Uncorrected double-differential spectra n[h−]raw/dy/dpT of negatively charged hadrons produced in the 5% Ar+Sc collisions with the smallest EPSD energy at beam momenta of 13A, 19A, 30A, 40A, 75A and 150A GeV/c

Uncorrected double-differential spectra n[h−]raw/dy/dpT of negatively charged hadrons produced in the 5% Ar+Sc collisions with the smallest EPSD energy at beam momenta of 13A, 19A, 30A, 40A, 75A and 150A GeV/c

Uncorrected double-differential spectra n[h−]raw/dy/dpT of negatively charged hadrons produced in the 5% Ar+Sc collisions with the smallest EPSD energy at beam momenta of 13A, 19A, 30A, 40A, 75A and 150A GeV/c

Uncorrected double-differential spectra n[h−]raw/dy/dpT of negatively charged hadrons produced in the 5% Ar+Sc collisions with the smallest EPSD energy at beam momenta of 13A, 19A, 30A, 40A, 75A and 150A GeV/c

Uncorrected double-differential spectra n[h−]raw/dy/dpT of negatively charged hadrons produced in the 5% Ar+Sc collisions with the smallest EPSD energy at beam momenta of 13A, 19A, 30A, 40A, 75A and 150A GeV/c

Uncorrected double-differential spectra n[h−]raw/dy/dpT of negatively charged hadrons produced in the 5% Ar+Sc collisions with the smallest EPSD energy at beam momenta of 13A, 19A, 30A, 40A, 75A and 150A GeV/c

Uncorrected double-differential spectra n[h−]raw/dy/dpT of negatively charged hadrons produced in the 5% Ar+Sc collisions with the smallest EPSD energy at beam momenta of 13A, 19A, 30A, 40A, 75A and 150A GeV/c

Uncorrected double-differential spectra n[h−]raw/dy/dpT of negatively charged hadrons produced in the 5% Ar+Sc collisions with the smallest EPSD energy at beam momenta of 13A, 19A, 30A, 40A, 75A and 150A GeV/c

Uncorrected double-differential spectra n[h−]raw/dy/dpT of negatively charged hadrons produced in the 5% Ar+Sc collisions with the smallest EPSD energy at beam momenta of 13A, 19A, 30A, 40A, 75A and 150A GeV/c

Corrected double-differential spectra d2n/dydpT of negatively charged pions produced in the 5% most central Ar+Sc collisions at beam momenta of 13A, 19A, 30A, 40A, 75A and 150A GeV/c

Corrected double-differential spectra d2n/dydpT of negatively charged pions produced in the 5% most central Ar+Sc collisions at beam momenta of 13A, 19A, 30A, 40A, 75A and 150A GeV/c

Corrected double-differential spectra d2n/dydpT of negatively charged pions produced in the 5% most central Ar+Sc collisions at beam momenta of 13A, 19A, 30A, 40A, 75A and 150A GeV/c

Corrected double-differential spectra d2n/dydpT of negatively charged pions produced in the 5% most central Ar+Sc collisions at beam momenta of 13A, 19A, 30A, 40A, 75A and 150A GeV/c

Corrected double-differential spectra d2n/dydpT of negatively charged pions produced in the 5% most central Ar+Sc collisions at beam momenta of 13A, 19A, 30A, 40A, 75A and 150A GeV/c

Corrected double-differential spectra d2n/dydpT of negatively charged pions produced in the 5% most central Ar+Sc collisions at beam momenta of 13A, 19A, 30A, 40A, 75A and 150A GeV/c

Corrected double-differential spectra d2n/dydpT of negatively charged pions produced in the 5% most central Ar+Sc collisions at beam momenta of 13A, 19A, 30A, 40A, 75A and 150A GeV/c

Corrected double-differential spectra d2n/dydpT of negatively charged pions produced in the 5% most central Ar+Sc collisions at beam momenta of 13A, 19A, 30A, 40A, 75A and 150A GeV/c

Corrected double-differential spectra d2n/dydpT of negatively charged pions produced in the 5% most central Ar+Sc collisions at beam momenta of 13A, 19A, 30A, 40A, 75A and 150A GeV/c

Corrected double-differential spectra d2n/dydpT of negatively charged pions produced in the 5% most central Ar+Sc collisions at beam momenta of 13A, 19A, 30A, 40A, 75A and 150A GeV/c

Corrected double-differential spectra d2n/dydpT of negatively charged pions produced in the 5% most central Ar+Sc collisions at beam momenta of 13A, 19A, 30A, 40A, 75A and 150A GeV/c

Corrected double-differential spectra d2n/dydpT of negatively charged pions produced in the 5% most central Ar+Sc collisions at beam momenta of 13A, 19A, 30A, 40A, 75A and 150A GeV/c

Transverse momentum distributions dn/dpT at mid-rapidity for all six beam momenta.

