NSR Query Results
Output year order : Descending NSR database version of May 3, 2024. Search: Author = J.B.Elliott Found 33 matches. 2013EL02 Phys.Rev. C 87, 054622 (2013) J.B.Elliott, P.T.Lake, L.G.Moretto, L.Phair Determination of the coexistence curve, critical temperature, density, and pressure of bulk nuclear matter from fragment emission data
doi: 10.1103/PhysRevC.87.054622
2012MO22 Phys.Rev. C 86, 021303 (2012) L.G.Moretto, P.T.Lake, L.Phair, J.B.Elliott Reexamination and extension of the liquid drop model: Correlation between liquid drop parameters and curvature term ATOMIC MASSES A=15-280; analyzed relationship between the volume and the surface energy coefficients in the liquid drop model; deduced residual masses as a function of mass number from the fits, curvature term in the liquid drop expansion. Possible generalization of the Wigner term.
doi: 10.1103/PhysRevC.86.021303
2008MO04 Phys.Rev. C 77, 037603 (2008) L.G.Moretto, C.O.Dorso, J.B.Elliott, L.Phair Symmetry entropy and isoscaling
doi: 10.1103/PhysRevC.77.037603
2006MO30 Europhys.Lett. 76, 402 (2006) L.G.Moretto, K.A.Bugaev, J.B.Elliott, L.Phair The Hagedorn thermostat
doi: 10.1209/epl/i2006-10280-8
2005EL02 Phys.Rev. C 71, 024607 (2005) J.B.Elliott, L.G.Moretto, L.Phair Saturated vapor properties and scaling in the lattice gas model
doi: 10.1103/PhysRevC.71.024607
2005MO15 Phys.Rev.Lett. 94, 202701 (2005) L.G.Moretto, K.A.Bugaev, J.B.Elliott, R.Ghetti, J.Helgesson, L.Phair The Complement: A Solution to Liquid Drop Finite Size Effects in Phase Transitions
doi: 10.1103/PhysRevLett.94.202701
2005MO42 Phys.Rev. C 72, 064605 (2005) L.G.Moretto, J.B.Elliott, L.Phair Compound nuclear decay and the liquid-vapor phase transition: A physical picture NUCLEAR REACTIONS 12C(64Ni, X), E=6-13 MeV/nucleon; analyzed fragment yields; deduced phase transition features, related parameters. Fisher droplet model.
doi: 10.1103/PhysRevC.72.064605
2004MO23 Prog.Part.Nucl.Phys. 53, 101 (2004) L.G.Moretto, J.B.Elliott, L.Phair From finite charged nuclei to infinite symmetric nuclear matter and its phase diagram
doi: 10.1016/j.ppnp.2004.02.030
2003EL01 Phys.Rev. C 67, 024609 (2003) J.B.Elliott, L.G.Moretto, L.Phair, G.J.Wozniak, S.Albergo, F.Bieser, F.P.Brady, Z.Caccia, D.A.Cebra, A.D.Chacon, J.L.Chance, Y.Choi, S.Costa, M.L.Gilkes, J.A.Hauger, A.S.Hirsch, E.L.Hjort, A.Insolia, M.Justice, D.Keane, J.C.Kintner, V.Lindenstruth, M.A.Lisa, H.S.Matis, M.McMahan, C.McParland, W.F.J.Muller, D.L.Olson, M.D.Partlan, N.T.Porile, R.Potenza, G.Rai, J.Rasmussen, H.G.Ritter, J.Romanski, J.L.Romero, G.V.Russo, H.Sann, R.P.Scharenberg, A.Scott, Y.Shao, B.K.Srivastava, T.J.M.Symons, M.Tincknell, C.Tuve, S.Wang, P.Warren, H.H.Wieman, T.Wienold, K.Wolf Constructing the phase diagram of finite neutral nuclear matter NUCLEAR REACTIONS C(197Au, X), (La, X), (Kr, X), E=1.0 GeV/nucleon; analyzed fragment charge and mass yields; deduced parameters. Fisher's droplet model, characteristics of neutral nuclear matter discussed.
