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Anionic Chemistry of Noble Gases: Formation of Mg-NG (NG = Xe, Kr, Ar) Compounds under Pressure

Autor(en)
Mao-sheng Miao, Xiao-li Wang, Jakoah Brgoch, Frank Spera, Matthew G. Jackson, Georg Kresse, Hai-qing Lin
Abstrakt

While often considered to be chemically inert, the reactivity of noble gas elements at elevated pressures is an important aspect of fundamental chemistry. The discovery of Xe oxidation transformed the doctrinal boundary of chemistry by showing that a complete electron shell is not inert to reaction. However, the reductive propensity, i.e., gaining electrons and forming anions, has not been proposed or examined for noble gas elements. In this work, we demonstrate, using first-principles electronic structure calculations coupled to an efficient structure prediction method, that Xe, Kr, and Ar can form thermodynamically stable compounds with Mg at high pressure (>= 125, >= 250, and >= 250 GPa, respectively). The resulting compounds are metallic and the noble gas atoms are negatively charged, suggesting that chemical species with a completely filled shell can gain electrons, filling their outermost shell(s). Moreover, this work indicates that Mg(2)NG (NG = Xe, Kr, Ar) are high-pressure electrides with some of the electrons localized at interstitial sites enclosed by the surrounding atoms. Previous predictions showed that such electrides only form in Mg and its compounds at very high pressures (>500 GPa). These calculations also demonstrate strong chemical interactions between the Xe 5d orbitals and the quantized interstitial quasiatom (ISQ) orbitals, including the strong chemical bonding and electron transfer, revealing the chemical nature of the ISQ.

Organisation(en)
Computergestützte Materialphysik
Externe Organisation(en)
California State University, Northridge, Chinese Academy of Sciences (CAS), Linyi University (LYU), University of California, Santa Barbara, University of Houston
Journal
Journal of the American Chemical Society
Band
137
Seiten
14122-14128
Anzahl der Seiten
7
ISSN
0002-7863
DOI
https://doi.org/10.1021/jacs.5b08162
Publikationsdatum
11-2015
Peer-reviewed
Ja
ÖFOS 2012
103025 Quantenmechanik, 103036 Theoretische Physik, 103015 Kondensierte Materie, 103009 Festkörperphysik
Schlagwörter
ASJC Scopus Sachgebiete
Allgemeine Chemie, Biochemistry, Catalysis, Colloid and Surface Chemistry
Link zum Portal
https://ucrisportal.univie.ac.at/de/publications/1ae37025-61b6-413c-b6dd-1ecd808e400b