.

Probing the effect of varying the source shift in the outward direction, $\mu_{\mathrm{out}}$, within the THERMINATOR 2 framework. To achieve this, particle pairs are formed from the simulation, but with altered spatial characteristics achieved by drawing the out, side, and long components from predetermined Gaussian distributions. The sources in all three directions are Gaussians of width 5 fm. The distributions used for the side and long direction are centered at the origin, while the shift in the outward direction, $\mu_{\mathrm{out}}$, is varied. THERMINATOR 2 simulated correlation functions with $\mu_{\mathrm{out}} = 6$ fm.

Spherical harmonics component $C_{00}$ of the $\Lambda\mathrm{K^{+}}$ correlation function for the 0--10\% centrality interval.

Spherical harmonics component $C_{00}$ of the $\Lambda\mathrm{K^{+}}$ correlation function from the THERMINATOR 2 simulation implemented with a shift $\mu_{\mathrm{out}} = 0$ fm in the outward direction.

Spherical harmonics component $C_{00}$ of the $\Lambda\mathrm{K^{+}}$ correlation function from the THERMINATOR 2 simulation implemented with a shift $\mu_{\mathrm{out}} = 1$ fm in the outward direction.

Spherical harmonics component $C_{00}$ of the $\Lambda\mathrm{K^{+}}$ correlation function from the THERMINATOR 2 simulation implemented with a shift $\mu_{\mathrm{out}} = 3$ fm in the outward direction.

Spherical harmonics component $C_{00}$ of the $\Lambda\mathrm{K^{+}}$ correlation function from the THERMINATOR 2 simulation implemented with a shift $\mu_{\mathrm{out}} = 6$ fm in the outward direction.

Spherical harmonics component $\Re C_{11}$ of the $\Lambda\mathrm{K^{+}}$ correlation function for the 0--10\% centrality interval.

Spherical harmonics component $\Re C_{11}$ of the $\Lambda\mathrm{K^{+}}$ correlation function from the THERMINATOR 2 simulation implemented with a shift $\mu_{\mathrm{out}} = 0$ fm in the outward direction.

Spherical harmonics component $\Re C_{11}$ of the $\Lambda\mathrm{K^{+}}$ correlation function from the THERMINATOR 2 simulation implemented with a shift $\mu_{\mathrm{out}} = 1$ fm in the outward direction.

Spherical harmonics component $\Re C_{11}$ of the $\Lambda\mathrm{K^{+}}$ correlation function from the THERMINATOR 2 simulation implemented with a shift $\mu_{\mathrm{out}} = 3$ fm in the outward direction.

Spherical harmonics component $\Re C_{11}$ of the $\Lambda\mathrm{K^{+}}$ correlation function from the THERMINATOR 2 simulation implemented with a shift $\mu_{\mathrm{out}} = 6$ fm in the outward direction.

Exclusion plot for the $\Lambda$-$\Lambda$ scattering parameters (1$\sigma$ contour).

Exclusion plot for the $\Lambda$-$\Lambda$ scattering parameters (2$\sigma$ contour).

Exclusion plot for the $\Lambda$-$\Lambda$ scattering parameters (3$\sigma$ contour).

Exclusion plot for the $\Lambda$-$\Lambda$ binding energy (statistical uncertainty).

Exclusion plot for the $\Lambda$-$\Lambda$ binding energy (total uncertainty).

$\lambda_{{\rm \overline{p}}{\rm \overline{p}}}+\lambda_{{\rm \overline{p}} \overline{\Lambda}}$ vs. $m_{\rm T}$ for $0-10\%$ centrality for ${\rm \overline{p}}{\rm \overline{p}}$.

$\lambda_{{\rm \overline{p}}{\rm \overline{p}}}+\lambda_{{\rm \overline{p}} \overline{\Lambda}}$ vs. $m_{\rm T}$ for $10-30\%$ centrality for ${\rm \overline{p}}{\rm \overline{p}}$.

$\lambda_{{\rm \overline{p}}{\rm \overline{p}}}+\lambda_{{\rm \overline{p}} \overline{\Lambda}}$ vs. $m_{\rm T}$ for $30-50\%$ centrality for ${\rm \overline{p}}{\rm \overline{p}}$.

$\lambda_{{\rm p}{\rm {p}}}+\lambda_{{\rm {p}}\Lambda}$ vs. $m_{\rm T}$ for $10-30\%$ centrality for ${\rm {p}}{\rm {p}}$.

$\lambda_{{\rm p}{\rm {p}}}+\lambda_{{\rm {p}}\Lambda}$ vs. $m_{\rm T}$ for $30-50\%$ centrality for ${\rm {p}}{\rm {p}}$.

$\lambda$ parameter vs. $m_{\rm T}$ for $0-10\%$ centrality for ${\rm K^{ 0}_S}{\rm K^{ 0}_S}$.

$\lambda$ parameter vs. $m_{\rm T}$ for $10-30\%$ centrality for ${\rm K^{ 0}_S}{\rm K^{ 0}_S}$.

$\lambda$ parameter vs. $m_{\rm T}$ for $30-50\%$ centrality for ${\rm K^{ 0}_S}{\rm K^{ 0}_S}$.

