On the Theory of the Brownian Motion
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概要
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The Brownian motion of an oscillator in a thermostat is considered assuming simple forms of interaction between them. No further assumption is made except that the thermostat is always in thermal equilibrium in itself. Solving the Liouville equation or its counterpart in quantum mechanics the long time evolution of the system is clarified. Thus the theory connects automatically the irreversible and the equilibrium behaviors of the system without any ad hoc assumption as in conventional theories. The results include, as a special case, the equation derived by Kramers and Chandrasekhar using the theory of stochastic processes. It is shown that the oscillating part of the distribution function or the density matrix plays an important role to which the peculiar way of damping of the oscillator is to be attributed.
- 社団法人日本物理学会の論文
- 1958-11-05
著者
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Toda Morikazu
Department Of Applied Mathematics Yokohama National University
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TODA Morikazu
Department of Physics, Tokyo University of Education
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- Preface
- Preface
- Damping Behavior and Space Dimensions (Part II. Time Dependent Problems)
- Statistical Dynamics of Systems of Interacting Oscillators (Part II. Time Dependent Problems)
- Diffusion on the Fermi Surface
- One-Dimensional Dual Transformation
- Wave Propagation in Anharmonic Lattices
- On the Theory of the Brownian Motion
- On the Theory of Quantum Liquids. I. Surface TenSion and Stress