Negative Heat Capacity for a Cluster of 147 Sodium Atoms
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Generalized replica exchange methodGeneralized simulated tempering for exploring strong phase transitions.Extended canonical Monte Carlo methods: Improving accuracy of microcanonical calculations using a reweighting technique.Neural network potentials for dynamics and thermodynamics of gold nanoparticles.Correlation between the variation in observed melting temperatures and structural motifs of the global minima of gallium clusters: an ab initio study.Tsallis power laws and finite baths with negative heat capacity.Roles of dynamical symmetry breaking in driving oblate-prolate transitions of atomic clusters.Accurate evaporation rates of pure and doped water clusters in vacuum: A statistico-dynamical approach.Isomeric transitions in size-selected methanol hexamers probed by OH-stretch spectroscopy.Eigenstate-specific temperatures in two-level paramagnetic spin lattices.Nucleation and superstabilization in small systems.Microcanonical analysis of association of hydrophobic segments in a heteropolymer.Cumulant expansion and analytic continuation in Monte Carlo simulation of classical Lennard-Jones clusters.Logarithmic oscillators: ideal Hamiltonian thermostats.Instability of the mean-field states and generalization of phase separation in long-range interacting systems.Quantum densities of states of fluxional polyatomic systems from a superposition approximation.Microcanonical quantum fluctuation theorems.Efficient parallel tempering for first-order phase transitions.Enhanced sampling via strong coupling to a heat bath: relationship between Tsallis and multicanonical algorithms.Generalized canonical ensembles and ensemble equivalence.Molecular-dynamics simulation of argon nucleation from supersaturated vapor in the NVE ensemble.Transient backbending behavior in the Ising model with fixed magnetization.Structural transitions in clusters.Long-range interacting systems in the unconstrained ensemble.The microcanonical thermodynamics of finite systems: the microscopic origin of condensation and phase separations, and the conditions for heat flow from lower to higher temperatures.Nanoparticles: Neither solid nor liquid.Electronic structures, equilibrium geometries, and finite-temperature properties ofNan(n=39–55)from first principles
P2860
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P2860
Negative Heat Capacity for a Cluster of 147 Sodium Atoms
description
2001 nî lūn-bûn
@nan
2001 թուականի Փետրուարին հրատարակուած գիտական յօդուած
@hyw
2001 թվականի փետրվարին հրատարակված գիտական հոդված
@hy
2001年の論文
@ja
2001年論文
@yue
2001年論文
@zh-hant
2001年論文
@zh-hk
2001年論文
@zh-mo
2001年論文
@zh-tw
2001年论文
@wuu
name
Negative Heat Capacity for a Cluster of 147 Sodium Atoms
@ast
Negative Heat Capacity for a Cluster of 147 Sodium Atoms
@en
Negative Heat Capacity for a Cluster of 147 Sodium Atoms
@nl
type
label
Negative Heat Capacity for a Cluster of 147 Sodium Atoms
@ast
Negative Heat Capacity for a Cluster of 147 Sodium Atoms
@en
Negative Heat Capacity for a Cluster of 147 Sodium Atoms
@nl
altLabel
Negative heat capacity for a cluster of 147 sodium atoms
@en
prefLabel
Negative Heat Capacity for a Cluster of 147 Sodium Atoms
@ast
Negative Heat Capacity for a Cluster of 147 Sodium Atoms
@en
Negative Heat Capacity for a Cluster of 147 Sodium Atoms
@nl
P2093
P1476
Negative Heat Capacity for a Cluster of 147 Sodium Atoms
@en
P2093
Bernd von Issendorff
Hellmut Haberland
Jörn Donges
Martin Schmidt
Robert Kusche
Thomas Hippler
Werner Kronmüller
P2860
P304
P356
10.1103/PHYSREVLETT.86.1191
P407
P577
2001-02-01T00:00:00Z
2001-02-12T00:00:00Z