Journal of Experimental and Theoretical Physics
HOME | SEARCH | AUTHORS | HELP      
Journal Issues
Golden Pages
About This journal
Aims and Scope
Editorial Board
Manuscript Submission
Guidelines for Authors
Manuscript Status
Contacts


ZhETF, Vol. 128, No. 1, p. 211 (July 2005)
(English translation - JETP, Vol. 101, No. 1, p. 186, July 2005 available online at www.springer.com )

THE TUBE CHARACTER OF ELECTRON DRIFT IN CONDENSED INERT GASES
Gordon E.B., Smirnov B.M.

Received: February 11, 2005

PACS: 34.80.-i, 52.80.Wq, 52.80.Yr, 79.20.Kz

DJVU (128.3K) PDF (289.1K)

The behavior of an excess electron in condensed inert gases in an external electric field is considered at densities and temperatures at which the mobility of a slow electron is relatively high. On the basis of experimental data and a model of a pair electron interaction with atoms, an effective potential energy surface is constructed for an excess electron inside a dense inert gas. The region available for a slow electron consists of many intersecting channels that form a Delone network located between atoms. A drifting electron, as a quantum object, propagates along these channels (tubes), and electron transition between intersecting potential energy tubes of different directions provides an effective electron scattering. This mechanism of electron drift and scattering differs from that in gases and crystals. Peculiarities of electron drift inside dense inert gases are analyzed within the framework of this mechanism of electron scattering, leading to a moderate change of the electron mobility upon melting.

 
Report problems