Quenched disorder at antiferromagnetic quantum critical points in two-dimensional metals

We study spin density wave quantum critical points in two-dimensional metals with a quenched disorder potential coupling to the electron density. Adopting an E expansion around three spatial dimensions, where both disorder and the Yukawa-type interaction between electrons and bosonic order parameter fluctuations are marginal, we present a perturbative, one-loop renormalization group analysis of this problem, where the interplay between fermionic and bosonic excitations is fully incorporated. Considering two different Gaussian disorder models restricted to small-angle scattering, we show that the non-Fermi liquid fixed point of the clean spin density wave (SDW) hot spot model is generically unstable and the theory flows to strong coupling due to a mutual enhancement of interactions and disorder. We study properties of the asymptotic flow towards strong coupling, where our perturbative approach eventually breaks down. Our results indicate that disorder dominates at low energies, suggesting that the ground state in two dimensions is Anderson-localized.

Automated summary

The study focuses on spin density wave quantum critical points in two-dimensional metals with a quenched disorder potential coupling to the electron density. By using perturbative one-loop renormalization group analysis, the interaction between fermionic and bosonic excitations is fully taken into account. The results show that disorder dominates at low energies, indicating that the ground state in two dimensions is Anderson-localized.