6 research outputs found
Nuclear modification factor for charged pions and protons at forward rapidity in central Au plus Au collisions at 200 GeV
We present spectra of charged pions and protons in 0–10% central Au + Au collisions at View the MathML sourcesNN=200 GeV at mid-rapidity (y=0y=0) and forward pseudorapidity (η=2.2η=2.2) measured with the BRAHMS experiment at RHIC. The spectra are compared to spectra from p+pp+p collisions at the same energy scaled by the number of binary collisions. The resulting nuclear modification factors for central Au + Au collisions at both y=0y=0 and η=2.2η=2.2 exhibit suppression for charged pions but not for (anti-) protons at intermediate pTpT. The View the MathML sourcep¯/π− ratios have been measured up to pT∼3 GeV/cpT∼3 GeV/c at the two rapidities and the results indicate that a significant fraction of the charged hadrons produced at intermediate pTpT range are (anti-) protons at both mid-rapidity and η=2.2η=2.2
Dense Nuclear Matter Equation of State from Heavy-Ion Collisions
The nuclear equation of state (EOS) is at the center of numerous theoretical
and experimental efforts in nuclear physics. With advances in microscopic
theories for nuclear interactions, the availability of experiments probing
nuclear matter under conditions not reached before, endeavors to develop
sophisticated and reliable transport simulations to interpret these
experiments, and the advent of multi-messenger astronomy, the next decade will
bring new opportunities for determining the nuclear matter EOS, elucidating its
dependence on density, temperature, and isospin asymmetry. Among controlled
terrestrial experiments, collisions of heavy nuclei at intermediate beam
energies (from a few tens of MeV/nucleon to about 25 GeV/nucleon in the
fixed-target frame) probe the widest ranges of baryon density and temperature,
enabling studies of nuclear matter from a few tenths to about 5 times the
nuclear saturation density and for temperatures from a few to well above a
hundred MeV, respectively. Collisions of neutron-rich isotopes further bring
the opportunity to probe effects due to the isospin asymmetry. However,
capitalizing on the enormous scientific effort aimed at uncovering the dense
nuclear matter EOS, both at RHIC and at FRIB as well as at other international
facilities, depends on the continued development of state-of-the-art hadronic
transport simulations. This white paper highlights the role that heavy-ion
collision experiments and hadronic transport simulations play in understanding
strong interactions in dense nuclear matter, with an emphasis on how these
efforts can be used together with microscopic approaches and neutron star
studies to uncover the nuclear EOS
Dense nuclear matter equation of state from heavy-ion collisions
International audienceThe nuclear equation of state (EOS) is at the center of numerous theoretical and experimental efforts in nuclear physics. With advances in microscopic theories for nuclear interactions, the availability of experiments probing nuclear matter under conditions not reached before, endeavors to develop sophisticated and reliable transport simulations to interpret these experiments, and the advent of multi-messenger astronomy, the next decade will bring new opportunities for determining the nuclear matter EOS, elucidating its dependence on density, temperature, and isospin asymmetry. Among controlled terrestrial experiments, collisions of heavy nuclei at intermediate beam energies (from a few tens of MeV/nucleon to about 25 GeV/nucleon in the fixed-target frame) probe the widest ranges of baryon density and temperature, enabling studies of nuclear matter from a few tenths to about 5 times the nuclear saturation density and for temperatures from a few to well above a hundred MeV, respectively. Collisions of neutron-rich isotopes further bring the opportunity to probe effects due to the isospin asymmetry. However, capitalizing on the enormous scientific effort aimed at uncovering the dense nuclear matter EOS, both at RHIC and at FRIB as well as at other international facilities, depends on the continued development of state-of-the-art hadronic transport simulations. This white paper highlights the essential role that heavy-ion collision experiments and hadronic transport simulations play in understanding strong interactions in dense nuclear matter, with an emphasis on how these efforts can be used together with microscopic approaches and neutron star studies to uncover the nuclear EOS