Thermodynamics, Statistical Physics, and Quantum Mechanics

(Axel Boer) #1

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4.65.

OttoCycle(Stony Brook)
JouleCycle(Stony Brook)
DieselCycle (StonyBrook)
Modified Joule–Thomson (Boston)
Ideal Gasand ClassicalStatistics
PoissonDistribution inIdeal Gas (Colorado)
Polarization of Ideal Gas (Moscow Phys-Tech)
Two-Dipole Interaction (Princeton)
Entropy ofIdeal Gas (Princeton)
Chemical Potential of Ideal Gas (Stony Brook)
Gas in Harmonic Well(Boston)
Ideal Gas in One-Dimensional Potential(Rutgers)
Equipartition Theorem (Columbia, Boston)
Diatomic Molecules in Two Dimensions(Columbia)
Diatomic Molecules in Three Dimensions(Stony Brook,
Michigan State)
Two-Level System (Princeton)
Zipper(Boston)
Hanging Chain (Boston)
Molecular Chain (MIT, Princeton, Colorado)
Nonideal Gas
Heat Capacities (Princeton)
Return ofHeat Capacities(Michigan)
Nonideal Gas Expansion (Michigan State)
van der Waals (MIT)
Critical Parameters (Stony Brook)
Mixtures andPhase Separation
Entropy of Mixing(Michigan, MIT)
Leaky Balloon (Moscow Phys-Tech)
Osmotic Pressure (MIT)
Clausius–Clapeyron(Stony Brook)
Phase Transition (MIT)
Hydrogen Sublimation in IntergalacticSpace(Princeton)
Gas Mixture Condensation (Moscow Phys-Tech)
Air Bubble Coalescence (Moscow Phys-Tech)
Soap Bubble Coalescence (Moscow Phys-Tech)
Soap Bubbles in Equilibrium(Moscow Phys-Tech)
QuantumStatistics
Fermi Energy of a 1D Electron Gas(Wisconsin-Madison)
Two-Dimensional Fermi Gas(MIT, Wisconson-Madison)
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