Abstract
AbstractThis article includes a short survey of selected averaging and dimension reduction techniques for deterministic fast–slow systems. This survey includes, among others, classical techniques, such as the WKB approximation or the averaging method, as well as modern techniques, such as the GENERIC formalism. The main part of this article combines ideas of some of these techniques and addresses the problem of deriving a reduced system for the slow degrees of freedom (DOF) of a fast–slow Hamiltonian system. In the first part, we derive an asymptotic expansion of the averaged evolution of the fast–slow system up to second order, using weak convergence techniques and two-scale convergence. In the second part, we determine quantities which can be interpreted as temperature and entropy of the system and expand these quantities up to second order, using results from the first part. The results give new insights into the thermodynamic interpretation of the fast–slow system at different scales.
Publisher
Springer Science and Business Media LLC
Subject
Mathematical Physics,Statistical and Nonlinear Physics
Reference49 articles.
1. Bender, C.M., Orszag, S.A.: Advanced Mathematical Methods for Scientists and Engineers. International Series in Pure and Applied Mathematics. McGraw-Hill Book Co., New York (1978)
2. Maslov, V.P., Fedoriuk, M.V.: Semiclassical Approximation in Quantum Mechanics. Mathematical Physics and Applied Mathematics, vol. 7. D. Reidel Publishing Co., Dordrecht-Boston (1981)
3. Schütte, C., Bornemann, F.A.: Homogenization approach to smoothed molecular dynamics. Nonlinear Anal. 30(3), 1805–1814 (1997)
4. Bornemann, F.A., Schütte, C.: Homogenization of Hamiltonian systems with a strong constraining potential. Phys. D 102(1–2), 57–77 (1997)
5. Bornemann, F.: Homogenization in Time of Singularly Perturbed Mechanical Systems. Lecture Notes in Mathematics, vol. 1687. Springer, Berlin (1998)