doi: 10.1103/PhysRevC.67.024609
2003MA90 Phys.Rev. C 68, 064601 (2003) C.M.Mader, A.Chappars, J.B.Elliott, L.G.Moretto, L.Phair, G.J.Wozniak The three-dimensional Ising model and its Fisher analysis: a Paradigm of liquid-vapor coexistence in nuclear multifragmentation
doi: 10.1103/PhysRevC.68.064601
2003MO40 Phys.Rev. C 68, 061602 (2003) L.G.Moretto, J.B.Elliott, L.Phair Resistible effects of Coulomb interaction on nucleus-vapor phase coexistence
doi: 10.1103/PhysRevC.68.061602
2002EL02 Phys.Rev.Lett. 88, 042701 (2002) J.B.Elliott, L.G.Moretto, L.Phair, G.J.Wozniak, L.Beaulieu, H.Breuer, R.G.Korteling, K.Kwiatkowski, T.Lefort, L.Pienkowski, A.Ruangma, V.E.Viola, S.J.Yennello, and the ISiS Collaboration Liquid to Vapor Phase Transition in Excited Nuclei NUCLEAR REACTIONS 197Au(π-, X), E at 8 GeV/c; analyzed fragment charge distributions, mass yields, related data; deduced phase transition features. Fisher's model scaling.
doi: 10.1103/PhysRevLett.88.042701
2002MO32 Phys.Rev. C66, 041601 (2002); Comment Phys.Rev. C 69, 069801 (2004) L.G.Moretto, J.B.Elliott, L.Phair, G.J.Wozniak Negative heat capacities and first order phase transitions in nuclei
doi: 10.1103/PhysRevC.66.041601
2001MO04 Nucl.Phys. A681, 239c (2001) L.G.Moretto, J.B.Elliott, L.Phair, G.J.Wozniak Nuclear Multifragmentation Along the Liquid-Vapor Univariant Equilibrium Line and Beyond
doi: 10.1016/S0375-9474(00)00524-8
2000EL05 Phys.Rev. C61, 054605 (2000) Standard Thermodynamic Quantities as Determined via Models of Nuclear Multifragmentation
doi: 10.1103/PhysRevC.61.054605
2000EL09 Phys.Rev.Lett. 85, 1194 (2000) J.B.Elliott, L.G.Moretto, L.Phair, G.J.Wozniak, S.Albergo, F.Bieser, F.P.Brady, Z.Caccia, D.A.Cebra, A.D.Chacon, J.L.Chance, Y.Choi, S.Costa, M.L.Gilkes, J.A.Hauger, A.S.Hirsch, E.L.Hjort, A.Insolia, M.Justice, D.Keane, J.C.Kintner, V.Lindenstruth, M.A.Lisa, H.S.Matis, M.McMahan, C.McParland, W.F.J.Muller, D.L.Olson, M.D.Partlan, N.T.Porile, R.Potenza, G.Rai, J.Rasmussen, H.G.Ritter, J.Romanski, J.L.Romero, G.V.Russo, H.Sann, R.P.Scharenberg, A.Scott, Y.Shao, B.K.Srivastava, T.J.M.Symons, M.Tincknell, C.Tuve, S.Wang, P.G.Warren, H.H.Wieman, T.Wienold, K.Wolf Nuclear Multifragmentation, Percolation, and the Fisher Droplet Model: Common features of reducibility and thermal scaling NUCLEAR REACTIONS C(197Au, X), E=high; analyzed Au fragmentation data; deduced parameters of droplet and percolation models of nuclear multifragmentation.
doi: 10.1103/PhysRevLett.85.1194
2000EL12 Phys.Rev. C62, 064603 (2000) J.B.Elliott, and the EOS Collaboration Statistical Signatures of Critical Behavior in Small Systems NUCLEAR REACTIONS C(197Au, X), E= 1 GeV/nucleon; analyzed fragments charge and mass distributions, cluster distributions; deduced continuous phase transition features, statistical signatures. Fisher droplet model.