$\lambda$ parameter vs. $m_{\rm T}$ for $0-10\%$ centrality for ${\rm K^{\pm}}{\rm K^{\pm}}$.

$\lambda$ parameter vs. $m_{\rm T}$ for $10-30\%$ centrality for ${\rm K^{\pm}}{\rm K^{\pm}}$.

$\lambda$ parameter vs. $m_{\rm T}$ for $30-50\%$ centrality for ${\rm K^{\pm}}{\rm K^{\pm}}$.

$\lambda$ parameter vs. $m_{\rm T}$ for $0-10\%$ centrality for $\pi^{\pm}\pi^{\pm}$.

$\lambda$ parameter vs. $m_{\rm T}$ for $10-30\%$ centrality for $\pi^{\pm}\pi^{\pm}$.

$\lambda$ parameter vs. $m_{\rm T}$ for $30-50\%$ centrality for $\pi^{\pm}\pi^{\pm}$.

$R_{\rm inv}$ vs. $m_{\rm T}$ for $0-10\%$ centrality for ${\rm \overline{p}}{\rm \overline{p}}$.

$R_{\rm inv}$ vs. $m_{\rm T}$ for $10-30\%$ centrality for ${\rm \overline{p}}{\rm \overline{p}}$.

$R_{\rm inv}$ vs. $m_{\rm T}$ for $30-50\%$ centrality for ${\rm \overline{p}}{\rm \overline{p}}$.

$R_{\rm inv}$ vs. $m_{\rm T}$ for $0-10\%$ centrality for ${\rm {p}}{\rm {p}}$.

$R_{\rm inv}$ vs. $m_{\rm T}$ for $10-30\%$ centrality for ${\rm {p}}{\rm {p}}$.

$R_{\rm inv}$ vs. $m_{\rm T}$ for $30-50\%$ centrality for ${\rm {p}}{\rm {p}}$.

$R_{\rm inv}$ vs. $m_{\rm T}$ for $0-10\%$ centrality for ${\rm K^{ 0}_S}{\rm K^{ 0}_S}$.

$R_{\rm inv}$ vs. $m_{\rm T}$ for $10-30\%$ centrality for ${\rm K^{ 0}_S}{\rm K^{ 0}_S}$.

$R_{\rm inv}$ vs. $m_{\rm T}$ for $30-50\%$ centrality for ${\rm K^{ 0}_S}{\rm K^{ 0}_S}$.

$R_{\rm inv}$ vs. $m_{\rm T}$ for $0-10\%$ centrality for ${\rm K^{\pm}}{\rm K^{\pm}}$.

$R_{\rm inv}$ vs. $m_{\rm T}$ for $10-30\%$ centrality for ${\rm K^{\pm}}{\rm K^{\pm}}$.

$R_{\rm inv}$ vs. $m_{\rm T}$ for $30-50\%$ centrality for ${\rm K^{\pm}}{\rm K^{\pm}}$.

$R_{\rm inv}$ vs. $m_{\rm T}$ for $0-10\%$ centrality for $\pi^{\pm}\pi^{\pm}$.

$R_{\rm inv}$ vs. $m_{\rm T}$ for $10-30\%$ centrality for $\pi^{\pm}\pi^{\pm}$.

$R_{\rm inv}$ vs. $m_{\rm T}$ for $30-50\%$ centrality for $\pi^{\pm}\pi^{\pm}$.

Correlation function as a function of pair relative momentum for 20-40% multiplicity class and pair transverse momentum range (0.5-1.0) GeV/c.

Correlation function as a function of pair relative momentum for 40-90% multiplicity class and pair transverse momentum range (0.2-0.5) GeV/c.

Correlation function as a function of pair relative momentum for 40-90% multiplicity class and pair transverse momentum range (0.5-1.0) GeV/c.

Femtoscopic radii as a function of the pair transverse momentum.

Correlation strengths as a function of the pair transverse momentum.

The radius $r_0$ as a function of m$_T$ obtained with the p$-$p $\oplus$ $\overline{\mathrm{p}}-\overline{\mathrm{p}}$ and the p$-\Lambda$ $\oplus$ $\overline{\mathrm{p}}-\overline{\Lambda}$ correlation functions.

C2 versus qinv for mixed-charge pions in six kT intervals. 45-50% centrality.

Fit parameters from two-pion correlations. 0-5% and 45-50% centrality. EW = Edgeworth, Gauss=Gaussian.

C3 versus Q3 for same-charge pions in six centrality intervals. Low KT3.

Cummulant c3 versus Q3 for same-charge pions in six centrality intervals. Low KT3.

C3 versus Q3 for same-charge pions in six centrality intervals. High KT3.

Cummulant c3 versus Q3 for same-charge pions in six centrality intervals. High KT3.

C3 versus Q3 for mixed-charge pions in six centrality intervals. Low KT3.

Cummulant c3 versus Q3 for mixed-charge pions in six centrality intervals. Low KT3.

C3 versus Q3 for mixed-charge pions in six centrality intervals. High KT3.

Cummulant c3 versus Q3 for mixed-charge pions in six centrality intervals. High KT3.

r3 for 0-5% centrality.

r3 for 5-10% centrality.

r3 for 10-20% centrality.

r3 for 20-30% centrality.

r3 for 30-40% centrality.

r3 for 40-50% centrality.