The Pauli exclusion principle at strong coupling: Holographic matter and momentum space

Abstract

For free fermions at finite density, the Pauli exclusion principle is responsible for the existence of a Fermi surface and the consequent presence of low energy spectral weight over a finite range of momenta. We investigate the extent to which this effect occurs in strongly interacting quantum matter with a holographic dual. We obtain the low energy current-current spectral weight in two holographic frameworks at finite density: systems exhibiting semi-local quantum criticality (with a low temperature entropy density vanishing like s ~ Teta), and a probe D3/D5 system. For the semi-local theory with 0 < eta < 2 we find a sharp discontinuity in the transverse spectral weight at a nonzero momentum k*. The case eta = 1 is found to have additional symmetries and is soluble even at nonzero temperature. We show that this case exhibits a robust linear in temperature resistivity in the presence of random charged impurities. For the probe D3/D5 system we find an analytic expression for the low energy spectral weight as a function of momentum. The spectral weight is supported below a specific momentum k* and is exponentially suppressed at higher momenta.