doi: 10.1103/PhysRevC.62.064603
1999SR03 Phys.Rev. C60, 064606 (1999) B.K.Srivastava, S.Albergo, F.Bieser, F.P.Brady, Z.Caccia, D.A.Cebra, A.D.Chacon, J.L.Chance, Y.Choi, S.Costa, P.Danielewicz, J.B.Elliott, M.L.Gilkes, J.A.Hauger, A.S.Hirsch, E.L.Hjort, A.Insolia, M.Justice, D.Keane, J.C.Kintner, V.Lindenstruth, M.A.Lisa, H.S.Matis, M.McMahan, C.McParland, W.F.J.Muller, D.L.Olson, M.D.Partlan, N.T.Porile, R.Potenza, G.Rai, J.Rasmussen, H.G.Ritter, J.Romanski, J.L.Romero, G.V.Russo, H.Sann, R.P.Scharenberg, A.Scott, Y.Shao, T.J.M.Symons, M.Tincknell, C.Tuve, S.Wang, P.Warren, H.H.Wieman, T.Wienold, K.Wolf, and the EOS Collaboration Comparison of the 1A GeV 197Au + C Interaction with First-Stage Transport Codes NUCLEAR REACTIONS C(197Au, X), E=1 GeV/nucleon; measured light, intermediate fragments mass, energy distributions. Comparisons with intranuclear cascade and BUU transport calculations.
doi: 10.1103/PhysRevC.60.064606
1998EL05 Phys.Lett. 418B, 34 (1998) J.B.Elliott, and the EOS Collaboration The Search for the Scaling Function in the Multifragmentation of Gold Nuclei NUCLEAR REACTIONS C(197Au, X), E=1 GeV/nucleon; analyzed fragments charge, energy distributions; deduced scaling function, thermodynamic behaviour.
doi: 10.1016/S0370-2693(97)01403-2
1997EL01 Phys.Rev. C55, 544 (1997) J.B.Elliott, J.A.Hauger, A.S.Hirsch, E.L.Hjort, N.T.Porile, R.Scharenberg, B.K.Srivastava, M.Tincknell, P.Warren Comment on ' Pre-Equilibrium Particle Emission and Critical Exponent Analysis ' NUCLEAR REACTIONS C(197Au, X), E=1 GeV/nucleon; analyzed model analyses; deduced analysis validity related features. Intranuclear cascade-percolation calculation.
doi: 10.1103/PhysRevC.55.544
1997EL03 Phys.Rev. C55, 1319 (1997) J.B.Elliott, M.L.Gilkes, J.A.Hauger, A.S.Hirsch, E.Hjort, N.T.Porile, R.P.Scharenberg, B.K.Srivastava, M.L.Tincknell, P.G.Warren Scaling Behavior in Very Small Percolation Lattices
doi: 10.1103/PhysRevC.55.1319
1997HJ01 Phys.Rev.Lett. 79, 4345 (1997) E.L.Hjort, S.Albergo, F.Bieser, F.P.Brady, Z.Caccia, D.A.Cebra, A.D.Chacon, J.L.Chance, Y.Choi, S.Costa, J.B.Elliott, M.L.Gilkes, J.A.Hauger, A.S.Hirsch, A.Insolia, M.Justice, D.Keane, J.C.Kintner, M.A.Lisa, H.S.Matis, M.McMahan, C.McParland, D.L.Olson, M.D.Partlan, N.T.Porile, R.Potenza, G.Rai, J.Rasmussen, H.G.Ritter, J.Romanski, J.L.Romero, G.V.Russo, R.P.Scharenberg, A.Scott, Y.Shao, B.K.Srivastava, T.J.M.Symons, M.Tincknell, C.Tuve, S.Wang, P.G.Warren, H.H.Wieman, T.Wienold, K.Wolf Δ Resonance Production in 58Ni + Cu Collisions at E = 1.97A GeV NUCLEAR REACTIONS Cu(58Ni, X), E=1.97 GeV/nucleon; measured invariant mass spectra associated with π±, π--absorption on proton; deduced Δ resonance mass shift.
