A GW-based many-body approach to electrical conductivity in warm dense matter yields lower DC conductivity for beryllium at low temperatures from improved transition energies and at high temperatures from electron-electron scattering.
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Kohn-Sham eigenvalues equal quasiparticle bands up to a frozen-core renormalization z_core derived from effective field theory, resolving the long-standing ARPES bandwidth discrepancy in metals.
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Capturing many-body effects in electrical conductivity of warm dense matter
A GW-based many-body approach to electrical conductivity in warm dense matter yields lower DC conductivity for beryllium at low temperatures from improved transition energies and at high temperatures from electron-electron scattering.
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Kohn-Sham Hamiltonian from Effective Field Theory: Quasiparticle Band Narrowing from Frozen Core Dynamics
Kohn-Sham eigenvalues equal quasiparticle bands up to a frozen-core renormalization z_core derived from effective field theory, resolving the long-standing ARPES bandwidth discrepancy in metals.