Fermion loops and improved power-counting in two-dimensional critical metals 
with singular forward scattering

Holder, T.; Metzner, W.

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Fermion loops and improved power-counting in two-dimensional critical metals with singular forward scattering

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Metzner, W.
Department Quantum Many-Body Theory (Walter Metzner), Max Planck Institute for Solid State Research, Max Planck Society;

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Holder, T., & Metzner, W. (2015). Fermion loops and improved power-counting in two-dimensional critical metals with singular forward scattering. Physical Review B, 92(24): 245128.

Cite as: https://hdl.handle.net/21.11116/0000-000E-CD56-B

Abstract

We analyze general properties of the perturbation expansion for two-dimensional quantum critical metals with singular forward scattering, such as metals at an Ising nematic quantum critical point and metals coupled to a U(1) gauge field. We derive asymptotic properties of fermion loops appearing as subdiagrams of the contributing Feynman diagrams-for large and small momenta. Substantial cancellations are found in important scaling limits, which reduce the degree of divergence of Feynman diagrams with boson legs. Implementing these cancellations, we obtain improved power-counting estimates that yield the true degree of divergence. In particular, we find that perturbative contributions to the boson self-energy are generally ultraviolet convergent for a dynamical critical exponent z < 3, and divergent beyond three-loop order for z >= 3.