Eugene Trubowitz scite author profile

The perturbation expansion for a general class of many-fermion systems with a non-nested, non-spherical Fermi surface is renormalized to all orders. In the limit as the infrared cutoff is removed, the counterterms converge to a finite limit which is differentiable in the band structure. The map from the renormalized to the bare band structure is shown to be locally injective. A new classification of graphs as overlapping or non-overlapping is given, and improved power counting bounds are derived from it. They imply that the only subgraphs that can generate r factorials in the r th order of the renormalized perturbation series are indeed the ladder graphs and thus give a precise sense to the statement that 'ladders are the most divergent diagrams'. Our results apply directly to the Hubbard model at any filling except for half-filling. The half-filled Hubbard model is treated in another place.

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The inverse problem for periodic potentials

Trubowitz¹

1977

Comm Pure Appl Math

229

126

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Inverse scattering and the boussinesq equation

Deift¹,

Tomei²,

Trubowitz³

1982

Comm Pure Appl Math

183

126

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