Numerical approaches for calculating the low-field dc Hall coefficient of the doped Hubbard model

Abstract

Using determinant Quantum Monte Carlo, we compare three methods of evaluating the dc Hall coefficient RH of the Hubbard model: the direct measurement of the off-diagonal current-current correlator xy in a system coupled to a finite magnetic field (FF), xyFF; the three-current linear response to an infinitesimal field as measured in the zero-field (ZF) Hubbard Hamiltonian, xyZF; and the leading order of the recurrent expansion RH(0) in terms of thermodynamic susceptibilities. The two quantities xyFF and xyZF can be compared directly in imaginary time. Proxies for RH constructed from the three-current correlator xyZF can be determined under different simplifying assumptions and compared with RH(0). We find these different quantities to be consistent with one another, validating previous conclusions about the close correspondence between Fermi surface topology and the sign of RH, even for strongly correlated systems. These various quantities also provide a useful set of numerical tools for testing theoretical predictions about the full behavior of the Hall conductivity for strong correlations.