Dynamical susceptibility near a long-wavelength critical point with a nonconserved order parameter

Abstract

We study the dynamic response of a two-dimensional system of itinerant fermions in the vicinity of a uniform (Q=0) Ising nematic quantum critical point of d-wave symmetry. The nematic order parameter is not a conserved quantity, and this permits a nonzero value of the fermionic polarization in the d-wave channel even for vanishing momentum and finite frequency: (q = 0,m) ≠ 0. For weak coupling between the fermions and the nematic order parameter (i.e. the coupling is small compared to the Fermi energy), we perturbatively compute (q = 0,m) ≠ 0 over a parametrically broad range of frequencies where the fermionic self-energy (ω) is irrelevant, and use Eliashberg theory to compute (q = 0,m) in the non-Fermi liquid regime at smaller frequencies, where (ω) > ω. We find that (q=0,) is a constant, plus a frequency dependent correction that goes as || at high frequencies, crossing over to ||1/3 at lower frequencies. The ||1/3 scaling holds also in a non-Fermi liquid regime. The non-vanishing of (q=0, ) gives rise to additional structure in the imaginary part of the nematic susceptibility '' (q, ) at > vF q, in marked contrast to the behavior of the susceptibility for a conserved order parameter. This additional structure may be detected in Raman scattering experiments in the d-wave geometry.