Improved reversible hydrogen storage of LiAlH4 by nano-sized TiH2

Shu Sheng Liu; Zhi Bao Li; Cheng Li Jiao; Xiao Liang Si; Li Ni Yang; Jian Zhang; Huai Ying Zhou; Feng Lei Huang; Zelimir Gabelica; Christoph Schick; Li Xian Sun; Fen Xu

doi:10.1016/j.ijhydene.2012.11.042

Improved reversible hydrogen storage of LiAlH₄ by nano-sized TiH₂

Shu Sheng Liu, Zhi Bao Li, Cheng Li Jiao, Xiao Liang Si, Li Ni Yang, Jian Zhang, Huai Ying Zhou, Feng Lei Huang, Zelimir Gabelica, Christoph Schick, Li Xian Sun^*, Fen Xu

^*Corresponding author for this work

School of Mechatronical Engineering

Research output: Contribution to journal › Article › peer-review

45 Citations (Scopus)

Abstract

Transition metal halides are mostly used as dopants to improve the hydrogen storage properties of LiAlH₄, but they will cause hydrogen capacity loss because of their relatively high molecular weights and reactions with LiAlH₄. To overcome these drawbacks, active nano-sized TiH ₂ (TiH₂^nano) prepared by reactive ball milling is used to dope LiAlH₄. It shows superior catalytic effect on the dehydrogenation of LiAlH₄ compared to commercial TiH₂. TiH₂^nano-doped LiAlH₄ starts to release hydrogen at 75 °C, which is 80 °C lower than the onset dehydrogenation temperature of commercial LiAlH₄. About 6.3 wt.% H₂ can be released isothermally at 100 °C (800 min) or at 120 °C (150 min). The apparent activation energies of the first two dehydrogenation reactions of LiAlH₄ are reduced by about 20 and 24 kJ mol^-1, respectively. Meanwhile, the regeneration of LiAlH₄ is realized through extracting the solvent from LiAlH₄·4THF, which is obtained by ball milling the dehydrogenated products of TiH₂ ^nano-doped LiAlH₄ in the presence of THF and 5 MPa H ₂. This suggests that TiH₂ is also an effective catalyst for the formation of LiAlH₄·4THF.

Original language	English
Pages (from-to)	2770-2777
Number of pages	8
Journal	International Journal of Hydrogen Energy
Volume	38
Issue number	6
DOIs	https://doi.org/10.1016/j.ijhydene.2012.11.042
Publication status	Published - 27 Feb 2013

Keywords

Alanate
Catalyst
Dehydrogenation
Regeneration
Titanium hydride

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.1016/j.ijhydene.2012.11.042

Cite this

Liu, S. S., Li, Z. B., Jiao, C. L., Si, X. L., Yang, L. N., Zhang, J., Zhou, H. Y., Huang, F. L., Gabelica, Z., Schick, C., Sun, L. X., & Xu, F. (2013). Improved reversible hydrogen storage of LiAlH₄ by nano-sized TiH₂. International Journal of Hydrogen Energy, 38(6), 2770-2777. https://doi.org/10.1016/j.ijhydene.2012.11.042

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title = "Improved reversible hydrogen storage of LiAlH4 by nano-sized TiH2",

abstract = "Transition metal halides are mostly used as dopants to improve the hydrogen storage properties of LiAlH4, but they will cause hydrogen capacity loss because of their relatively high molecular weights and reactions with LiAlH4. To overcome these drawbacks, active nano-sized TiH 2 (TiH2nano) prepared by reactive ball milling is used to dope LiAlH4. It shows superior catalytic effect on the dehydrogenation of LiAlH4 compared to commercial TiH2. TiH2nano-doped LiAlH4 starts to release hydrogen at 75 °C, which is 80 °C lower than the onset dehydrogenation temperature of commercial LiAlH4. About 6.3 wt.% H2 can be released isothermally at 100 °C (800 min) or at 120 °C (150 min). The apparent activation energies of the first two dehydrogenation reactions of LiAlH4 are reduced by about 20 and 24 kJ mol-1, respectively. Meanwhile, the regeneration of LiAlH4 is realized through extracting the solvent from LiAlH4·4THF, which is obtained by ball milling the dehydrogenated products of TiH2 nano-doped LiAlH4 in the presence of THF and 5 MPa H 2. This suggests that TiH2 is also an effective catalyst for the formation of LiAlH4·4THF.",

keywords = "Alanate, Catalyst, Dehydrogenation, Regeneration, Titanium hydride",

author = "Liu, {Shu Sheng} and Li, {Zhi Bao} and Jiao, {Cheng Li} and Si, {Xiao Liang} and Yang, {Li Ni} and Jian Zhang and Zhou, {Huai Ying} and Huang, {Feng Lei} and Zelimir Gabelica and Christoph Schick and Sun, {Li Xian} and Fen Xu",

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AU - Liu, Shu Sheng

AU - Li, Zhi Bao

AU - Jiao, Cheng Li

AU - Si, Xiao Liang

AU - Yang, Li Ni

AU - Zhang, Jian

AU - Zhou, Huai Ying

AU - Huang, Feng Lei

AU - Gabelica, Zelimir

AU - Schick, Christoph

AU - Sun, Li Xian

AU - Xu, Fen

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N2 - Transition metal halides are mostly used as dopants to improve the hydrogen storage properties of LiAlH4, but they will cause hydrogen capacity loss because of their relatively high molecular weights and reactions with LiAlH4. To overcome these drawbacks, active nano-sized TiH 2 (TiH2nano) prepared by reactive ball milling is used to dope LiAlH4. It shows superior catalytic effect on the dehydrogenation of LiAlH4 compared to commercial TiH2. TiH2nano-doped LiAlH4 starts to release hydrogen at 75 °C, which is 80 °C lower than the onset dehydrogenation temperature of commercial LiAlH4. About 6.3 wt.% H2 can be released isothermally at 100 °C (800 min) or at 120 °C (150 min). The apparent activation energies of the first two dehydrogenation reactions of LiAlH4 are reduced by about 20 and 24 kJ mol-1, respectively. Meanwhile, the regeneration of LiAlH4 is realized through extracting the solvent from LiAlH4·4THF, which is obtained by ball milling the dehydrogenated products of TiH2 nano-doped LiAlH4 in the presence of THF and 5 MPa H 2. This suggests that TiH2 is also an effective catalyst for the formation of LiAlH4·4THF.

AB - Transition metal halides are mostly used as dopants to improve the hydrogen storage properties of LiAlH4, but they will cause hydrogen capacity loss because of their relatively high molecular weights and reactions with LiAlH4. To overcome these drawbacks, active nano-sized TiH 2 (TiH2nano) prepared by reactive ball milling is used to dope LiAlH4. It shows superior catalytic effect on the dehydrogenation of LiAlH4 compared to commercial TiH2. TiH2nano-doped LiAlH4 starts to release hydrogen at 75 °C, which is 80 °C lower than the onset dehydrogenation temperature of commercial LiAlH4. About 6.3 wt.% H2 can be released isothermally at 100 °C (800 min) or at 120 °C (150 min). The apparent activation energies of the first two dehydrogenation reactions of LiAlH4 are reduced by about 20 and 24 kJ mol-1, respectively. Meanwhile, the regeneration of LiAlH4 is realized through extracting the solvent from LiAlH4·4THF, which is obtained by ball milling the dehydrogenated products of TiH2 nano-doped LiAlH4 in the presence of THF and 5 MPa H 2. This suggests that TiH2 is also an effective catalyst for the formation of LiAlH4·4THF.

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KW - Catalyst

KW - Dehydrogenation

KW - Regeneration

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