Physics – Condensed Matter – Other Condensed Matter
Scientific paper
2008-02-04
JETP 105, 1198 (2007) [Zh.Eksp.Teor.Fiz. 132, 1368 (2007)]
Physics
Condensed Matter
Other Condensed Matter
PDF, 11pages
Scientific paper
The 1/[-i\omega + D(\omega, q)q^2] diffusion pole in the localized phase transfers to the 1/\omega Berezinskii-Gorkov singularity, which can be analyzed by the instanton method (M V. Sadovskii, 1982; J. L. Cardy, 1978). Straightforward use of this approach leads to contradictions, which do not disappear even if the problem is extremely simplied by taking zero-dimensional limit. On the contrary, they are extremely sharpened in this case and become paradoxes. The main paradox is specified by the following statements: (i) the 1/\omega singularity is determined by high orders of perturbation theory, (ii) the high-order behaviors for two quantities \Phi^{RA} and U^{RA} are the same, and (iii) \Phi^{RA} has the 1/\omega singularity, whereas U^{RA} does not have it. Solution to the paradox indicates that the instanton method makes it possible to obtain only the 1/(\omega + i\gamma) singularity, where the parameter \gamma remains indefinite and must be determined from additional conditions. This conceptually confirms the necessity of the self-consistent treatment for the diffusion coefficient that is used in the Vollhardt-Wolfle type theories.
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