Linear scaling computation of the Fock matrix VII. Periodic Density Functional Theory at the -point

Abstract

Linear scaling quantum chemical methods for Density Functional Theory are extended to the condensed phase at the -point. For the two-electron Coulomb matrix, this is achieved with a tree-code algorithm for fast Coulomb summation [J. Chem. Phys. 106, 5526 (1997)], together with multipole representation of the crystal field [J. Chem. Phys. 107, 10131 (1997)]. A periodic version of the hierarchical cubature algorithm [J. Chem. Phys. 113, 10037 (2000)], which builds a telescoping adaptive grid for numerical integration of the exchange-correlation matrix, is shown to be efficient when the problem is posed as integration over the unit cell. Commonalities between the Coulomb and exchange-correlation algorithms are discussed, with an emphasis on achieving linear scaling through the use of modern data structures. With these developments, convergence of the -point supercell approximation to the k-space integration limit is demonstrated for MgO and NaCl. Linear scaling construction of the Fockian and control of error is demonstrated for RBLYP/6-21G* diamond up to 512 atoms.

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