Crossed pseudopotential$-$functional calculations made simple: An extended Kohn-Sham framework

Modern density-functional-theory (DFT) calculations rely heavily on pseudopotentials, yet their impact on accuracy is barely addressed. In this work, we derive from the Kohn-Sham equation that the use of pseudopotentials invariably introduces a ``dropping" error, which leads to a deviation from the Hohenberg-Kohn theorem. Crossed pseudopotential-functional calculations provide a pragmatic way to balance accuracy and efficiency, enabling the right results for the right reasons. This paradigm goes beyond the (generalized) Kohn-Sham framework, which we name the extended Kohn-Sham framework. We support our assertion with a bandgap study on 54 monovalent-Cu semiconductors. The crossed calculations, compared to consistent ones, not only remove all 11 erroneous metal predictions, but also drastically reduce the mean relative error from 80\% to 20\%. The accuracy even exceeds that of the hybrid functionals and GW due to the role of pseudopotentials in modelling the external potentials of Cu-valence electrons that cannot be compensated by exchange-correlation.