The proceedings of the 4th Italy-Japan Symposium on Heavy Ion Physics cover the following fields of nuclear physics: heavy ion nuclear reactions; nuclei under extreme conditions; nuclear astrophysics; photon detectors and physics; technology of RI beams and experimental instrumentation; application of RI beams.
The proceedings of the 4th Italy-Japan Symposium on Heavy Ion Physics cover the following fields of nuclear physics: heavy ion nuclear reactions; nuclei under extreme conditions; nuclear astrophysics; photon detectors and physics; technology of RI beams and experimental instrumentation; application of RI beams.
These proceedings present the most recent progress made by Japanese and Italian researchers in the field of heavy ion physics. They cover both experimental and theoretical aspects from low energies (Tandem Van de Graaff accelerators) to medium energies (LINAC, Cyclotrons) up to relativistic energies (LHC at CERN).The majority of the experiments presented have been performed in the two largest Italian laboratories: LNL, Legnaro-Padova, with the Tandem + SC Linac (ALPI); LNS, Catania, with the Tandem + SC Cyclotron; and in one of the largest Japanese facilities: RIKEN, Saitama, with the Ring Cyclotron.The future Italian developments with relativistic heavy ions at LHC (CERN) are also presented, as well as experiments in collaboration with other laboratories, like JAERI, CNS (University of Tokyo), the Tandem Accelerator Center (Tsukuba), GANIL (France), and the Accelerator Laboratory in Munich, Germany.The highlights of the proceedings, and the area in which most experimental efforts are presently involved, are: research with radioactive ion beams at RIKEN with the RIPS separator; spectroscopy study at LNL with the GASP/EUROBALL 4πγ spectrometers; and intermediate energy hysics (deep inelastic, fragmentation) at LNS.Also presented are the future trends in Japan at RIKEN, RiBeam Factory, and JHP at KEK, and in Italy EXCYT at LNS and SPES at LNL. All these new developments are strongly connected with production and subsequent exploitation of radioactive ion beams, and offer a very promising, fertile future.
We expect heavy-ion collisions at very high colliding energies to produce a quark-gluon plasma (QGP) at the highest temperature obtainable in a laboratory setting. Experimental studies of these reactions can provide an unprecedented range of information on properties of the QGP at high temperatures. We also report theoretical investigations of the physics perspectives of heavy-ion collisions at a future high-energy collider. These include initial parton production, collective expansion of the dense medium, jet quenching, heavy-quark transport, dissociation and regeneration of quarkonia, photon and dilepton production. Here, we illustrate the potential of future experimental studies of the initial particle production and formation of QGP at the highest temperature to provide constraints on properties of strongly interaction matter.
This symposium was organized in order to discuss recent developments and future perspectives in intermediate-energy heavy-ion physics. The subjects included sub-barrier fusion, superheavy elements, fission; halo, skin nuclei; multi-fragmentation, collective flow, compression; properties of hot nuclei; high spin and exotic nuclear shapes; nuclear astrophysics; applications; facilities.