doi: 10.1103/PhysRevLett.79.4345
1997KI07 Phys.Rev.Lett. 78, 4165 (1997) J.C.Kintner, S.Albergo, F.Bieser, F.P.Brady, Z.Caccia, D.Cebra, A.D.Chacon, J.L.Chance, Y.Choi, S.Costa, J.B.Elliott, M.L.Gilkes, J.A.Hauger, A.S.Hirsch, E.L.Hjort, A.Insolia, M.Justice, D.Keane, M.A.Lisa, H.S.Matis, M.McMahan, C.McParland, D.L.Olson, M.D.Partlan, N.T.Porile, R.Potenza, G.Rai, J.Rasmussen, H.G.Ritter, J.Romanski, J.L.Romero, G.V.Russo, R.Scharenberg, A.Scott, Y.Shao, B.Srivastava, T.J.M.Symons, M.Tincknell, C.Tuve, S.Wang, P.Warren, H.H.Wieman, T.Wienold, K.Wolf Pion Flow and Antiflow in 1.15A GeV Au + Au NUCLEAR REACTIONS 197Au(197Au, X), E=1.15 GeV/nucleon; measured pion transverse flow vs impact parameter; deduced antiflow behavior for π+, π-.
doi: 10.1103/PhysRevLett.78.4165
1996EL06 Phys.Lett. 381B, 35 (1996) J.B.Elliott, and the EOS Collaboration Individual Fragment Yields and Determination of the Critical Exponent σ NUCLEAR REACTIONS C(197Au, X), E=1 GeV/nucleon; measured fragment yield vs total charge multiplicity; deduced liquid-gas value consistent critical exponent.
doi: 10.1016/0370-2693(96)00590-4
1996HA19 Phys.Rev.Lett. 77, 235 (1996) J.A.Hauger, S.Albergo, F.Bieser, F.P.Brady, Z.Caccia, D.A.Cebra, A.D.Chacon, J.L.Chance, Y.Choi, S.Costa, J.B.Elliott, M.L.Gilkes, A.S.Hirsch, E.L.Hjort, A.Insolia, M.Justice, D.Keane, J.C.Kintner, V.Lindenstruth, M.A.Lisa, U.Lynen, H.S.Matis, M.McMahan, C.McParland, W.F.J.Muller, D.L.Olson, M.D.Partlan, N.T.Porile, R.Potenza, G.Rai, J.Rasmussen, H.G.Ritter, J.Romanski, J.L.Romero, G.V.Russo, H.Sann, R.Scharenberg, A.Scott, Y.Shao, B.K.Srivastava, T.J.M.Symons, M.Tincknell, C.Tuve, S.Wang, P.Warren, H.H.Wieman, T.Wienold, K.Wolf, and the EOS Collaboration Dynamics of the Multifragmentation of 1A GeV Gold on Carbon NUCLEAR REACTIONS Cu(197Au, X), E=1 GeV/nucleon; analyzed multi-fragmentation dynamics; deduced prompt, equilibrated remnant decay stages.
doi: 10.1103/PhysRevLett.77.235
1996WA17 Phys.Rev.Lett. 76, 3911 (1996) S.Wang, M.A.Lisa, S.Albergo, F.Bieser, F.P.Brady, Z.Caccia, D.A.Cebra, A.D.Chacon, J.L.Chance, Y.Choi, S.Costa, J.B.Elliott, M.L.Gilkes, J.A.Hauger, A.S.Hirsch, E.L.Hjort, A.Insolia, M.Justice, D.Keane, J.Kintner, V.Lindenstruth, H.Liu, H.S.Matis, M.McMahan, C.McParland, D.L.Olson, M.D.Partlan, N.T.Porile, R.Potenza, G.Rai, J.Rasmussen, H.G.Ritter, J.Romanski, J.L.Romero, G.V.Russo, R.P.Scharenberg, A.Scott, Y.Shao, B.K.Srivastava, T.J.M.Symons, M.L.Tincknell, C.Tuve, P.G.Warren, D.Weerasundara, H.H.Wieman, K.L.Wolf, and the EOS Collaboration In-Plane Retardation of Collective Expansion in Au + Au Collisions NUCLEAR REACTIONS 197Au(197Au, X), E=600 MeV/nucleon; measured light fragments transverse mass spectra, other features; deduced collective expansion in-plane retardation related features.