Transverse momentum distributions dn/dpT at mid-rapidity for all six beam momenta.

Transverse momentum distributions dn/dpT at mid-rapidity for all six beam momenta.

Transverse momentum distributions dn/dpT at mid-rapidity for all six beam momenta.

Transverse momentum distributions dn/dpT at mid-rapidity for all six beam momenta.

Transverse momentum distributions dn/dpT at mid-rapidity for all six beam momenta.

Transverse momentum distributions dn/dpT at mid-rapidity for all six beam momenta.

Transverse momentum distributions dn/dpT at mid-rapidity for all six beam momenta.

Transverse momentum distributions dn/dpT at mid-rapidity for all six beam momenta.

Transverse momentum distributions dn/dpT at mid-rapidity for all six beam momenta.

Transverse momentum distributions dn/dpT at mid-rapidity for all six beam momenta.

Transverse momentum distributions dn/dpT at mid-rapidity for all six beam momenta.

Rapidity distributions dn/dy for all six beam momenta obtained by pT integration.

Rapidity distributions dn/dy for all six beam momenta obtained by pT integration.

Rapidity distributions dn/dy for all six beam momenta obtained by pT integration.

Rapidity distributions dn/dy for all six beam momenta obtained by pT integration.

Rapidity distributions dn/dy for all six beam momenta obtained by pT integration.

Rapidity distributions dn/dy for all six beam momenta obtained by pT integration.

Rapidity distributions dn/dy for all six beam momenta obtained by pT integration.

Rapidity distributions dn/dy for all six beam momenta obtained by pT integration.

Rapidity distributions dn/dy for all six beam momenta obtained by pT integration.

Rapidity distributions dn/dy for all six beam momenta obtained by pT integration.

Rapidity distributions dn/dy for all six beam momenta obtained by pT integration.

Rapidity distributions dn/dy for all six beam momenta obtained by pT integration.

Transverse mass spectra at mid-rapidity(0 < y < 0.2).

Transverse mass spectra at mid-rapidity(0 < y < 0.2).

Transverse mass spectra at mid-rapidity(0 < y < 0.2).

Transverse mass spectra at mid-rapidity(0 < y < 0.2).

Transverse mass spectra at mid-rapidity(0 < y < 0.2).

Transverse mass spectra at mid-rapidity(0 < y < 0.2).

Transverse mass spectra at mid-rapidity(0 < y < 0.2).

Transverse mass spectra at mid-rapidity(0 < y < 0.2).

Transverse mass spectra at mid-rapidity(0 < y < 0.2).

Transverse mass spectra at mid-rapidity(0 < y < 0.2).

Transverse mass spectra at mid-rapidity(0 < y < 0.2).

Transverse mass spectra at mid-rapidity(0 < y < 0.2).

The inverse slope parameter T of the transverse mass spectra as a function of rapidity divided by the beam rapidity.

The inverse slope parameter T of the transverse mass spectra as a function of rapidity divided by the beam rapidity.

The inverse slope parameter T of the transverse mass spectra as a function of rapidity divided by the beam rapidity.

The inverse slope parameter T of the transverse mass spectra as a function of rapidity divided by the beam rapidity.

The inverse slope parameter T of the transverse mass spectra as a function of rapidity divided by the beam rapidity.

The inverse slope parameter T of the transverse mass spectra as a function of rapidity divided by the beam rapidity.

The inverse slope parameter T of the transverse mass spectra as a function of rapidity divided by the beam rapidity.

The inverse slope parameter T of the transverse mass spectra as a function of rapidity divided by the beam rapidity.

The inverse slope parameter T of the transverse mass spectra as a function of rapidity divided by the beam rapidity.

The inverse slope parameter T of the transverse mass spectra as a function of rapidity divided by the beam rapidity.

The inverse slope parameter T of the transverse mass spectra as a function of rapidity divided by the beam rapidity.

The inverse slope parameter T of the transverse mass spectra as a function of rapidity divided by the beam rapidity.

Average transverse mass <mT> − mπ at mid-rapidity(0 < y < 0.2) versus the collision energy.

Average transverse mass <mT> − mπ at mid-rapidity(0 < y < 0.2) versus the collision energy.

The speed of sound as a function of beam energy as extracted from the data.

The speed of sound as a function of beam energy as extracted from the data.

The speed of sound as a function of beam energy as extracted from the data.

The speed of sound as a function of beam energy as extracted from the data.

