Stability of Relativistic Matter With Magnetic Fields

C. Fefferman; C. Fefferman; D. Evans; E. H. Lieb; E. H. Lieb; E. H. Lieb; E. H. Lieb; E. H. Lieb; E. H. Lieb; E. H. Lieb; E. H. Lieb; Elliott H. Lieb; F. J. Dyson; G. E. Brown; Heinz Siedentop; I. Herbst; J. Avron; J. Fröhlich; J. G. Conlon; Jan Philip Solovej; L. Bugliaro; M. Loss; M. S. Birman; T. Kato

research

Stability of Relativistic Matter With Magnetic Fields

Authors: C. Fefferman
C. Fefferman
D. Evans
E. H. Lieb
E. H. Lieb
E. H. Lieb
E. H. Lieb
E. H. Lieb
E. H. Lieb
E. H. Lieb
E. H. Lieb
Elliott H. Lieb
F. J. Dyson
G. E. Brown
Heinz Siedentop
I. Herbst
J. Avron
J. Fröhlich
J. G. Conlon
Jan Philip Solovej
L. Bugliaro
M. Loss
M. S. Birman
T. Kato
Publication date: 1 January 1997
Publisher: 'American Physical Society (APS)'
Doi

Abstract

Stability of matter with Coulomb forces has been proved for non-relativistic dynamics, including arbitrarily large magnetic fields, and for relativistic dynamics without magnetic fields. In both cases stability requires that the fine structure constant alpha be not too large. It was unclear what would happen for both relativistic dynamics and magnetic fields, or even how to formulate the problem clearly. We show that the use of the Dirac operator allows both effects, provided the filled negative energy `sea' is defined properly. The use of the free Dirac operator to define the negative levels leads to catastrophe for any alpha, but the use of the Dirac operator with magnetic field leads to stability.Comment: This is an announcement of the work in cond-mat/9610195 (LaTeX

Similar works

Full text

Available Versions

Copenhagen University Research Information System

oai:pure.atira.dk:publications...

Last time updated on 18/12/2019

Crossref

Last time updated on 26/03/2019