Effect of the deposition technique on the metallurgy and hydrogen storage characteristics of metastable MgyTi(1-y) thin films

P. Vermeulen; R.A.H. Niessen; D.M. Borsa; B. Dam; R. Griessen; P.H.L. Notten

doi:10.1149/1.2345548

Effect of the deposition technique on the metallurgy and hydrogen storage characteristics of metastable MgyTi(1-y) thin films

P. Vermeulen, R.A.H. Niessen, D.M. Borsa, B. Dam, R. Griessen, P.H.L. Notten

Inorganic Materials & Catalysis

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Abstract

MgyTi(1-y) alloys with 0.50¿¿¿¿.00 were prepared by electron beam deposition and magnetron co-sputter deposition. The effects of the deposition technique are discussed in two ways: the metallurgy of the as-deposited films and the hydrogen storage characteristics. In spite of the fact that for both preparation methods similar unit cell dimensions are found, the broader XRD peaks of e-beam deposited alloys indicate a relatively small grain size. Electrochemical characterization of the compounds upon (de)hydrogenation shows that the deposition method does not significantly influence the hydrogen capacity and kinetics. Moreover, essentially the same cycle-life behavior is found for both types of alloys.

Original language	English
Pages (from-to)	A520-A523
Number of pages	4
Journal	Electrochemical and Solid-State Letters
Volume	9
Issue number	11
DOIs	https://doi.org/10.1149/1.2345548
Publication status	Published - 2006

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title = "Effect of the deposition technique on the metallurgy and hydrogen storage characteristics of metastable MgyTi(1-y) thin films",

abstract = "MgyTi(1-y) alloys with 0.50¿¿¿¿.00 were prepared by electron beam deposition and magnetron co-sputter deposition. The effects of the deposition technique are discussed in two ways: the metallurgy of the as-deposited films and the hydrogen storage characteristics. In spite of the fact that for both preparation methods similar unit cell dimensions are found, the broader XRD peaks of e-beam deposited alloys indicate a relatively small grain size. Electrochemical characterization of the compounds upon (de)hydrogenation shows that the deposition method does not significantly influence the hydrogen capacity and kinetics. Moreover, essentially the same cycle-life behavior is found for both types of alloys.",

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T1 - Effect of the deposition technique on the metallurgy and hydrogen storage characteristics of metastable MgyTi(1-y) thin films

AU - Vermeulen, P.

AU - Niessen, R.A.H.

AU - Borsa, D.M.

AU - Dam, B.

AU - Griessen, R.

AU - Notten, P.H.L.

PY - 2006

Y1 - 2006

N2 - MgyTi(1-y) alloys with 0.50¿¿¿¿.00 were prepared by electron beam deposition and magnetron co-sputter deposition. The effects of the deposition technique are discussed in two ways: the metallurgy of the as-deposited films and the hydrogen storage characteristics. In spite of the fact that for both preparation methods similar unit cell dimensions are found, the broader XRD peaks of e-beam deposited alloys indicate a relatively small grain size. Electrochemical characterization of the compounds upon (de)hydrogenation shows that the deposition method does not significantly influence the hydrogen capacity and kinetics. Moreover, essentially the same cycle-life behavior is found for both types of alloys.

AB - MgyTi(1-y) alloys with 0.50¿¿¿¿.00 were prepared by electron beam deposition and magnetron co-sputter deposition. The effects of the deposition technique are discussed in two ways: the metallurgy of the as-deposited films and the hydrogen storage characteristics. In spite of the fact that for both preparation methods similar unit cell dimensions are found, the broader XRD peaks of e-beam deposited alloys indicate a relatively small grain size. Electrochemical characterization of the compounds upon (de)hydrogenation shows that the deposition method does not significantly influence the hydrogen capacity and kinetics. Moreover, essentially the same cycle-life behavior is found for both types of alloys.

U2 - 10.1149/1.2345548

DO - 10.1149/1.2345548

M3 - Article

SN - 1099-0062

VL - 9

SP - A520-A523

JO - Electrochemical and Solid-State Letters

JF - Electrochemical and Solid-State Letters

IS - 11

ER -

Effect of the deposition technique on the metallurgy and hydrogen storage characteristics of metastable MgyTi(1-y) thin films

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