Forward neutron single spin asymmetries as a function of PT

Transverse momentum spectra in rapidity slices of K+ produced in the 20% most central Be+Be collisions at beam momentum 30A GeV/c (collision energy 7.62 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K+ produced in the 20% most central Be+Be collisions at beam momentum 30A GeV/c (collision energy 7.62 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using tof-dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K+ produced in the 20% most central Be+Be collisions at beam momentum 30A GeV/c (collision energy 7.62 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using tof-dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K+ produced in the 20% most central Be+Be collisions at beam momentum 40A GeV/c (collision energy 8.87 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K+ produced in the 20% most central Be+Be collisions at beam momentum 40A GeV/c (collision energy 8.87 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K+ produced in the 20% most central Be+Be collisions at beam momentum 40A GeV/c (collision energy 8.87 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using tof-dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K+ produced in the 20% most central Be+Be collisions at beam momentum 40A GeV/c (collision energy 8.87 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using tof-dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K+ produced in the 20% most central Be+Be collisions at beam momentum 75A GeV/c (collision energy 11.95 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K+ produced in the 20% most central Be+Be collisions at beam momentum 75A GeV/c (collision energy 11.95 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K+ produced in the 20% most central Be+Be collisions at beam momentum 75A GeV/c (collision energy 11.95 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using tof-dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K+ produced in the 20% most central Be+Be collisions at beam momentum 75A GeV/c (collision energy 11.95 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using tof-dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K+ produced in the 20% most central Be+Be collisions at beam momentum 150A GeV/c (collision energy 16.83 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K+ produced in the 20% most central Be+Be collisions at beam momentum 150A GeV/c (collision energy 16.83 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K+ produced in the 20% most central Be+Be collisions at beam momentum 150A GeV/c (collision energy 16.83 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using tof-dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K+ produced in the 20% most central Be+Be collisions at beam momentum 150A GeV/c (collision energy 16.83 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using tof-dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K- produced in the 20% most central Be+Be collisions at beam momentum 19A GeV/c (collision energy 6.27 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K- produced in the 20% most central Be+Be collisions at beam momentum 19A GeV/c (collision energy 6.27 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K- produced in the 20% most central Be+Be collisions at beam momentum 30A GeV/c (collision energy 7.62 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval.

Transverse momentum spectra in rapidity slices of K- produced in the 20% most central Be+Be collisions at beam momentum 30A GeV/c (collision energy 7.62 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval.

Transverse momentum spectra in rapidity slices of K- produced in the 20% most central Be+Be collisions at beam momentum 30A GeV/c (collision energy 7.62 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using tof-dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K- produced in the 20% most central Be+Be collisions at beam momentum 30A GeV/c (collision energy 7.62 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using tof-dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K- produced in the 20% most central Be+Be collisions at beam momentum 40A GeV/c (collision energy 8.87 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K- produced in the 20% most central Be+Be collisions at beam momentum 40A GeV/c (collision energy 8.87 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K- produced in the 20% most central Be+Be collisions at beam momentum 40A GeV/c (collision energy 8.87 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using tof-dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K- produced in the 20% most central Be+Be collisions at beam momentum 40A GeV/c (collision energy 8.87 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using tof-dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K- produced in the 20% most central Be+Be collisions at beam momentum 75A GeV/c (collision energy 11.95 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K- produced in the 20% most central Be+Be collisions at beam momentum 75A GeV/c (collision energy 11.95 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K- produced in the 20% most central Be+Be collisions at beam momentum 75A GeV/c (collision energy 11.95 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using tof-dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K- produced in the 20% most central Be+Be collisions at beam momentum 75A GeV/c (collision energy 11.95 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using tof-dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K- produced in the 20% most central Be+Be collisions at beam momentum 150A GeV/c (collision energy 16.83 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K- produced in the 20% most central Be+Be collisions at beam momentum 150A GeV/c (collision energy 16.83 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K- produced in the 20% most central Be+Be collisions at beam momentum 150A GeV/c (collision energy 16.83 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using tof-dE/dx analysis method.

Transverse momentum spectra in rapidity slices of K- produced in the 20% most central Be+Be collisions at beam momentum 150A GeV/c (collision energy 16.83 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using tof-dE/dx analysis method.

