Reversing the Irreversible: Thermodynamic Stabilization of LiAlH4Nanoconfined within a Nitrogen-Doped Carbon Host

Yongjun Cho; Sichi Li; Jonathan L. Snider; Maxwell A.T. Marple; Nicholas A. Strange; Joshua D. Sugar; Farid El Gabaly; Andreas Schneemann; Sungsu Kang; Min Ho Kang; Hayoung Park; Jungwon Park; Liwen F. Wan; Harris E. Mason; Mark D. Allendorf; Brandon C. Wood; Eun Seon Cho; Vitalie Stavila

doi:10.1021/acsnano.1c02079

Reversing the Irreversible: Thermodynamic Stabilization of LiAlH₄Nanoconfined within a Nitrogen-Doped Carbon Host

Yongjun Cho, Sichi Li, Jonathan L. Snider, Maxwell A.T. Marple, Nicholas A. Strange, Joshua D. Sugar, Farid El Gabaly, Andreas Schneemann, Sungsu Kang, Min Ho Kang, Hayoung Park, Jungwon Park, Liwen F. Wan, Harris E. Mason, Mark D. Allendorf, Brandon C. Wood, Eun Seon Cho, Vitalie Stavila

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

35 Scopus citations

Abstract

A general problem when designing functional nanomaterials for energy storage is the lack of control over the stability and reactivity of metastable phases. Using the high-capacity hydrogen storage candidate LiAlH4 as an exemplar, we demonstrate an alternative approach to the thermodynamic stabilization of metastable metal hydrides by coordination to nitrogen binding sites within the nanopores of N-doped CMK-3 carbon (NCMK-3). The resulting LiAlH4@NCMK-3 material releases H2 at temperatures as low as 126 °C with full decomposition below 240 °C, bypassing the usual Li3AlH6 intermediate observed in bulk. Moreover, >80% of LiAlH4 can be regenerated under 100 MPa H2, a feat previously thought to be impossible. Nitrogen sites are critical to these improvements, as no reversibility is observed with undoped CMK-3. Density functional theory predicts a drastically reduced Al-H bond dissociation energy and supports the observed change in the reaction pathway. The calculations also provide a rationale for the solid-state reversibility, which derives from the combined effects of nanoconfinement, Li adatom formation, and charge redistribution between the metal hydride and the host.

Original language	English
Pages (from-to)	10163-10174
Number of pages	12
Journal	ACS Nano
Volume	15
Issue number	6
DOIs	https://doi.org/10.1021/acsnano.1c02079
State	Published - 22 Jun 2021

Bibliographical note

Publisher Copyright:
© 2021 American Chemical Society. All rights reserved.

Keywords

coordination chemistry
hydrogen storage
metal hydrides
metastable materials
nanoconfinement
porous carbons

Access to Document

10.1021/acsnano.1c02079

Cite this

Cho, Y., Li, S., Snider, J. L., Marple, M. A. T., Strange, N. A., Sugar, J. D., El Gabaly, F., Schneemann, A., Kang, S., Kang, M. H., Park, H., Park, J., Wan, L. F., Mason, H. E., Allendorf, M. D., Wood, B. C., Cho, E. S., & Stavila, V. (2021). Reversing the Irreversible: Thermodynamic Stabilization of LiAlH₄Nanoconfined within a Nitrogen-Doped Carbon Host. ACS Nano, 15(6), 10163-10174. https://doi.org/10.1021/acsnano.1c02079

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title = "Reversing the Irreversible: Thermodynamic Stabilization of LiAlH4Nanoconfined within a Nitrogen-Doped Carbon Host",

abstract = "A general problem when designing functional nanomaterials for energy storage is the lack of control over the stability and reactivity of metastable phases. Using the high-capacity hydrogen storage candidate LiAlH4 as an exemplar, we demonstrate an alternative approach to the thermodynamic stabilization of metastable metal hydrides by coordination to nitrogen binding sites within the nanopores of N-doped CMK-3 carbon (NCMK-3). The resulting LiAlH4@NCMK-3 material releases H2 at temperatures as low as 126 °C with full decomposition below 240 °C, bypassing the usual Li3AlH6 intermediate observed in bulk. Moreover, >80% of LiAlH4 can be regenerated under 100 MPa H2, a feat previously thought to be impossible. Nitrogen sites are critical to these improvements, as no reversibility is observed with undoped CMK-3. Density functional theory predicts a drastically reduced Al-H bond dissociation energy and supports the observed change in the reaction pathway. The calculations also provide a rationale for the solid-state reversibility, which derives from the combined effects of nanoconfinement, Li adatom formation, and charge redistribution between the metal hydride and the host.",

