A systematic
computational study on the structural, electronic,
and bonding properties of binary sulfur nitrides has been performed
using the projector augmented wave method based on density functional
theory. The pressure–composition phase diagram of the S–N
system has been established. The simulated pressure–temperature
phase diagram and X-ray diffraction pattern of (SN)
x
explain the experimentally observed two-phase coexistence.
The crystal structure of experimentally observed orthorhombic (SN)
x
is predicted. The high-pressure phase transition
of (SN)
x
has been studied. Sulfur–sulfur
interactions induced by localized sulfur 3p
z
electrons are found in the high-pressure phase of (SN)
x
. With increasing nitrogen composition, the
coordination number of sulfur atoms increases from two to six in the
S–N system. Furthermore, two nitrogen-rich sulfur nitrides
SN2 and SN4 have been found at high pressure.
SN4 exhibits a high energy density (2.66 kJ·g–1), which makes it potentially interesting for industrial
applications as a high energy density material.
The evolutionary structure-searching method discovers that the energetically preferred compounds of germane can be synthesized at a pressure of 190 GPa. New structures with the space groups Ama2 and C2/c proposed here contain semimolecular H2 and V-type H3 units, respectively. Electronic structure analysis shows the metallic character and charge transfer from Ge to H. The conductivity of the two structures originates from the electrons around the hydrogen atoms. Further electron-phonon coupling calculations predict that the two phases are superconductors with a high Tc of 47-57 K for Ama2 at 250 GPa and 70-84 K for C2/c at 500 GPa from quasi-harmonic approximation calculations, which may be higher than under actual conditions.
Crystal structures of silane have been extensively investigated using ab initio evolutionary simulation methods at high pressures. Two metallic structures with P21/c and C2/m symmetries are found stable above 383 GPa. The superconductivities of metallic phases are fully explored under BCS theory, including the reported C2/c one. Perturbative linear-response calculations for C2/m silane at 610 GPa reveal a high superconducting critical temperature that beyond the order of 102 K.
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