Open AccessPressure-stabilized hafnium nitrides and their properties
Author(s) -
Jin Zhang,
Artem R. Oganov,
Xinfeng Li,
Haiyang Niu
Publication year - 2017
Publication title -
physical review. b./physical review. b
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.78
H-Index - 465
eISSN - 2469-9969
pISSN - 2469-9950
DOI - 10.1103/physrevb.95.020103
Subject(s) - hafnium , nitride , ambient pressure , metastability , materials science , gravimetric analysis , phase (matter) , vickers hardness test , metal , crystallography , activation energy , analytical chemistry (journal) , zirconium , thermodynamics , chemistry , metallurgy , composite material , microstructure , physics , organic chemistry , layer (electronics) , chromatography
We report hafnium nitrides under pressure using first-principles evolutionary calculations. Metallic $P{6}_{3}/mmc$-HfN (calculated Vickers hardness 23.8 GPa) is found to be more energetically favorable than NaCl-type HfN at zero and high pressure. Moreover, NaCl-type HfN actually undergoes a phase transition to $P{6}_{3}/mmc$-HfN below 670 K at ambient pressure. ${\mathrm{HfN}}_{10}$, which simultaneously has infinite armchairlike polymeric N chains and ${\mathrm{N}}_{2}$ molecules in its crystal structure, is discovered to be stable at moderate pressure above 23 GPa and can be preserved as a metastable phase at ambient pressure. At ambient conditions (298 K, 0 GPa), the gravimetric energy densities and the volumetric energy densities of ${\mathrm{HfN}}_{10}$ are 2.8 kJ/g and 14.1 kJ/${\mathrm{cm}}^{3}$, respectively.
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