Effect of the structural evolution on the ionic conductivity of Li-N-H system during the dehydrogenation

Biswajit Paik; Motoaki Matsuo; Toyoto Sato; Liyuan Qu; Anna Roza Wolczyk; Shin Ichi Orimo

doi:10.1063/1.4952601

Effect of the structural evolution on the ionic conductivity of Li-N-H system during the dehydrogenation

Biswajit Paik, Motoaki Matsuo, Toyoto Sato, Liyuan Qu, Anna Roza Wolczyk, Shin Ichi Orimo

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

10 Citations (Scopus)

Abstract

On the way to transform lithium amide (LiNH₂) into lithium imide (Li₂NH) by releasing H₂, the 1:1 molar mixture of LiNH₂-LiH forms cubic (F m 3 m) non-stoichiometric complex hydride phases (Li₁₊ _xNH_2- _x; 0 < x < 1) that co-exist with the tetragonal (I 4) LiNH₂ and with the cubic (F d 3 m) Li₂NH, respectively, at the early and at the advanced stage of the dehydrogenation. The change in LiNH₂ → Li₂NH may be viewed as a mechanism which continuously fills up the vacant Li sites of the tetragonal structure and, in a parallel process, transforms the anions [NH₂]^- → [NH]^2-. The Li-N-H system, thus formed, by releasing >6 wt. % H₂ can offer high Li-ionic conductivity (>10^-4 S·cm^-1 at room temperature) having an electrochemical stability window >5 V. The study suggests that the Li-N-H system may be a prospective electrolyte in the all-solid-state Li-ion battery, in addition to its use as a reversible hydrogen storage material.

Original language	English
Article number	213903
Journal	Applied Physics Letters
Volume	108
Issue number	21
DOIs	https://doi.org/10.1063/1.4952601
Publication status	Published - 2016 May 23

ASJC Scopus subject areas

Physics and Astronomy (miscellaneous)

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10.1063/1.4952601

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title = "Effect of the structural evolution on the ionic conductivity of Li-N-H system during the dehydrogenation",

abstract = "On the way to transform lithium amide (LiNH2) into lithium imide (Li2NH) by releasing H2, the 1:1 molar mixture of LiNH2-LiH forms cubic (F m 3 m) non-stoichiometric complex hydride phases (Li1+ xNH2- x; 0 < x < 1) that co-exist with the tetragonal (I 4) LiNH2 and with the cubic (F d 3 m) Li2NH, respectively, at the early and at the advanced stage of the dehydrogenation. The change in LiNH2 → Li2NH may be viewed as a mechanism which continuously fills up the vacant Li sites of the tetragonal structure and, in a parallel process, transforms the anions [NH2]- → [NH]2-. The Li-N-H system, thus formed, by releasing >6 wt. % H2 can offer high Li-ionic conductivity (>10-4 S·cm-1 at room temperature) having an electrochemical stability window >5 V. The study suggests that the Li-N-H system may be a prospective electrolyte in the all-solid-state Li-ion battery, in addition to its use as a reversible hydrogen storage material.",

author = "Biswajit Paik and Motoaki Matsuo and Toyoto Sato and Liyuan Qu and Wolczyk, {Anna Roza} and Orimo, {Shin Ichi}",

note = "Funding Information: The work has been funded by the Japan Society for the Promotion of Science (JSPS) KAKENHI under Grant-in-aid Nos. 2522091, 26820311, and 26820313. L.Q. acknowledges the {\^a}€{\oe}Inter-departmental Doctoral Degree Program for Multi-dimensional Materials Science Leaders{\^a}€(MD Program) and A.R.W. acknowledges European Marie Curie Actions under ECOSTORE Grant Agreement No. 607040 for supporting this work. Technical assistance from Ms. N. Warifune is also greatly acknowledged. Publisher Copyright: {\textcopyright} 2016 Author(s).",

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AU - Paik, Biswajit

AU - Matsuo, Motoaki

AU - Sato, Toyoto

AU - Qu, Liyuan

AU - Wolczyk, Anna Roza

AU - Orimo, Shin Ichi

N1 - Funding Information: The work has been funded by the Japan Society for the Promotion of Science (JSPS) KAKENHI under Grant-in-aid Nos. 2522091, 26820311, and 26820313. L.Q. acknowledges the â€œInter-departmental Doctoral Degree Program for Multi-dimensional Materials Science Leadersâ€(MD Program) and A.R.W. acknowledges European Marie Curie Actions under ECOSTORE Grant Agreement No. 607040 for supporting this work. Technical assistance from Ms. N. Warifune is also greatly acknowledged. Publisher Copyright: © 2016 Author(s).

PY - 2016/5/23

Y1 - 2016/5/23

N2 - On the way to transform lithium amide (LiNH2) into lithium imide (Li2NH) by releasing H2, the 1:1 molar mixture of LiNH2-LiH forms cubic (F m 3 m) non-stoichiometric complex hydride phases (Li1+ xNH2- x; 0 < x < 1) that co-exist with the tetragonal (I 4) LiNH2 and with the cubic (F d 3 m) Li2NH, respectively, at the early and at the advanced stage of the dehydrogenation. The change in LiNH2 → Li2NH may be viewed as a mechanism which continuously fills up the vacant Li sites of the tetragonal structure and, in a parallel process, transforms the anions [NH2]- → [NH]2-. The Li-N-H system, thus formed, by releasing >6 wt. % H2 can offer high Li-ionic conductivity (>10-4 S·cm-1 at room temperature) having an electrochemical stability window >5 V. The study suggests that the Li-N-H system may be a prospective electrolyte in the all-solid-state Li-ion battery, in addition to its use as a reversible hydrogen storage material.

AB - On the way to transform lithium amide (LiNH2) into lithium imide (Li2NH) by releasing H2, the 1:1 molar mixture of LiNH2-LiH forms cubic (F m 3 m) non-stoichiometric complex hydride phases (Li1+ xNH2- x; 0 < x < 1) that co-exist with the tetragonal (I 4) LiNH2 and with the cubic (F d 3 m) Li2NH, respectively, at the early and at the advanced stage of the dehydrogenation. The change in LiNH2 → Li2NH may be viewed as a mechanism which continuously fills up the vacant Li sites of the tetragonal structure and, in a parallel process, transforms the anions [NH2]- → [NH]2-. The Li-N-H system, thus formed, by releasing >6 wt. % H2 can offer high Li-ionic conductivity (>10-4 S·cm-1 at room temperature) having an electrochemical stability window >5 V. The study suggests that the Li-N-H system may be a prospective electrolyte in the all-solid-state Li-ion battery, in addition to its use as a reversible hydrogen storage material.

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Effect of the structural evolution on the ionic conductivity of Li-N-H system during the dehydrogenation

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