Hostname: page-component-84b7d79bbc-c654p Total loading time: 0 Render date: 2024-07-26T17:33:39.975Z Has data issue: false hasContentIssue false
  • English
  • Français

Thermal relaxation of light dilute particles in a heat bath: a model problem

Published online by Cambridge University Press:  13 March 2009

A. J. M. Garrett
A. J. M. Garrett
Affiliation:
Cavendish Laboratory, University of Cambridge
Get access Rights & Permissions [Opens in a new window]

Abstract

The relaxation of a very dilute test particle species undergoing elastic collisions with a distinct, thermally distributed second particle species is considered. The Boltzmann equation is set up for the component of the test particle distribution function isotropic in velocity space; external forces and spatial dependence are ignored. For small test particle: heat-bath particle mass ratio, collisions are adequately described by a differential operator that is second-or der with respect to collision speed, which depends on the functional form of the collision frequency in terms of speed. The evolution equation is transformed to the form of the time-dependent Schrödinger equation, and the equivalent Schrödinger potential evaluated in terms of the collision frequency-speed relation. The relaxation problem may be solved by specifying the Green's propagator, describing the relaxation of an initial monoenergetic distribution. The case of constant Schrödinger potential is studied: the corresponding form of the collision frequency is found by an inversion process, and the evolution equation studied in Schrödinger form. The transformed speed variable has a finite range as particle speeds vary from 0 to ∞, and it is necessary to specify that particles are not lost at the finite values corresponding to small and large speeds. The Green's propagator is continued beyond this physical range, rather as in the ‘method of images’ of electrostatics. The particle conservation requirements induce a Laplace transform problem for the initial value of the Green's propagator, which is reduced to a polynomial recurrence relation and solved by finding the generating function. The Green's propagator is itself propagated forward from its initial value by a ‘primitive’ propagator which is the solution of the problem for initial delta function not only in the physical range, but anywhere in the space of the transformed variable. This primitive propagator is readily found, and the propagation quadrature performed to yield the true propagator in terms of parabolic cylinder functions. A check is made with a special case, for which relaxation to thermal form is explicitly demonstrated. Differences and similarities between this analysis and those corresponding to more general collision frequencies and potentials are considered.

Type
Research Article
Information
Journal of Plasma Physics , Volume 36 , Issue 2 , October 1986 , pp. 151 - 187
Copyright
Copyright © Cambridge University Press 1986

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

Arsac, A., Basquin, L., Denisse, -J.-F., Delcroix, J.-L. & Salmon, J. 1958 J. Phys. Rad. 19, 624.Google Scholar
Bayet, M., Delcroix, J.-L. & Denisse, J.-F. 1956 J. Phys. Rad. 17, 923.CrossRefGoogle Scholar
Braglia, G. L. & Ferrari, L. 1970 Nuovo Cimento, 67 B, 167.CrossRefGoogle Scholar
Braglia, G. L., Caraffini, G. L. & Diligenti, M. 1981 Nuovo Cimento, 62 B, 139.CrossRefGoogle Scholar
Chapman, S. & Cowling, T. G. 1939 (1st Ed.); 1970 (3rd. Ed.). The Mathematical Theory of Non-Uniform Gases. Cambridge University Press.Google Scholar
Eastham, M. S. P. & Kalf, H. 1982 Schrödinger Type Operators with Continuous Spectra. Pitman.Google Scholar
Garrett, A. J. M. 1982 a J. Plasma Phys. 27, 135.CrossRefGoogle Scholar
Garrett, A. J. M. 1982 b J. Plasma Phys. 28, 233.CrossRefGoogle Scholar
Garrett, A. J. M. 1986 Phys. Rep. 134, 195.Google Scholar
Oser, H., Shuler, K. E. & Weiss, G. H. 1964 J. Chem. Phys. 41, 2661.Google Scholar
Titchmarsh, E. C. 1962 Eigenfunction Expansions (Part 1). Oxford University Press.Google Scholar