Schrodinger Fermi Liquids
Abstract
A class of strongly interacting many-body fermionic systems in 2+1D non-relativistic conformal field theory is examined via the gauge-gravity duality correspondence. The 5D charged black hole with asymptotic Schrodinger isometry in the bulk gravity side introduces parameters of background density and finite particle number into the boundary field theory. We propose the holographic dictionary, and realize a quantum phase transition of this fermionic liquid with fixed particle number by tuning the background density at zero temperature. On the larger side, we find the signal of a sharp quasiparticle pole on the spectral function A(k,w), indicating a well-defined Fermi surface. On the smaller side, we find only a hump with no sharp peak for A(k,w), indicating the disappearance of Fermi surface. The dynamical exponent of quasiparticle dispersion goes from being Fermi-liquid-like scaling at larger to a non-Fermi-liquid scaling at smaller . By comparing the structure of Green's function with Landau Fermi liquid theory and Senthil's scaling ansatz, we further investigate the behavior of this quantum phase transition.
Cite
@article{arxiv.1301.1986,
title = {Schrodinger Fermi Liquids},
author = {Juven Wang},
journal= {arXiv preprint arXiv:1301.1986},
year = {2014}
}
Comments
26 pages, many figures of spectral functions A(k,w). v2: add a new Fig, several clarifications, and discussions about holographic renormalization. Program code shared via a URL link in the manuscript