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dc.contributor.authorKurzydlowski, Dominik*
dc.contributor.authorHermann, Andreas*
dc.date.accessioned2021-02-11T13:45:44Z
dc.date.available2021-02-11T13:45:44Z
dc.date.issued2019*
dc.date.submitted2019-12-09 16:10:12*
dc.identifier42708*
dc.identifier.urihttps://directory.doabooks.org/handle/20.500.12854/47707
dc.description.abstractThe term “first-principles calculations” is a synonym for the numerical determination of the electronic structure of atoms, molecules, clusters, or materials from ‘first principles’, i.e., without any approximations to the underlying quantum-mechanical equations. Although numerous approximate approaches have been developed for small molecular systems since the late 1920s, it was not until the advent of the density functional theory (DFT) in the 1960s that accurate “first-principles” calculations could be conducted for crystalline materials. The rapid development of this method over the past two decades allowed it to evolve from an explanatory to a truly predictive tool. Yet, challenges remain: complex chemical compositions, variable external conditions (such as pressure), defects, or properties that rely on collective excitations—all represent computational and/or methodological bottlenecks. This Special Issue comprises a collection of papers that use DFT to tackle some of these challenges and thus highlight what can (and cannot yet) be achieved using first-principles calculations of crystals.*
dc.languageEnglish*
dc.subjectQD1-999*
dc.subjectQ1-390*
dc.subjectQD450-801*
dc.subject.classificationthema EDItEUR::P Mathematics and Science::PN Chemistryen_US
dc.subject.otherab initio*
dc.subject.othern/a*
dc.subject.othermagnetic Lennard–Jones*
dc.subject.othersuperconductivity*
dc.subject.otherglobal optimisation*
dc.subject.otherelectrical engineering*
dc.subject.otherfirst-principles*
dc.subject.othersemiconductors*
dc.subject.otherrefractory metals*
dc.subject.othergenetic algorithm*
dc.subject.otherDFT*
dc.subject.othercrystal structure prediction*
dc.subject.otherelectronic structure*
dc.subject.otherindium arsenide*
dc.subject.othervan der Waals corrections*
dc.subject.othercharged defects*
dc.subject.otherIr-based intermetallics*
dc.subject.otherpoint defects*
dc.subject.otherelectronic properties*
dc.subject.otherlearning algorithms*
dc.subject.otherhalf-Heusler alloy*
dc.subject.othermolecular crystals*
dc.subject.otherchlorine*
dc.subject.otheroptical properties*
dc.subject.otherab initio calculations*
dc.subject.othermagnetic properties*
dc.subject.otherstructure prediction*
dc.subject.otherthermoelectricity*
dc.subject.otherhigh-pressure*
dc.subject.otherdensity functional theory*
dc.subject.othermagnetic materials*
dc.subject.otherstructural fingerprint*
dc.subject.othercrystal structure*
dc.subject.othersemihard materials*
dc.subject.othersilver*
dc.subject.otherformation energy*
dc.subject.otherHeusler alloy*
dc.subject.otherbattery materials*
dc.subject.otherelastic properties*
dc.titleFirst-Principles Prediction of Structures and Properties in Crystals*
dc.typebook
oapen.identifier.doi10.3390/books978-3-03921-671-0*
oapen.relation.isPublishedBy46cabcaa-dd94-4bfe-87b4-55023c1b36d0*
oapen.relation.isbn9783039216703*
oapen.relation.isbn9783039216710*
oapen.pages128*
oapen.edition1st*


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