Fidelity susceptibility and general quench near an anisotropic quantum critical point

Abstract

We study the scaling behavior of fidelity susceptibility density ( f) at or close to an anisotropic quantum critical point characterized by two different correlation length exponents || and along parallel and perpendicular spatial directions, respectively. Our studies show that the response of the system due to a small change in the Hamiltonian near an anisotropic quantum critical point is different from that seen near an isotropic quantum critical point. In particular, for a finite system with linear dimension L|| (L) in the parallel (perpendicular) directions, the maximum value of f is found to increases in a power-law fashion with L|| for small L||, with an exponent depending on both || and and eventually crosses over to a scaling with L for L||1/|| L1/. We also propose scaling relations of heat density and defect density generated following a quench starting from an anisotropic quantum critical point and connect them to a generalized fidelity susceptibility. These predictions are verified exactly both analytically and numerically taking the example of a Hamiltonian showing a semi-Dirac band-crossing point.