Transverse momentum spectra in rapidity slices of PI+ produced in the 20% most central Be+Be collisions at beam momentum 19A GeV/c (collision energy 6.27 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of PI+ produced in the 20% most central Be+Be collisions at beam momentum 19A GeV/c (collision energy 6.27 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of PI+ produced in the 20% most central Be+Be collisions at beam momentum 30A GeV/c (collision energy 7.62 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of PI+ produced in the 20% most central Be+Be collisions at beam momentum 30A GeV/c (collision energy 7.62 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of PI+ produced in the 20% most central Be+Be collisions at beam momentum 40A GeV/c (collision energy 8.87 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of PI+ produced in the 20% most central Be+Be collisions at beam momentum 40A GeV/c (collision energy 8.87 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of PI+ produced in the 20% most central Be+Be collisions at beam momentum 75A GeV/c (collision energy 11.95 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of PI+ produced in the 20% most central Be+Be collisions at beam momentum 75A GeV/c (collision energy 11.95 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of PI+ produced in the 20% most central Be+Be collisions at beam momentum 150A GeV/c (collision energy 16.83 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of PI+ produced in the 20% most central Be+Be collisions at beam momentum 150A GeV/c (collision energy 16.83 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of PI- produced in the 20% most central Be+Be collisions at beam momentum 19A GeV/c (collision energy 6.27 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of PI- produced in the 20% most central Be+Be collisions at beam momentum 19A GeV/c (collision energy 6.27 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of PI- produced in the 20% most central Be+Be collisions at beam momentum 30A GeV/c (collision energy 7.62 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of PI- produced in the 20% most central Be+Be collisions at beam momentum 30A GeV/c (collision energy 7.62 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of PI- produced in the 20% most central Be+Be collisions at beam momentum 40A GeV/c (collision energy 8.87 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of PI- produced in the 20% most central Be+Be collisions at beam momentum 40A GeV/c (collision energy 8.87 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of PI- produced in the 20% most central Be+Be collisions at beam momentum 75A GeV/c (collision energy 11.95 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of PI- produced in the 20% most central Be+Be collisions at beam momentum 75A GeV/c (collision energy 11.95 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of PI- produced in the 20% most central Be+Be collisions at beam momentum 150A GeV/c (collision energy 16.83 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of PI- produced in the 20% most central Be+Be collisions at beam momentum 150A GeV/c (collision energy 16.83 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of protons produced in the 20% most central Be+Be collisions at beam momentum 19A GeV/c (collision energy 6.27 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of protons produced in the 20% most central Be+Be collisions at beam momentum 19A GeV/c (collision energy 6.27 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of protons produced in the 20% most central Be+Be collisions at beam momentum 30A GeV/c (collision energy 7.62 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of protons produced in the 20% most central Be+Be collisions at beam momentum 30A GeV/c (collision energy 7.62 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of protons produced in the 20% most central Be+Be collisions at beam momentum 40A GeV/c (collision energy 8.87 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of protons produced in the 20% most central Be+Be collisions at beam momentum 40A GeV/c (collision energy 8.87 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of protons produced in the 20% most central Be+Be collisions at beam momentum 75A GeV/c (collision energy 11.95 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of protons produced in the 20% most central Be+Be collisions at beam momentum 75A GeV/c (collision energy 11.95 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of protons produced in the 20% most central Be+Be collisions at beam momentum 150A GeV/c (collision energy 16.83 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of protons produced in the 20% most central Be+Be collisions at beam momentum 150A GeV/c (collision energy 16.83 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of antiprotons produced in the 20% most central Be+Be collisions at beam momentum 40A GeV/c (collision energy 8.87 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of antiprotons produced in the 20% most central Be+Be collisions. Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of antiprotons produced in the 20% most central Be+Be collisions at beam momentum 75A GeV/c (collision energy 11.95 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of antiprotons produced in the 20% most central Be+Be collisions. Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of antiprotons produced in the 20% most central Be+Be collisions at beam momentum 150A GeV/c (collision energy 16.83 GeV). Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

Transverse momentum spectra in rapidity slices of antiprotons produced in the 20% most central Be+Be collisions. Rapidity values given in the legends correspond to the middle of the corresponding interval. Results presented in this table were obtained using dE/dx analysis method.

The beam momentum dependence of the inverse slope parameter of transverse momentum spectra at mid-rapidity (0<y< 0.2 for 40A GeV/c, 75A GeV/c and 150A GeV/c; -0.2<y<0.0 for 30A GeV/c) of positively charged K mesons for central 20% Be+Be collisions. Incoming beam momentum translates to collision energy (SQRT(SNN)) as following 30A GeV/c (7.62 GeV), 40AGeV/c (8.87 GeV), 75A GeV/c (11.95 GeV), 150A GeV/c (16.83 GeV).

The beam momentum dependence of the inverse slope parameter of transverse momentum spectra at mid-rapidity (0<y< 0.2 for 40A GeV/c, 75A GeV/c and 150A GeV/c; -0.2<y<0.0 for 30A GeV/c) of positively charged K mesons for central 20% Be+Be collisions. Incoming beam momentum translates to collision energy (SQRT(SNN)) as following 30A GeV/c (7.62 GeV), 40AGeV/c (8.87 GeV), 75A GeV/c (11.95 GeV), 150A GeV/c (16.83 GeV).

The energy dependence of the inverse slope parameter of transverse momentum spectra at mid-rapidity (0<y< 0.2 for 40A GeV/c, 75A GeV/c and 150A GeV/c; -0.2<y<0.0 for 30A GeV/c) of negatively charged K mesons for 20% central Be+Be collisions. Incoming beam momentum translates to collision energy (SQRT(SNN)) as following 30A GeV/c (7.62 GeV), 40AGeV/c (8.87 GeV), 75A GeV/c (11.95 GeV), 150A GeV/c (16.83 GeV).

