B1-mobilstor: Materials for sustainable energy storage techniques - Lithium containing compounds for hydrogen and electrochemical energy storage

Bö Hme, B.; Minella, C.; Thoss, F.; Lindemann, I.; Rosenburg, M.; Pistidda, C.; Moller, Kasper; Jensen, T.; Giebeler, L.; Baitinger, M.; Gutfleisch, O.; Ehrenberg, H.; Eckert, J.; Grin, Y.; Schultz, L.

doi:10.1002/adem.201400182

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Authors

Bö Hme, B.

Minella, C.

Thoss, F.

Lindemann, I.

Rosenburg, M.

Pistidda, C.

Moller, Kasper

Jensen, T.

Giebeler, L.

Baitinger, M.

Gutfleisch, O.

Ehrenberg, H.

Eckert, J.

Grin, Y.

Schultz, L.

Date

2014

Type

Journal Article

Metadata

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Citation

Bö Hme, B. and Minella, C. and Thoss, F. and Lindemann, I. and Rosenburg, M. and Pistidda, C. and Moller, K. et al. 2014. B1-mobilstor: Materials for sustainable energy storage techniques - Lithium containing compounds for hydrogen and electrochemical energy storage. Advanced Engineering Materials. 16 (10): pp. 1189-1195.

Source Title

Advanced Engineering Materials

DOI

10.1002/adem.201400182

ISSN

1438-1656

School

School of Electrical Engineering, Computing and Mathematical Science (EECMS)

URI

http://hdl.handle.net/20.500.11937/71447

Collection

Curtin Research Publications

Abstract

© 2014 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim. New material concepts for hydrogen storage and lithium ion batteries are investigated in the joint ECEMP project B1 - Mobilstor. Chemical composition are essential for the performance of a storage material. A certain state of material can be effectively analyzed by in situ methods to obtain a maximum of information. For hydrogen storage the LiNH2MgH2system and as lithium ion batteryanode the Ge(cF136) allotrop are highlighted under this issue.