SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2322615029> ?p ?o ?g. }

Showing items 1 to 100 of ±161 with 100 items per page.

W2322615029 abstract "For a wide range of magnetic fields, $0ensuremath{le}Bensuremath{le}2000$ a.u., we present a systematic comparative study of the performance of different types of density-functional approximations in light atoms ($2ensuremath{le}Zensuremath{le}6$). Local, generalized-gradient approximation (GGA; semilocal), and meta-GGA ground-state exchange-correlation (xc) functionals are compared on an equal footing with exact-exchange, Hartree-Fock (HF), and current-density-functional-theory (CDFT) approximations. Comparison also is made with published quantum Monte Carlo data. Though all approximations give qualitatively reasonable results, the exchange energies from local and GGA functionals are too negative for large $B$. Results from the Perdew-Burke-Ernzerhof ground-state GGA and Tao-Perdew-Staroverov-Scuseria (TPSS) ground-state meta-GGA functionals are very close. Because of confinement, self-interaction error in such functionals is more severe at large $B$ than at $B=0$, hence self-interaction correction is crucial. Exact exchange combined with the TPSS correlation functional results in a self-interaction-free (xc) functional, from which we obtain atomic energies of comparable accuracy to those from correlated wave-function methods. Specifically for the B and C atoms, we provide beyond-HF energies in a wide range of $B$ fields. Fully self-consistent CDFT calculations were done with the Vignale-Rasolt-Geldart (VRG) functional in conjunction with the PW92 xc functional. Current effects turn out to be small, and the vorticity variable in the VRG functional diverges in some low-density regions. This part of the study suggests that nonlocal, self-interaction-free functionals may be better than local approximations as a starting point for CDFT functional construction and that some basic variable other than the vorticity could be helpful in making CDFT calculations practical." @default.
W2322615029 created "2016-06-24" @default.
W2322615029 creator A5000930582 @default.
W2322615029 creator A5021831749 @default.
W2322615029 creator A5066599847 @default.
W2322615029 date "2014-08-11" @default.
W2322615029 modified "2023-10-18" @default.
W2322615029 title "Comparative studies of density-functional approximations for light atoms in strong magnetic fields" @default.
W2322615029 cites W1595100039 @default.
W2322615029 cites W1966972082 @default.
W2322615029 cites W1967505918 @default.
W2322615029 cites W1969518036 @default.
W2322615029 cites W1971386000 @default.
W2322615029 cites W1973374559 @default.
W2322615029 cites W1974126996 @default.
W2322615029 cites W1974653818 @default.
W2322615029 cites W1979027171 @default.
W2322615029 cites W1981368803 @default.
W2322615029 cites W1981668092 @default.
W2322615029 cites W1984806160 @default.
W2322615029 cites W1985702263 @default.
W2322615029 cites W1987015589 @default.
W2322615029 cites W1988128360 @default.
W2322615029 cites W1988808806 @default.
W2322615029 cites W1992962610 @default.
W2322615029 cites W1993823958 @default.
W2322615029 cites W1995049158 @default.
W2322615029 cites W1997072717 @default.
W2322615029 cites W1997971026 @default.
W2322615029 cites W2005130909 @default.
W2322615029 cites W2006806329 @default.
W2322615029 cites W2006959986 @default.
W2322615029 cites W2011712139 @default.
W2322615029 cites W2012078989 @default.
W2322615029 cites W2014778136 @default.
W2322615029 cites W2016723995 @default.
W2322615029 cites W2019109263 @default.
W2322615029 cites W2019332397 @default.
W2322615029 cites W2022878311 @default.
W2322615029 cites W2025375608 @default.
W2322615029 cites W2030976617 @default.
W2322615029 cites W2032719166 @default.
W2322615029 cites W2032863186 @default.
W2322615029 cites W2034812818 @default.
W2322615029 cites W2038166012 @default.
W2322615029 cites W2038224624 @default.
W2322615029 cites W2039557297 @default.
W2322615029 cites W2040302858 @default.
W2322615029 cites W2040720587 @default.
W2322615029 cites W2045162020 @default.
W2322615029 cites W2045511196 @default.
W2322615029 cites W2047710225 @default.
W2322615029 cites W2048799840 @default.
W2322615029 cites W2049079467 @default.
W2322615029 cites W2051860475 @default.
W2322615029 cites W2053623890 @default.
W2322615029 cites W2054209389 @default.
W2322615029 cites W2054253981 @default.
W2322615029 cites W2054704030 @default.
W2322615029 cites W2054839455 @default.
W2322615029 cites W2055447288 @default.
W2322615029 cites W2064608522 @default.
W2322615029 cites W2065757584 @default.
W2322615029 cites W2066857037 @default.
W2322615029 cites W2066908273 @default.
W2322615029 cites W2067733985 @default.
W2322615029 cites W2070650036 @default.
W2322615029 cites W2075301380 @default.
W2322615029 cites W2077959315 @default.
W2322615029 cites W2079379078 @default.
W2322615029 cites W2079607177 @default.
W2322615029 cites W2080220464 @default.
W2322615029 cites W2080777994 @default.
W2322615029 cites W2081031224 @default.
W2322615029 cites W2083633537 @default.
W2322615029 cites W2087533754 @default.
W2322615029 cites W2092655956 @default.
W2322615029 cites W2093387898 @default.
W2322615029 cites W2131039391 @default.
W2322615029 cites W2138406487 @default.
W2322615029 cites W2161342498 @default.
W2322615029 cites W2166488081 @default.
W2322615029 cites W2230728100 @default.
W2322615029 cites W2329540137 @default.
W2322615029 cites W2332694750 @default.
W2322615029 cites W2570155021 @default.
W2322615029 cites W2593813005 @default.
W2322615029 cites W3099448832 @default.
W2322615029 cites W3099965137 @default.
W2322615029 cites W3105460832 @default.
W2322615029 cites W3105687778 @default.
W2322615029 cites W411413486 @default.
W2322615029 cites W4251267542 @default.
W2322615029 cites W4381161774 @default.
W2322615029 doi "https://doi.org/10.1103/physreva.90.022504" @default.
W2322615029 hasPublicationYear "2014" @default.
W2322615029 type Work @default.
W2322615029 sameAs 2322615029 @default.
W2322615029 citedByCount "16" @default.
W2322615029 countsByYear W23226150292015 @default.