| Preface |
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vii | |
| Who is addressed, and why |
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vii | |
| A necessary clarification |
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viii | |
| Acknowledgment |
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ix | |
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1 | (18) |
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Phase transitions and thermodynamics in ``Small'' Systems |
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1 | (3) |
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4 | (3) |
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Micro-canonical Thermodynamics describes non-extensive systems |
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7 | (6) |
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At phase transitions of first order the system becomes inhomogeneous |
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8 | (1) |
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Conserved quantities are the natural control parameters |
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9 | (1) |
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Micro-Canonical Thermodynamics offers a new, effective, and natural way to calculate the basic parameters of phase transitions |
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10 | (2) |
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Fragmentation a new transition in finite systems |
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12 | (1) |
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Long range forces demand the use of the micro-canonical ensemble |
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12 | (1) |
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Some realistic systems: Nuclei and atomic clusters |
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13 | (1) |
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Why Micro-Canonical Metropolis Monte Carlo and not Molecular Dynamics? |
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13 | (1) |
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The significance of the freeze-out volume. Or how can a finite decaying system become equilibrized? |
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13 | (1) |
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14 | (5) |
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The Mechanical Basis of Thermodynamics |
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19 | (16) |
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19 | (2) |
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The thermodynamic limit, the global concavity of s(e, n) |
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21 | (1) |
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Phase transitions micro-canonically |
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22 | (7) |
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Micro-canonical signals of phase transitions |
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27 | (2) |
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The interphase surface tension |
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29 | (1) |
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Second Law of Thermodynamics and Boltzmann's entropy |
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29 | (6) |
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Convex entropy --- Violation of the Second Law? |
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31 | (1) |
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The rise of Boltzman's entropy of a non-equilibrium system in contrast to the constancy of Gibbs' entropy |
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32 | (2) |
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Weinhold's geometrical interpretation of thermodynamics |
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34 | (1) |
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Micro-canonical thermodynamics of Phase Transitions studied in the Potts model |
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35 | (58) |
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35 | (1) |
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The surface tension in the Potts model. [ GEZ50] |
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36 | (9) |
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Finite-size scaling, advantage of micro-canonical compared to canonical scaling |
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40 | (1) |
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The specific heat in the micro-canonical ensemble |
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41 | (4) |
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The topology of the entropy surface S(E, N) for Potts lattice gases [ GV99] |
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45 | (21) |
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Qualitative considerations |
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45 | (1) |
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45 | (3) |
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48 | (1) |
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Diluted q = 3 Potts model |
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48 | (2) |
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50 | (1) |
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51 | (5) |
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On the topology of curvatures |
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56 | (3) |
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The order parameters of the phase transition |
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59 | (1) |
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The information lost in the grand-canonical ensemble |
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60 | (3) |
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63 | (3) |
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On the origin of isolated critical points and critical lines |
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66 | (27) |
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The Ising model with the cluster pair Approximation |
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68 | (6) |
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Micro-canonical classifications of the phase transitions |
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74 | (5) |
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Ferro-magenetic (FM) Ising model |
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79 | (4) |
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Anti-ferro magnetic (AFM) Ising model, the line of second order transition signalizes a first order transition in the non-conserved order parameter λ |
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83 | (3) |
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86 | (1) |
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Ordinary q = 3 Potts model in the plaquette approximation |
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86 | (7) |
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Liquid--gas transition and surface tension under constant pressure |
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93 | (26) |
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Andersen's constant pressure ensemble |
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93 | (1) |
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Micro-canonical ensemble with given pressure; The enthalpy |
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94 | (3) |
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Piston under constant external force II |
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95 | (2) |
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Liquid-gas transition in realistic metal systems |
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97 | (13) |
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The micro-canonical liquid-gas transition at constant pressure |
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97 | (3) |
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The liquid-gas transition of sodium, potassium, and iron [ GM00] |
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100 | (8) |
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A more realistic assumption for the treatment of the surface degree of freedom of small liquid sodium clusters |
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108 | (2) |
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Approaching the critical point |
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110 | (1) |
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The relation to the method of the Gibbs-ensemble |