doi: 10.1103/PhysRevLett.76.3911
1995LI41 Phys.Rev.Lett. 75, 2662 (1995) M.A.Lisa, S.Albergo, F.Bieser, F.P.Brady, Z.Caccia, D.A.Cebra, A.D.Chacon, J.L.Chance, Y.Choi, S.Costa, J.B.Elliott, M.L.Gilkes, J.A.Hauger, A.S.Hirsch, E.L.Hjort, A.Insolia, M.Justice, D.Keane, J.Kintner, H.S.Matis, M.McMahan, C.McParland, D.L.Olson, M.D.Partlan, N.T.Porile, R.Potenza, G.Rai, J.Rasmussen, H.G.Ritter, J.Romanski, J.L.Romero, G.V.Russo, R.Scharenberg, A.Scott, Y.Shao, B.K.Srivastava, T.J.M.Symons, M.Tincknell, C.Tuve, S.Wang, P.Warren, G.D.Westfall, H.H.Wieman, K.Wolf, and the EOS Collaboration Radial Flow in Au + Au Collisions at E = (0.25-1.15)A GeV NUCLEAR REACTIONS 197Au(197Au, X), E=0.25-1.15 GeV/nucleon; measured light fragment energy spectra at midrapidity; deduced temperature, radial flow parameters. Quantum molecular dynamics, BUU models analysis.
doi: 10.1103/PhysRevLett.75.2662
1995PA39 Phys.Rev.Lett. 75, 2100 (1995) M.D.Partlan, S.Albergo, F.Bieser, F.P.Brady, Z.Caccia, D.Cebra, A.D.Chacon, J.Chance, Y.Choi, S.Costa, J.B.Elliott, M.L.Gilkes, J.A.Hauger, A.S.Hirsch, E.L.Hjort, A.Insolia, M.Justice, D.Keane, J.Kintner, M.A.Lisa, H.S.Matis, M.McMahan, C.McParland, D.L.Olson, G.Peilert, N.T.Porile, R.Potenza, G.Rai, J.Rasmussen, H.G.Ritter, J.Romanski, J.L.Romero, G.V.Russo, R.P.Scharenberg, A.Scott, Y.Shao, B.K.Srivastava, T.J.M.Symons, M.L.Tincknell, C.Tuve, S.Wang, P.G.Warren, H.H.Wieman, K.Wolf, and the EOS Collaboration Fragment Flow in Au + Au Collisions NUCLEAR REACTIONS 197Au(197Au, X), E=0.25-1.15 GeV/nucleon; measured light fragment associated averaged collective flow; deduced 'soft' or 'hard' equation of state inadequacy.
doi: 10.1103/PhysRevLett.75.2100
1995RI02 Nucl.Phys. A583, 491c (1995) H.G.Ritter, S.Albergo, F.Bieser, F.P.Brady, Z.Caccia, D.A.Cebra, A.D.Chacon, J.L.Chance, Y.Choi, S.Costa, J.B.Elliott, M.L.Gilkes, J.A.Hauger, A.S.Hirsch, E.L.Hjort, A.Insolia, M.Justice, D.Keane, J.Kintner, V.Lindenstruth, M.A.Lisa, U.Lynen, H.S.Matis, M.McMahan, C.McParland, W.F.J.Mueller, D.L.Olson, M.D.Partlan, N.T.Porile, R.Potenza, G.Rai, J.Rasmussen, J.Romanski, J.L.Romero, G.V.Russo, H.Sann, R.P.Scharenberg, A.Scott, Y.Shao, B.K.Srivastava, T.J.M.Symons, M.L.Tincknell, C.Tuve, S.Wang, P.G.Warren, H.H.Wieman, K.L.Wolf, and the EOS Collaboration Flow and Multifragmentation in Nuclear Collisions at Intermediate Energies NUCLEAR REACTIONS 197Au(197Au, X), E=0.25-1.15 GeV/nucleon; measured light fragment σ(θ, E); deduced radially expanding thermal source properties.