The energy dependence of the inverse slope parameter of transverse momentum spectra at mid-rapidity (0<y< 0.2 for 40A GeV/c, 75A GeV/c and 150A GeV/c; -0.2<y<0.0 for 30A GeV/c) of negatively charged K mesons for 20% central Be+Be collisions. Incoming beam momentum translates to collision energy (SQRT(SNN)) as following 30A GeV/c (7.62 GeV), 40AGeV/c (8.87 GeV), 75A GeV/c (11.95 GeV), 150A GeV/c (16.83 GeV).

Rapidity spectra of K+ produced in the 20% most central Be+Be at beam momentum of 19A GeV/c, 30A GeV/c, 40A GeV/c 75A GeV/c and 150A GeV/c. Incoming beam momentum translates to collision energy (SQRT(SNN)) as following 19A GeV/c -> 6.27 GeV, 30A GeV/c -> 7.62 GeV, 40A GeV/c -> 8.87 GeV, 75A GeV/c -> 11.95 GeV, 150A GeV/c -> 16.83 GeV.

Rapidity spectra of K+ produced in the 20% most central Be+Be at beam momentum of 19A GeV/c, 30A GeV/c, 40A GeV/c 75A GeV/c and 150A GeV/c. Incoming beam momentum translates to collision energy (SQRT(SNN)) as following 19A GeV/c -> 6.27 GeV, 30A GeV/c -> 7.62 GeV, 40A GeV/c -> 8.87 GeV, 75A GeV/c -> 11.95 GeV, 150A GeV/c -> 16.83 GeV.

Rapidity spectra of K- produced in the 20% most central Be+Be at beam momentum of 19A GeV/c, 30A GeV/c, 40A GeV/c 75A GeV/c and 150A GeV/c. Incoming beam momentum translates to collision energy (SQRT(SNN)) as following 19A GeV/c -> 6.27 GeV, 30A GeV/c -> 7.62 GeV, 40A GeV/c -> 8.87 GeV, 75A GeV/c -> 11.95 GeV, 150A GeV/c -> 16.83 GeV.

Rapidity spectra of K- produced in the 20% most central Be+Be at beam momentum of 19A GeV/c, 30A GeV/c, 40A GeV/c 75A GeV/c and 150A GeV/c. Incoming beam momentum translates to collision energy (SQRT(SNN)) as following 19A GeV/c -> 6.27 GeV, 30A GeV/c -> 7.62 GeV, 40A GeV/c -> 8.87 GeV, 75A GeV/c -> 11.95 GeV, 150A GeV/c -> 16.83 GeV.

Rapidity spectra of PI+ produced in the 20% most central Be+Be at beam momentum of 19A GeV/c, 30A GeV/c, 40A GeV/c 75A GeV/c and 150A GeV/c. Incoming beam momentum translates to collision energy (SQRT(SNN)) as following 19A GeV/c -> 6.27 GeV, 30A GeV/c -> 7.62 GeV, 40A GeV/c -> 8.87 GeV, 75A GeV/c -> 11.95 GeV, 150A GeV/c -> 16.83 GeV.

Rapidity spectra of PI+ produced in the 20% most central Be+Be at beam momentum of 19A GeV/c, 30A GeV/c, 40A GeV/c 75A GeV/c and 150A GeV/c. Incoming beam momentum translates to collision energy (SQRT(SNN)) as following 19A GeV/c -> 6.27 GeV, 30A GeV/c -> 7.62 GeV, 40A GeV/c -> 8.87 GeV, 75A GeV/c -> 11.95 GeV, 150A GeV/c -> 16.83 GeV.

Rapidity spectra of PI- produced in the 20% most central Be+Be at beam momentum of 19A GeV/c, 30A GeV/c, 40A GeV/c 75A GeV/c and 150A GeV/c. Incoming beam momentum translates to collision energy (SQRT(SNN)) as following 19A GeV/c -> 6.27 GeV, 30A GeV/c -> 7.62 GeV, 40A GeV/c -> 8.87 GeV, 75A GeV/c -> 11.95 GeV, 150A GeV/c -> 16.83 GeV.

Rapidity spectra of PI- produced in the 20% most central Be+Be at beam momentum of 19A GeV/c, 30A GeV/c, 40A GeV/c 75A GeV/c and 150A GeV/c. Incoming beam momentum translates to collision energy (SQRT(SNN)) as following 19A GeV/c -> 6.27 GeV, 30A GeV/c -> 7.62 GeV, 40A GeV/c -> 8.87 GeV, 75A GeV/c -> 11.95 GeV, 150A GeV/c -> 16.83 GeV.

