DFT plus U-type functional derived to explicitly address the flat plane condition

A DFT+U-type corrective functional is derived from first principles to enforce the flat plane condition on localized subspaces, thus dispensing with the need for an ad hoc derivation from the Hubbard model. Small, molecular test systems at the dissociated limit are used to compare the functional form against several previously proposed DFT+U-type functionals. The functional derived here yields relative errors below 0.6% in the total energy of the dissociated s-block dimers as well as the dissociated H+5 ring system, a challenging test case in which the asymmetric, tilted flat plane condition applies. In comparison, bare PBE and PBE+U (using Dudarev's 1998 Hubbard functional) yields relative energetic errors as high as 8.0% and 20.5%, respectively.

DFT plus U-type functional derived to explicitly address the flat plane condition

Advancing Computational Chemistry with Stochastic and Artificial Intelligence Approaches

Type-Preserving Compilation of Class-Based Languages

A recipe for cracking the quantum scaling limit with machine learned electron densities

Type-Preserving Compilation of Class-Based Languages

Advancing Computational Chemistry with Stochastic and Artificial Intelligence Approaches

A recipe for cracking the quantum scaling limit with machine learned electron densities