The local potential approximation of the renormalization group
The local potential approximation of the renormalization group
We introduce Wilson's, or Polchinski's, exact renormalization group, and review the Local Potential Approximation as applied to scalar field theory. Focusing on the Polchinski flow equation, standard methods are investigated, and by choosing restrictions to some sub-manifold of coupling constant space we arrive at a very promising variational approximation method. Within the Local Potential Approximation, we construct a function, C, of the coupling constants; it has the property that (for unitary theories) it decreases monotonically along flows and is stationary only at fixed points - where it 'counts degrees of freedom', i.e. is extensive, counting one for each Gaussian scalar.
In the latter part of the thesis, the Local Potential Approximation is used to derive a non-trivial Polchinski flow equation to include Fermi fields. Our flow equation does not support chirally invariant solutions and does not reproduce the features associated with the corresponding invariant theories. We solve both for a finite number of components, N, and within the large N limit. The Legendre flow equation provides a comparison with exact results in the large N limit. In this limit, it is solved to yield both chirally invariant and non-invariant solutions.
University of Southampton
Harvey-Fros, Christopher Simon Francis
1999
Harvey-Fros, Christopher Simon Francis
Harvey-Fros, Christopher Simon Francis
(1999)
The local potential approximation of the renormalization group.
University of Southampton, Doctoral Thesis.
Record type:
Thesis
(Doctoral)
Abstract
We introduce Wilson's, or Polchinski's, exact renormalization group, and review the Local Potential Approximation as applied to scalar field theory. Focusing on the Polchinski flow equation, standard methods are investigated, and by choosing restrictions to some sub-manifold of coupling constant space we arrive at a very promising variational approximation method. Within the Local Potential Approximation, we construct a function, C, of the coupling constants; it has the property that (for unitary theories) it decreases monotonically along flows and is stationary only at fixed points - where it 'counts degrees of freedom', i.e. is extensive, counting one for each Gaussian scalar.
In the latter part of the thesis, the Local Potential Approximation is used to derive a non-trivial Polchinski flow equation to include Fermi fields. Our flow equation does not support chirally invariant solutions and does not reproduce the features associated with the corresponding invariant theories. We solve both for a finite number of components, N, and within the large N limit. The Legendre flow equation provides a comparison with exact results in the large N limit. In this limit, it is solved to yield both chirally invariant and non-invariant solutions.
This record has no associated files available for download.
More information
Published date: 1999
Identifiers
Local EPrints ID: 463590
URI: http://eprints.soton.ac.uk/id/eprint/463590
PURE UUID: d2c09fdb-be85-4443-8189-8fdc49eb0f45
Catalogue record
Date deposited: 04 Jul 2022 20:54
Last modified: 04 Jul 2022 20:54
Export record
Contributors
Author:
Christopher Simon Francis Harvey-Fros
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics