Quantum field theories generally exhibit divergences. Ultra-violet divergences are
treated through the renormalisation programme. Infra-red divergences, which accompany
massless particles, are a characteristic of unbroken gauge theories and make
it difficult to extract physical predictions. In this thesis we analyse various approaches
to the infra-red problem and apply them to 2+1 dimensional gauge theories. These
are useful as toy models, are related to the high temperature limit and are important
in condensed matter physics. After briefly reviewing various responses to the infra-red
problem in 3H-1 dimensions, we begin our study of gauge theories in 2+1 dimensions
by performing a one loop renormalisation of various on-shell Green's functions. Both
the fermionic and scalar theories are employed to study the spin dependence of the
infra-red structures. Ward identities are explicitly verified and gauge dependence is
analysed by calculating in different gauges. Following arguments due to Kulish and
Faddeev we see that the asymptotic interaction in QED cannot be neglected before or
after scattering. This means that, even at asymptotic times, QED has a non-trivial
gauge symmetry and so the Lagrangian fermion cannot be identified with a physical
field. We then introduce a systematic method to construct locally gauge invariant
dressed fields which describe particles moving with a well-defined velocity. We then
find that the mass shift and the wave function renormalisation constants are infra-red
finite when these dressed solutions are used. The infra-red structure of scattering is
also analysed. Finally, the Bloch-Nordsieck method is used to study the IR problem
at the level of the inclusive cross-section. It is seen that this method breaks down in
2+1 dimensions. Some suggestions for future work conclude this thesis.
Date of Award | 2003 |
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Original language | English |
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Awarding Institution | |
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INFRA-RED DIVERGENCES IN 2+1 DIMENSIONAL GAUGE THEORIES
MAZUMDER, Z. (Author). 2003
Student thesis: PhD