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110 | (2) |
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Alternative microscopic methods to calculate the surface tension |
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112 | (1) |
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Criticism and necessary improvements of the computational method |
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113 | (1) |
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114 | (5) |
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Statistical Fragmentation under Repulsive Forces of Long Range |
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119 | (72) |
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119 | (2) |
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Three dimensional stress of long range: The Coulomb force |
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121 | (57) |
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121 | (1) |
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Which mechanism leads to equilibration? What can we learn from nuclear friction? [ GLD92] |
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121 | (2) |
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``Simulataneous'' or sequential statistical fragmentation? |
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123 | (9) |
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Phase transition towards fragmentation |
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132 | (2) |
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New experimental evidence for phase transition in nuclear evaporation data |
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134 | (7) |
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Determination of the micro heat capacity from the fluctuations of the kinetic energies of the fragments |
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141 | (2) |
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The order parameter of multifragmentation |
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143 | (1) |
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144 | (1) |
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IMF-IMF correlation functions |
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145 | (1) |
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Excitation energy dependence |
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146 | (3) |
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How to distinguish different multifragmentation modes by the shapes of the correlation function |
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149 | (1) |
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``Planetary'' and ``soup'' events |
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149 | (2) |
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Binary-multifragmentation events |
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151 | (3) |
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Summary on IMF-IMF correlations |
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154 | (2) |
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Fragmentation of multiply charged atomic clusters: |
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156 | (1) |
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156 | (2) |
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First example: Sodium clusters |
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158 | (2) |
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The microscopic - macroscopic approach: How to determine the internal level-density in the strongly enharmonic regime near the melting phase-transition? |
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160 | (2) |
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Evaporation rate and emax |
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162 | (4) |
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Phase transition to cluster fragmentation |
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166 | (2) |
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Mass and charge correlation functions |
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168 | (3) |
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Fission of doubly charged antimony clusters compared to alkali clusters |
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171 | (5) |
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Conclusions for the statistical fragmentation of hot atomic clusters |
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176 | (2) |
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Two dimensional stress of long range: Rapidly rotating hot nuclei [ BG95b] |
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178 | (8) |
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186 | (5) |
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The collapse transition in self-gravitating systems First model-studies |
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191 | (24) |
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1 - and 2 - dim. Hamiltonian Mean Field Model, a caricature of phase transitions under self-gravitation |
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192 | (11) |
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Saddle point approximation for large N |
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194 | (2) |
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196 | (1) |
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197 | (4) |
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201 | (2) |
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Collapse of non-extensive (gravitating) systems under conserved angular momentum |
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203 | (12) |
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205 | (2) |
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207 | (1) |
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The Thirring model with angular momentum |
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208 | (7) |
| Appendix A On the historical development of statistical nuclear multifragmentation models |
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215 | (6) |
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A.1 Mathematical partition vs. quantum partition |
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219 | (2) |
| Appendix B The micro-canonical ensemble of Na-clusters |
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221 | (20) |
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B.1 Micro-canonical Metropolis sampling |
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226 | (2) |
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B.2 The basic micro-canonical weights |
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228 | (10) |
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229 | (1) |
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229 | (1) |
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230 | (1) |
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231 | (1) |
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B.2.5 Sampling of the excitation energies {E*j}Nf1 and the associated weights wqd, wqt, and wqb |
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232 | (1) |
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233 | (1) |
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233 | (2) |
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B.2.8 Decomposition of IF, the weight wpl |
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235 | (3) |
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238 | (3) |
| Appendix C Some General Technical Aspects of Microcanonical Monte Carlo Simulation on a Lattice |
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241 | (8) |
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C.0.1 Direct sampling method |
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241 | (1) |
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C.0.2 Method using a grid of local patches c. f. fig. (C.1) |
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242 | (1) |
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C.0.3 Using an auxiliary weight W0(A1,..., AQ) |
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243 | (1) |
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C.0.4 Iterative improvement of the auxiliary weight W0(A1,..., AQ) |
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243 | (6) |
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C.1 Example: The diluted Potts model |
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246 | (3) |
| Bibliography |
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249 | (16) |
| Index |
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265 | |
Rohkem infot World Scientific e-raamatute kohta