TY - JOUR
T1 - Formation of novel transition metal hydride complexes with ninefold hydrogen coordination
AU - Takagi, Shigeyuki
AU - Iijima, Yuki
AU - Sato, Toyoto
AU - Saitoh, Hiroyuki
AU - Ikeda, Kazutaka
AU - Otomo, Toshiya
AU - Miwa, Kazutoshi
AU - Ikeshoji, Tamio
AU - Orimo, Shin Ichi
N1 - Funding Information:
This work was supported by JSPS KAKENHI (Grant Numbers 16H06119, 25220911, 16K06766 and 25420725), the Photon and Quantum Basic Research Coordinated Development Program by MEXT and Collaborative Research Center on Energy Materials in IMR (E-IMR).
Publisher Copyright:
© The Author(s) 2017.
PY - 2017/3/13
Y1 - 2017/3/13
N2 - Ninefold coordination of hydrogen is very rare, and has been observed in two different hydride complexes comprising rhenium and technetium. Herein, based on a theoretical/experimental approach, we present evidence for the formation of ninefold H- coordination hydride complexes of molybdenum ([MoH 9 ] 3-), tungsten ([WH 9 ] 3-), niobium ([NbH 9 ] 4-) and tantalum ([TaH 9 ] 4-) in novel complex transition-metal hydrides, Li 5 MoH 11, Li 5 WH 11, Li 6 NbH 11 and Li 6 TaH 11, respectively. All of the synthesized materials are insulated with band gaps of approximately 4 eV, but contain a sufficient amount of hydrogen to cause the H 1s-derived states to reach the Fermi level. Such hydrogen-rich materials might be of interest for high-critical-temperature superconductivity if the gaps close under compression. Furthermore, the hydride complexes exhibit significant rotational motions associated with anharmonic librations at room temperature, which are often discussed in relation to the translational diffusion of cations in alkali-metal dodecahydro-closo-dodecaborates and strongly point to the emergence of a fast lithium conduction even at room temperature.
AB - Ninefold coordination of hydrogen is very rare, and has been observed in two different hydride complexes comprising rhenium and technetium. Herein, based on a theoretical/experimental approach, we present evidence for the formation of ninefold H- coordination hydride complexes of molybdenum ([MoH 9 ] 3-), tungsten ([WH 9 ] 3-), niobium ([NbH 9 ] 4-) and tantalum ([TaH 9 ] 4-) in novel complex transition-metal hydrides, Li 5 MoH 11, Li 5 WH 11, Li 6 NbH 11 and Li 6 TaH 11, respectively. All of the synthesized materials are insulated with band gaps of approximately 4 eV, but contain a sufficient amount of hydrogen to cause the H 1s-derived states to reach the Fermi level. Such hydrogen-rich materials might be of interest for high-critical-temperature superconductivity if the gaps close under compression. Furthermore, the hydride complexes exhibit significant rotational motions associated with anharmonic librations at room temperature, which are often discussed in relation to the translational diffusion of cations in alkali-metal dodecahydro-closo-dodecaborates and strongly point to the emergence of a fast lithium conduction even at room temperature.
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U2 - 10.1038/srep44253
DO - 10.1038/srep44253
M3 - Article
C2 - 28287143
AN - SCOPUS:85015347473
SN - 2045-2322
VL - 7
JO - Scientific Reports
JF - Scientific Reports
M1 - 44253
ER -