keywords = "coordination chemistry, hydrogen storage, metal hydrides, metastable materials, nanoconfinement, porous carbons",

author = "Yongjun Cho and Sichi Li and Snider, {Jonathan L.} and Marple, {Maxwell A.T.} and Strange, {Nicholas A.} and Sugar, {Joshua D.} and {El Gabaly}, Farid and Andreas Schneemann and Sungsu Kang and Kang, {Min Ho} and Hayoung Park and Jungwon Park and Wan, {Liwen F.} and Mason, {Harris E.} and Allendorf, {Mark D.} and Wood, {Brandon C.} and Cho, {Eun Seon} and Vitalie Stavila",

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Cho, Y, Li, S, Snider, JL, Marple, MAT, Strange, NA, Sugar, JD, El Gabaly, F, Schneemann, A, Kang, S, Kang, MH, Park, H, Park, J, Wan, LF, Mason, HE, Allendorf, MD, Wood, BC, Cho, ES & Stavila, V 2021, 'Reversing the Irreversible: Thermodynamic Stabilization of LiAlH₄Nanoconfined within a Nitrogen-Doped Carbon Host', ACS Nano, vol. 15, no. 6, pp. 10163-10174. https://doi.org/10.1021/acsnano.1c02079

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T2 - Thermodynamic Stabilization of LiAlH4Nanoconfined within a Nitrogen-Doped Carbon Host

AU - Cho, Yongjun

AU - Li, Sichi

AU - Snider, Jonathan L.

AU - Marple, Maxwell A.T.

AU - Strange, Nicholas A.

AU - Sugar, Joshua D.

AU - El Gabaly, Farid

AU - Schneemann, Andreas

AU - Kang, Sungsu

AU - Kang, Min Ho

AU - Park, Hayoung

AU - Park, Jungwon

AU - Wan, Liwen F.

AU - Mason, Harris E.

AU - Allendorf, Mark D.

AU - Wood, Brandon C.

AU - Cho, Eun Seon

AU - Stavila, Vitalie

PY - 2021/6/22

Y1 - 2021/6/22

N2 - A general problem when designing functional nanomaterials for energy storage is the lack of control over the stability and reactivity of metastable phases. Using the high-capacity hydrogen storage candidate LiAlH4 as an exemplar, we demonstrate an alternative approach to the thermodynamic stabilization of metastable metal hydrides by coordination to nitrogen binding sites within the nanopores of N-doped CMK-3 carbon (NCMK-3). The resulting LiAlH4@NCMK-3 material releases H2 at temperatures as low as 126 °C with full decomposition below 240 °C, bypassing the usual Li3AlH6 intermediate observed in bulk. Moreover, >80% of LiAlH4 can be regenerated under 100 MPa H2, a feat previously thought to be impossible. Nitrogen sites are critical to these improvements, as no reversibility is observed with undoped CMK-3. Density functional theory predicts a drastically reduced Al-H bond dissociation energy and supports the observed change in the reaction pathway. The calculations also provide a rationale for the solid-state reversibility, which derives from the combined effects of nanoconfinement, Li adatom formation, and charge redistribution between the metal hydride and the host.

AB - A general problem when designing functional nanomaterials for energy storage is the lack of control over the stability and reactivity of metastable phases. Using the high-capacity hydrogen storage candidate LiAlH4 as an exemplar, we demonstrate an alternative approach to the thermodynamic stabilization of metastable metal hydrides by coordination to nitrogen binding sites within the nanopores of N-doped CMK-3 carbon (NCMK-3). The resulting LiAlH4@NCMK-3 material releases H2 at temperatures as low as 126 °C with full decomposition below 240 °C, bypassing the usual Li3AlH6 intermediate observed in bulk. Moreover, >80% of LiAlH4 can be regenerated under 100 MPa H2, a feat previously thought to be impossible. Nitrogen sites are critical to these improvements, as no reversibility is observed with undoped CMK-3. Density functional theory predicts a drastically reduced Al-H bond dissociation energy and supports the observed change in the reaction pathway. The calculations also provide a rationale for the solid-state reversibility, which derives from the combined effects of nanoconfinement, Li adatom formation, and charge redistribution between the metal hydride and the host.

KW - coordination chemistry

KW - hydrogen storage

KW - metal hydrides

KW - metastable materials

KW - nanoconfinement

KW - porous carbons

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