Rapidity spectra of protons produced in the 20% most central Be+Be at beam momentum of 19A GeV/c, 30A GeV/c, 40A GeV/c 75A GeV/c and 150A GeV/c. Incoming beam momentum translates to collision energy (SQRT(SNN)) as following 19A GeV/c -> 6.27 GeV, 30A GeV/c -> 7.62 GeV, 40A GeV/c -> 8.87 GeV, 75A GeV/c -> 11.95 GeV, 150A GeV/c -> 16.83 GeV.

Rapidity spectra of protons produced in the 20% most central Be+Be at beam momentum of 19A GeV/c, 30A GeV/c, 40A GeV/c 75A GeV/c and 150A GeV/c. Incoming beam momentum translates to collision energy (SQRT(SNN)) as following 19A GeV/c -> 6.27 GeV, 30A GeV/c -> 7.62 GeV, 40A GeV/c -> 8.87 GeV, 75A GeV/c -> 11.95 GeV, 150A GeV/c -> 16.83 GeV.

Rapidity spectra of antiprotons produced in the 20% most central Be+Beat beam momentum of 40A GeV/c 75A GeV/c and 150A GeV/c. Incoming beam momentum translates to collision energy (SQRT(SNN)) as following 40A GeV/c -> 8.87 GeV, 75A GeV/c -> 11.95 GeV, 150A GeV/c -> 16.83 GeV.

Rapidity spectra of antiprotons produced in the 20% most central Be+Beat beam momentum of 40A GeV/c 75A GeV/c and 150A GeV/c. Incoming beam momentum translates to collision energy (SQRT(SNN)) as following 40A GeV/c -> 8.87 GeV, 75A GeV/c -> 11.95 GeV, 150A GeV/c -> 16.83 GeV.

Collision energy dependence of mean multiplicities of K+ produced in the 20% most central Be+Be collisions.

Collision energy dependence of mean multiplicities of K+ produced in the 20% most central Be+Be collisions.

Collision energy dependence of mean multiplicities of K- produced in the 20% most central Be+Be collisions.

Collision energy dependence of mean multiplicities of K- produced in the 20% most central Be+Be collisions.

Collision energy dependence of mean multiplicities of PI+ produced in the 20% most central Be+Be collisions.

Collision energy dependence of mean multiplicities of PI+ produced in the 20% most central Be+Be collisions.

Collision energy dependence of mean multiplicities of PI- produced in the 20% most central Be+Be collisions.

Collision energy dependence of mean multiplicities of PI- produced in the 20% most central Be+Be collisions.

Collision energy dependence of mean multiplicities of antiprotons produced in the 20% most central Be+Be collisions.

Collision energy dependence of mean multiplicities of antiprotons produced in the 20% most central Be+Be collisions.

The energy dependence of the K+/PI+ particle yields ratio at mid-rapidity for the 20% most central Be+Be collisions.

The energy dependence of the K+/PI+ particle yields ratio at mid-rapidity for the 20% most central Be+Be collisions.

The energy dependence of the K+/PI+ particle yields ratio at full acceptance for the 20% most central Be+Be collisions.

The energy dependence of the K+/PI+ particle yields ratio at full acceptance for the 20% most central Be+Be collisions.

Transverse momentum spectra of PI− in rapidity slices produced in the 5% most central Be+Be collisions at 75A GeV/c.

Transverse momentum spectra of PI− in rapidity slices produced in the 5% most central Be+Be collisions at 150A GeV/c.

Transverse mass spectra 1/mT d2n/(dydmT) of negatively charged pions produced in central Be+Be collisions at the SPS energies.

Rapidity spectra of PI− produced in the 5% most central Be+Be collisions at the SPS energies.

Collision energy dependence of the ratio of the width sigma_y of the rapidity distribution to the beam rapidity y_beam for central Be+Be.

Energy dependence of the mean transverse mass of PI- measured at mid-rapidity in central Be+Be collisions.

The "kink" plot showing the ratio of pion multiplicity <PI> to number of wounded nucleons <W> versus the Fermi energy variable F=s^1/4_NN from central Be+Be collisions.

Inverse slope of mT fit of XI- and XIBAR+ produced in inelastic p+p interactions at 158 GeV/c.

The XIBAR+/Xi-ratio in inelastic p+p interactions at 158 GeV/c beam momentum.

Ratio of pT integrated yields versus rapidity of XIBAR+ and Xi- produced in inelastic p+p interactions at 158 GeV/c beam momentum.

$\pi^0$ spectra from figure 2a from 40-60% U+U collisions. Type A uncertainties are uncorrelated point-to-point. Type B uncertainties are correlated point-to-point. Type C uncertainties affect the scale of the data.

$\pi^0$ spectra from figure 2a from 60-80% U+U collisions. Type A uncertainties are uncorrelated point-to-point. Type B uncertainties are correlated point-to-point. Type C uncertainties affect the scale of the data.

$\eta$ spectra from figure 2b from minimum bias U+U collisions. Type A uncertainties are uncorrelated point-to-point. Type B uncertainties are correlated point-to-point. Type C uncertainties affect the scale of the data.

