NSR Query Results
Output year order : Descending NSR database version of May 3, 2024. Search: Author = A.J.Santiago Found 13 matches. 2001CH12 Eur.Phys.J. A 10, 27 (2001) K.C.Chung, C.S.Wang, A.J.Santiago, J.W.Zhang Effective Nucleon-Nucleon Interactions and Nuclear Matter Equation of State
doi: 10.1007/s100500170141
2001CH53 Eur.Phys.J. A 11, 137 (2001) K.C.Chung, C.S.Wang, A.J.Santiago, J.W.Zhang Nuclear Matter Properties in Relativistic Mean-Field Model with σ-ω Coupling
doi: 10.1007/s100500170078
2001CH83 Eur.Phys.J. A 12, 161 (2001) K.C.Chung, C.S.Wang, A.J.Santiago, J.W.Zhang Determination of Nonlinear σ-ω-ρ Model Parameters in the Relativistic Mean-Field Theory by Nuclear-Matter Properties
doi: 10.1007/s100500170024
2000CH08 Phys.Rev. C61, 047303 (2000) K.C.Chung, C.S.Wang, A.J.Santiago, J.W.Zhang Nuclear Matter Equation of State Based on Effective Nucleon-Nucleon Interactions
doi: 10.1103/PhysRevC.61.047303
2000CH52 Eur.Phys.J. A 9, 453 (2000) K.C.Chung, C.S.Wang, A.J.Santiago, J.W.Zhang Nuclear Matter Properties and Relativistic Mean-Field Theory
doi: 10.1007/s100500070003
1999CH02 Phys.Rev. C59, 714 (1999) K.C.Chung, C.S.Wang, A.J.Santiago Nuclear Incompressibility Determined by Nuclear Mass and Monopole Resonance Energy
doi: 10.1103/PhysRevC.59.714
1999CH40 Europhys.Lett. 47, 663 (1999) K.C.Chung, C.S.Wang, A.J.Santiago Nuclear Matter Properties from Nuclear Masses
doi: 10.1209/epl/i1999-00440-4
1999WA18 Phys.Rev. C60, 034310 (1999) C.S.Wang, K.C.Chung, A.J.Santiago Systematics of Nuclear Central Densities NUCLEAR STRUCTURE A=1-208; analyzed electron scattering, muonic atom data; deduced nuclear central densities, mass and asymmetry dependence.
doi: 10.1103/PhysRevC.60.034310
1998CH07 Phys.Rev. C57, 847 (1998) K.C.Chung, C.S.Wang, A.J.Santiago, G.Pech Transverse and Forward Energy Distributions in Ultrarelativistic Heavy Collisions by an Absorption Model NUCLEAR REACTIONS Ag, Cu(16O, X), E=60 GeV/nucleon; Pb(208Pb, X), E=158 GeV/nucleon; 197Au(16O, X), E=60, 200 GeV/nucleon; S, Cu, Ag, 197Au(32S, X), E=200 GeV/nucleon; analyzed transverse, forward energy distributions; deduced parameters. Absorption model.
doi: 10.1103/PhysRevC.57.847
1997SA27 Phys.Scr. 55, 152 (1997) A.J.Santiago, K.C.Chung, C.S.Wang Nuclear Fragmentation in Nucleus-Nucleus Reaction Within a Two-Lattices Percolation Picture NUCLEAR REACTIONS 36Ar, Cu, 129Xe, 197Au(197Au, X), E not given; analyzed fragmentation data. Two-lattice percolation model.
doi: 10.1088/0031-8949/55/2/006
1997WA15 Phys.Rev. C55, 2844 (1997) C.S.Wang, K.C.Chung, A.J.Santiago Thomas-Fermi Theory of the Breathing Mode and Nuclear Incompressibiility NUCLEAR STRUCTURE 16O, 40Ca, 58Ni, 90Zr, 112Sn, 140Ce, 208Pb; calculated isoscalar giant monopole resonance energy; deduced contributions of Coulomb energy, nucleon density gradient to nuclear incompressibility. Thomas-Fermi theory, linear scaling.
doi: 10.1103/PhysRevC.55.2844
1996SA21 Prog.Theor.Phys.(Kyoto) 95, 97 (1996) Percolation and Nucleation Approaches to Nuclear Fragmentation - Criticality in Very Small Systems - NUCLEAR REACTIONS 45Sc(40Ar, X), E=65 MeV/nucleon; 129Xe(197Au, X), E not given; analyzed data; deduced nonuniqueness of criticality criterion. Percolation, nucleation models.
doi: 10.1143/PTP.95.97
1993SA12 J.Phys.(London) G19, 349 (1993) Do Percolative Simulations of Nuclear Fragmentation Depend on the Lattice Structure ( Question ) NUCLEAR REACTIONS Kr, Xe(p, X), E not given; calculated fragment spectra for X=16O, 12C; deduced lattice structure role in percolative simulations.
doi: 10.1088/0954-3899/19/2/017
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