SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2017882766> ?p ?o ?g. }

Showing items 1 to 100 of ±163 with 100 items per page.

W2017882766 abstract "The conventional analysis of Perdew and Levy, and Sham and Schlüter shows that the functional derivative discontinuity of the exchange-correlation density functional plays a critical role in the correct prediction of bandgaps, or the chemical hardness. In a recent work by the present authors, explicit expressions for bandgap prediction with all common types of exchange-correlation functionals have been derived without invoking the concept of exchange-correlation energy functional derivative discontinuity at all. We here analyze the two approaches and establish their connection and difference. The present analysis further leads to several important results: (1) The lowest unoccupied molecular orbital (LUMO) in DFT has as much meaning in describing electron addition as the highest occupied molecular orbital (HOMO) in describing electron removal. (2) Every term in the total energy functional contributes to the energy gap because of the discontinuity of the derivative of the density (or density matrix) with respect to the number of electrons, documentclass[12pt]{minimal}begin{document}$((partial rho _{s}(mathbf {r^{prime }},mathbf {r}))/partial N )_{v_{s}}$end{document}((∂ρs(r′,r))/∂N)vs, at integers. (3) Consistent with the Perdew-Levy-Sham-Schlüter conclusion that the exact Kohn-Sham energy gap differs from the fundamental bandgap by a finite correction due to the functional derivative discontinuity of the exchange-correlation energy, we show that the exchange-correlation functional cannot be an explicit and differentiable functional of the electron density, either local or nonlocal. The last result is further strengthened when we consider Mott insulators. There, the exact exchange-correlation functional needs to have an explicitly discontinuous (nondifferentiable) dependence on the density or the density matrix. (4) We obtain exact conditions on the derivatives of total energy with respect to the spin-up and spin-down number of electrons." @default.
W2017882766 created "2016-06-24" @default.
W2017882766 creator A5019365851 @default.
W2017882766 creator A5028349799 @default.
W2017882766 creator A5053764587 @default.
W2017882766 date "2012-05-24" @default.
W2017882766 modified "2023-10-16" @default.
W2017882766 title "Derivative discontinuity, bandgap and lowest unoccupied molecular orbital in density functional theory" @default.
W2017882766 cites W1513819669 @default.
W2017882766 cites W1643643809 @default.
W2017882766 cites W1654278279 @default.
W2017882766 cites W1964823939 @default.
W2017882766 cites W1967261560 @default.
W2017882766 cites W1970512969 @default.
W2017882766 cites W1973070144 @default.
W2017882766 cites W1974943505 @default.
W2017882766 cites W1977462511 @default.
W2017882766 cites W1979283539 @default.
W2017882766 cites W1980197072 @default.
W2017882766 cites W1980942200 @default.
W2017882766 cites W1981368803 @default.
W2017882766 cites W1986759412 @default.
W2017882766 cites W1986783124 @default.
W2017882766 cites W1987198520 @default.
W2017882766 cites W1991300868 @default.
W2017882766 cites W1993898990 @default.
W2017882766 cites W1995070176 @default.
W2017882766 cites W1996943850 @default.
W2017882766 cites W1998732907 @default.
W2017882766 cites W2000826139 @default.
W2017882766 cites W2002651440 @default.
W2017882766 cites W2002927697 @default.
W2017882766 cites W2007805650 @default.
W2017882766 cites W2008038275 @default.
W2017882766 cites W2008423326 @default.
W2017882766 cites W2008708918 @default.
W2017882766 cites W2009018767 @default.
W2017882766 cites W2009458392 @default.
W2017882766 cites W2012279747 @default.
W2017882766 cites W2012523318 @default.
W2017882766 cites W2013465150 @default.
W2017882766 cites W2017425597 @default.
W2017882766 cites W2023271753 @default.
W2017882766 cites W2024524145 @default.
W2017882766 cites W2025476943 @default.
W2017882766 cites W2028054907 @default.
W2017882766 cites W2042490355 @default.
W2017882766 cites W2044202126 @default.
W2017882766 cites W2046668457 @default.
W2017882766 cites W2051648115 @default.
W2017882766 cites W2052269441 @default.
W2017882766 cites W2052637367 @default.
W2017882766 cites W2053171774 @default.
W2017882766 cites W2053415214 @default.
W2017882766 cites W2053499780 @default.
W2017882766 cites W2054723927 @default.
W2017882766 cites W2055208155 @default.
W2017882766 cites W2055837606 @default.
W2017882766 cites W2059965864 @default.
W2017882766 cites W2060320428 @default.
W2017882766 cites W2062852634 @default.
W2017882766 cites W2065832042 @default.
W2017882766 cites W2072276121 @default.
W2017882766 cites W2072782129 @default.
W2017882766 cites W2077338572 @default.
W2017882766 cites W2077943054 @default.
W2017882766 cites W2080110676 @default.
W2017882766 cites W2080790766 @default.
W2017882766 cites W2084053963 @default.
W2017882766 cites W2085093563 @default.
W2017882766 cites W2086458318 @default.
W2017882766 cites W2095515682 @default.
W2017882766 cites W2098658310 @default.
W2017882766 cites W2099241086 @default.
W2017882766 cites W2100048524 @default.
W2017882766 cites W2101958915 @default.
W2017882766 cites W2102937493 @default.
W2017882766 cites W2143981217 @default.
W2017882766 cites W2230728100 @default.
W2017882766 cites W2329717581 @default.
W2017882766 cites W2963886673 @default.
W2017882766 cites W4235761954 @default.
W2017882766 cites W63525776 @default.
W2017882766 doi "https://doi.org/10.1063/1.3702391" @default.
W2017882766 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/22667544" @default.
W2017882766 hasPublicationYear "2012" @default.
W2017882766 type Work @default.
W2017882766 sameAs 2017882766 @default.
W2017882766 citedByCount "151" @default.
W2017882766 countsByYear W20178827662012 @default.
W2017882766 countsByYear W20178827662013 @default.
W2017882766 countsByYear W20178827662014 @default.
W2017882766 countsByYear W20178827662015 @default.
W2017882766 countsByYear W20178827662016 @default.
W2017882766 countsByYear W20178827662017 @default.
W2017882766 countsByYear W20178827662018 @default.
W2017882766 countsByYear W20178827662019 @default.
W2017882766 countsByYear W20178827662020 @default.
W2017882766 countsByYear W20178827662021 @default.
W2017882766 countsByYear W20178827662022 @default.