doi: 10.1016/0375-9474(94)00710-5
1995WA11 Phys.Rev.Lett. 74, 2646 (1995) S.Wang, S.Albergo, F.Bieser, F.P.Brady, Z.Caccia, D.A.Cebra, A.D.Chacon, J.L.Chance, Y.Choi, S.Costa, J.B.Elliott, M.L.Gilkes, J.A.Hauger, A.S.Hirsch, E.L.Hjort, A.Insolia, M.Justice, D.Keane, J.Kintner, M.A.Lisa, H.S.Matis, M.McMahan, C.McParland, D.L.Olson, M.D.Partlan, N.T.Porile, R.Potenza, G.Rai, J.Rasmussen, H.G.Ritter, J.Romanski, J.L.Romero, G.V.Russo, R.P.Scharenberg, A.Scott, Y.Shao, B.K.Srivastava, T.J.M.Symons, M.L.Tincknell, C.Tuve, P.G.Warren, D.Weerasundara, H.H.Wieman, K.L.Wolf, and the EOS Collaboration Light Fragment Production and Power Law Behavior in Au + Au Collisions NUCLEAR REACTIONS 197Au(197Au, X), E=1.15 GeV/nucleon; measured momentum space light charged particle densities vs rapidity, multiplicity, beam energy; deduced momentum-space coalescence evidence.
doi: 10.1103/PhysRevLett.74.2646
1994EL06 Phys.Rev. C49, 3185 (1994) J.B.Elliott, M.L.Gilkes, J.A.Hauger, A.S.Hirsch, E.Hjort, N.T.Porile, R.P.Scharenberg, B.K.Srivastava, M.L.Tincknell, P.G.Warren Extraction of Critical Exponents from Very Small Percolation Lattices
doi: 10.1103/PhysRevC.49.3185
1994GI10 Phys.Rev.Lett. 73, 1590 (1994) M.L.Gilkes, S.Albergo, F.Bieser, F.P.Brady, Z.Caccia, D.A.Cebra, A.D.Chacon, J.L.Chance, Y.Choi, S.Costa, J.B.Elliott, J.A.Hauger, A.S.Hirsch, E.L.Hjort, A.Insolia, M.Justice, D.Keane, J.C.Kintner, V.Lindenstruth, M.A.Lisa, U.Lynen, H.S.Matis, M.McMahan, C.McParland, W.F.J.Muller, D.L.Olson, M.D.Partlan, N.T.Porile, R.Potenza, G.Rai, J.Rasmussen, H.G.Ritter, J.Romanski, J.L.Romero, G.V.Russo, H.Sann, R.Scharenberg, A.Scott, Y.Shao, B.K.Srivastava, T.J.M.Symons, M.Tincknell, C.Tuve, S.Wang, P.Warren, H.H.Wieman, K.Wolf, and the EOS Collaboration Determination of Critical Exponents from the Multifragmentation of Gold Nuclei NUCLEAR REACTIONS C(197Au, X), E=1 GeV/nucleon; measured charged fragment distribution; deduced critical exponents value.
doi: 10.1103/PhysRevLett.73.1590
1991KO26 Nucl.Phys. A535, 637 (1991) E.Korkmaz, J.Li, D.A.Hutcheon, R.Abegg, J.B.Elliott, L.G.Greeniaus, D.J.Mack, C.A.Miller, N.L.Rodning Measurements of NN → dπ Very Near Threshold (II). The pp → dπ+ Analyzing Power NUCLEAR REACTIONS 1H(polarized p, π+), E=290.7, 294.7 MeV; measured analyzing power vs E(θ(π)). Liquid hydrogen target.
doi: 10.1016/0375-9474(91)90480-T
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