$\eta$ spectra from figure 2b from 0-20% U+U collisions. Type A uncertainties are uncorrelated point-to-point. Type B uncertainties are correlated point-to-point. Type C uncertainties affect the scale of the data.

$\eta$ spectra from figure 2b from 20-40% U+U collisions. Type A uncertainties are uncorrelated point-to-point. Type B uncertainties are correlated point-to-point. Type C uncertainties affect the scale of the data.

$\eta$ spectra from figure 2b from 40-60% U+U collisions. Type A uncertainties are uncorrelated point-to-point. Type B uncertainties are correlated point-to-point. Type C uncertainties affect the scale of the data.

$\eta$ spectra from figure 2b from 60-80% U+U collisions. Type A uncertainties are uncorrelated point-to-point. Type B uncertainties are correlated point-to-point. Type C uncertainties affect the scale of the data.

Ratio of $\pi^0$ yield to the fit from figure 2c from minimum bias U+U collisions. Sys. uncertainties include B and C uncertainties from data points.

Ratio of $\pi^0$ yield to the fit from figure 2c from 0-20% U+U collisions. Sys. uncertainties include B and C uncertainties from data points.

Ratio of $\pi^0$ yield to the fit from figure 2c from 60-80% U+U collisions. Sys. uncertainties include B and C uncertainties from data points.

Ratio of $\eta$ yield to the fit from figure 2d from minimum bias U+U collisions. Sys. uncertainties include B and C uncertainties from data points.

Ratio of $\eta$ yield to the fit from figure 2d from 0-20% U+U collisions. Sys. uncertainties include B and C uncertainties from data points.

Ratio of $\eta$ yield to the fit from figure 2d from 40-60% U+U collisions. Sys. uncertainties include B and C uncertainties from data points.

$\eta/\pi^0$ ratio from figure 3 from minimum bias U+U collisions. Type A uncertainties are uncorrelated point-to-point. Type B uncertainties are correlated point-to-point.

$\eta/\pi^0$ ratio from figure 3 from 0-20% U+U collisions. Type A uncertainties are uncorrelated point-to-point. Type B uncertainties are correlated point-to-point.

$\eta/\pi^0$ ratio from figure 3 from 20-40% U+U collisions. Type A uncertainties are uncorrelated point-to-point. Type B uncertainties are correlated point-to-point.

$\eta/\pi^0$ ratio from figure 3 from 40-60% U+U collisions. Type A uncertainties are uncorrelated point-to-point. Type B uncertainties are correlated point-to-point.

$\eta/\pi^0$ ratio from figure 3 from 60-80% U+U collisions. Type A uncertainties are uncorrelated point-to-point. Type B uncertainties are correlated point-to-point.

$\eta/\pi^0$ ratio from figure 3 from minimum bias Au+Au collisions. Type A uncertainties are uncorrelated point-to-point. Type B uncertainties are correlated point-to-point.

$\pi^0$ $R_{AA}$ from figure 4a from 0-20% U+U collisions. Type A uncertainties are uncorrelated point-to-point. Type B uncertainties are correlated point-to-point. Type C uncertainties affect the scale of the data. Calculation is carried out for Glauber 1 set.

$\eta$ $R_{AA}$ from figure 4a from 0-20% U+U collisions. Type A uncertainties are uncorrelated point-to-point. Type B uncertainties are correlated point-to-point. Type C uncertainties affect the scale of the data. Calculation is carried out for Glauber 1 set.

$\pi^0$ $R_{AA}$ from figure 4b from 20-40% U+U collisions. Type A uncertainties are uncorrelated point-to-point. Type B uncertainties are correlated point-to-point. Type C uncertainties affect the scale of the data. Calculation is carried out for Glauber 1 set.

$\eta$ $R_{AA}$ from figure 4b from 20-40% U+U collisions. Type A uncertainties are uncorrelated point-to-point. Type B uncertainties are correlated point-to-point. Type C uncertainties affect the scale of the data. Calculation is carried out for Glauber 1 set.

$\pi^0$ $R_{AA}$ from figure 4c from 40-60% U+U collisions. Type A uncertainties are uncorrelated point-to-point. Type B uncertainties are correlated point-to-point. Type C uncertainties affect the scale of the data. Calculation is carried out for Glauber 1 set.

$\eta$ $R_{AA}$ from figure 4c from 40-60% U+U collisions. Type A uncertainties are uncorrelated point-to-point. Type B uncertainties are correlated point-to-point. Type C uncertainties affect the scale of the data. Calculation is carried out for Glauber 1 set.

$\pi^0$ $R_{AA}$ from figure 4d from minimum bias U+U collisions. Type A uncertainties are uncorrelated point-to-point. Type B uncertainties are correlated point-to-point. Type C uncertainties affect the scale of the data. Calculation is carried out for Glauber 1 set.

