Derivative Discontinuity in Many-Body Perturbation Theory and Chemical Potentials in Random Phase Approximation
Abstract
We derive analytical expressions for chemical potentials within the random phase approximation (RPA), equivalently the GW energy functional evaluated using non interacting Green's functions (Gs). The chemical potential is obtained using two formally equivalent approaches: a direct derivative of the total energy with respect to particle number, and a functional derivative via the chain rule through Gs, both validated with finite difference benchmarks. We show that the functional derivative of the GW correlation energyx2013i.e., the GW correlation self energyx2013exhibits a discontinuity at integer particle numbers with finite jumps. This resolves the apparent inconsistency between accurate GW quasiparticle energies and the large delocalization errors observed in RPA total energies, as standard GW self energies neglect this nonanalytic behavior. Our results suggest that derivative discontinuities are a fundamental feature of correlation energy functionals, analogous to the known discontinuity in the exact exchange correlation energy.
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