Hydrogen release from Li alanates originates in molecular lattice instability emerging at ∼ 100 K

K. Tomiyasu; T. Sato; K. Horigane; S. Orimo; K. Yamada

doi:10.1063/1.4712053

Hydrogen release from Li alanates originates in molecular lattice instability emerging at ∼ 100 K

K. Tomiyasu, T. Sato, K. Horigane, S. Orimo, K. Yamada

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Abstract

Lattice vibrations from 20 K to room temperature in lithium alanates LiAlH ₄ and Li ₃AlH ₆, which decompose to release hydrogen over 423 K, were investigated by neutron spectroscopy. For both alanates, the overall spectra already start to broaden at 100-150 K with increasing temperature. The spectral lines assigned to the librational (rotational) modes of the polyhedral Al hydrido complexes, [AlH ₄] ^- and [AlH ₆] ^3-, exhibit not only broadening but also softening at around 250-300 K. These results suggest that the decomposition stems from low-temperature bulk lattice instability/ anharmonicity, in particular, due to the weakening of binding between the complexes and their surroundings.

Original language	English
Article number	193901
Journal	Applied Physics Letters
Volume	100
Issue number	19
DOIs	https://doi.org/10.1063/1.4712053
Publication status	Published - 2012 May 7
Externally published	Yes

ASJC Scopus subject areas

Physics and Astronomy (miscellaneous)

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@article{5eaa2b6adf834c61a6661ecdae93c680,

title = "Hydrogen release from Li alanates originates in molecular lattice instability emerging at ∼ 100 K",

abstract = "Lattice vibrations from 20 K to room temperature in lithium alanates LiAlH 4 and Li 3AlH 6, which decompose to release hydrogen over 423 K, were investigated by neutron spectroscopy. For both alanates, the overall spectra already start to broaden at 100-150 K with increasing temperature. The spectral lines assigned to the librational (rotational) modes of the polyhedral Al hydrido complexes, [AlH 4] - and [AlH 6] 3-, exhibit not only broadening but also softening at around 250-300 K. These results suggest that the decomposition stems from low-temperature bulk lattice instability/ anharmonicity, in particular, due to the weakening of binding between the complexes and their surroundings.",

author = "K. Tomiyasu and T. Sato and K. Horigane and S. Orimo and K. Yamada",

note = "Funding Information: We thank Dr. K. Ikeda, Dr. S. Iikubo, Dr. R. Kiyanagi, and Dr. Y. Ishikawa for the preliminary experiments and the helpful discussions, Dr. H. Nakamura and Dr. M. Machida for the fruitful discussion on the first-principle calculations, Dr. K. Iwasa for providing the extra beam time on TOPAN, and Mr. K. Nemoto and Mr. M. Ohkawara for supporting the experiments at JAEA. This study was financially supported by the Exploratory Research Program for Young Researchers from Tohoku University, and by Grants-in-Aid for Young Scientists (B) (22740209), Priority Areas (22014001), Scientific Researches (S) (21224008) and (A) (22244039), and NEXT Program (GR008) from the MEXT, Japan, and JSPS.",

year = "2012",

month = may,

day = "7",

doi = "10.1063/1.4712053",

language = "English",

volume = "100",

journal = "Applied Physics Letters",

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T1 - Hydrogen release from Li alanates originates in molecular lattice instability emerging at ∼ 100 K

AU - Tomiyasu, K.

AU - Sato, T.

AU - Horigane, K.

AU - Orimo, S.

AU - Yamada, K.

N1 - Funding Information: We thank Dr. K. Ikeda, Dr. S. Iikubo, Dr. R. Kiyanagi, and Dr. Y. Ishikawa for the preliminary experiments and the helpful discussions, Dr. H. Nakamura and Dr. M. Machida for the fruitful discussion on the first-principle calculations, Dr. K. Iwasa for providing the extra beam time on TOPAN, and Mr. K. Nemoto and Mr. M. Ohkawara for supporting the experiments at JAEA. This study was financially supported by the Exploratory Research Program for Young Researchers from Tohoku University, and by Grants-in-Aid for Young Scientists (B) (22740209), Priority Areas (22014001), Scientific Researches (S) (21224008) and (A) (22244039), and NEXT Program (GR008) from the MEXT, Japan, and JSPS.

PY - 2012/5/7

Y1 - 2012/5/7

N2 - Lattice vibrations from 20 K to room temperature in lithium alanates LiAlH 4 and Li 3AlH 6, which decompose to release hydrogen over 423 K, were investigated by neutron spectroscopy. For both alanates, the overall spectra already start to broaden at 100-150 K with increasing temperature. The spectral lines assigned to the librational (rotational) modes of the polyhedral Al hydrido complexes, [AlH 4] - and [AlH 6] 3-, exhibit not only broadening but also softening at around 250-300 K. These results suggest that the decomposition stems from low-temperature bulk lattice instability/ anharmonicity, in particular, due to the weakening of binding between the complexes and their surroundings.

AB - Lattice vibrations from 20 K to room temperature in lithium alanates LiAlH 4 and Li 3AlH 6, which decompose to release hydrogen over 423 K, were investigated by neutron spectroscopy. For both alanates, the overall spectra already start to broaden at 100-150 K with increasing temperature. The spectral lines assigned to the librational (rotational) modes of the polyhedral Al hydrido complexes, [AlH 4] - and [AlH 6] 3-, exhibit not only broadening but also softening at around 250-300 K. These results suggest that the decomposition stems from low-temperature bulk lattice instability/ anharmonicity, in particular, due to the weakening of binding between the complexes and their surroundings.

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Hydrogen release from Li alanates originates in molecular lattice instability emerging at ∼ 100 K

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