$\eta$ $R_{AA}$ from figure 4d from minimum bias U+U collisions. Type A uncertainties are uncorrelated point-to-point. Type B uncertainties are correlated point-to-point. Type C uncertainties affect the scale of the data. Calculation is carried out for Glauber 1 set.

$\pi^0$ $R_{AA}$ from figure 5a from 0-20% U+U collisions. Type A uncertainties are uncorrelated point-to-point. Type B uncertainties are correlated point-to-point. Type C uncertainties affect the scale of the data. Calculation is carried out for Glauber 2 set.

$\pi^0$ $R_{AA}$ from figure 5a from 0-5% Au+Au collisions. Type A uncertainties are uncorrelated point-to-point. Type B uncertainties are correlated point-to-point. Type C uncertainties affect the scale of the data.

$\pi^0$ $R_{AA}$ from figure 5a from 40-60% U+U collisions. Type A uncertainties are uncorrelated point-to-point. Type B uncertainties are correlated point-to-point. Type C uncertainties affect the scale of the data. Calculation is carried out for Glauber 2 set.

$\pi^0$ $R_{AA}$ from figure 5a from 40-50% Au+Au collisions. Type A uncertainties are uncorrelated point-to-point. Type B uncertainties are correlated point-to-point. Type C uncertainties affect the scale of the data.

$\pi^0$ integrated $R_{AA}$ for $p_T>5$ GeV/$c$ in U+U collisions as a function of centrality from figure 6a. Type A uncertainties are uncorrelated point-to-point. Type B uncertainties are correlated point-to-point. Type C uncertainties affect the scale of the data. Calculation is carried out for Glauber 1 set.

$\eta$ integrated $R_{AA}$ for $p_T>5$ GeV/$c$ in U+U collisions as a function of centrality from figure 6a. Type A uncertainties are uncorrelated point-to-point. Type B uncertainties are correlated point-to-point. Type C uncertainties affect the scale of the data. Calculation is carried out for Glauber 1 set.

$\pi^0$ integrated $R_{AA}$ for $p_T>5$ GeV/$c$ in Au+Au collisions as a function of centrality from figure 6a. Type A uncertainties are uncorrelated point-to-point. Type B uncertainties are correlated point-to-point. Type C uncertainties affect the scale of the data.

$\eta$ integrated $R_{AA}$ for $p_T>5$ GeV/$c$ in U+U collisions as a function of centrality from figure 6b. Type A uncertainties are uncorrelated point-to-point. Type B uncertainties are correlated point-to-point. Type C uncertainties affect the scale of the data. Calculation is carried out for Glauber 2 set.

Number of participant nucleons of in dep U$+$U collisions

Number of participant nucleons of in dep U$+$U collisions

Number of participant nucleons of in dep Au$+$Au collisions

$\lambda_{\phi}$ measured in $J/\psi$ transverse momentum bins of 0.0 < $p_T$ < 3.0 GeV/$c$ and 3.0 < $p_T$ < 10.0 GeV/$c$ overlaid with NRQCD predictions in the Helicity and Collins-Soper frames.

$\lambda_{\theta \phi}$ measured in $J/\psi$ transverse momentum bins of 0.0 < $p_T$ < 3.0 GeV/$c$ and 3.0 < $p_T$ < 10.0 GeV/$c$ overlaid with NRQCD predictions in the Helicity and Collins-Soper frames.

$\lambda_{\theta \phi}$ measured in $J/\psi$ transverse momentum bins of 0.0 < $p_T$ < 3.0 GeV/$c$ and 3.0 < $p_T$ < 10.0 GeV/$c$ overlaid with NRQCD predictions in the Helicity and Collins-Soper frames.

$\bar{\lambda}$ measured in $J/\psi$ transverse momentum bins of 0.0 < $p_T$ < 3.0 GeV/$c$ and 3.0 < $p_T$ < 10.0 GeV/$c$ overlaid with CSM and NRQCD predictions in the Helicity frame.

$\bar{\lambda}$ measured in $J/\psi$ transverse momentum bins of 0.0 < $p_T$ < 3.0 GeV/$c$ and 3.0 < $p_T$ < 10.0 GeV/$c$ overlaid with CSM and NRQCD predictions in the Helicity frame.

Invariant $F$ measured in $J/\psi$ transverse momentum bins of 0.0 < $p_T$ < 3.0 GeV/$c$ and 3.0 < $p_T$ < 10.0 GeV/$c$ overlaid with CSM and NRQCD predictions in the Helicity frame.

Invariant $F$ measured in $J/\psi$ transverse momentum bins of 0.0 < $p_T$ < 3.0 GeV/$c$ and 3.0 < $p_T$ < 10.0 GeV/$c$ overlaid with CSM and NRQCD predictions in the Helicity frame.