Effect of (Ti0.35V0.65)0.86Fe0.14Hy on synthesis and hydrogen storage properties of NaAlH4

Ya Dong Wang; Chang Run Li; Jia Bao Wen; Wei He Meng; Ke Wang; Sen Miao Zhao; Hai Zhen Liu; Cun Ke Huang; Jin Guo

doi:10.1016/j.ijhydene.2023.01.207

Effect of (Ti₀_.₃₅V_0.65)_0.86Fe_0.14H_y on synthesis and hydrogen storage properties of NaAlH₄

Ya Dong Wang, Chang Run Li, Jia Bao Wen, Wei He Meng, Ke Wang, Sen Miao Zhao, Hai Zhen Liu, Cun Ke Huang, Jin Guo

Guangxi University

科研成果: 期刊稿件 › 文章 › 同行评审

5 引用（Scopus）

摘要

The (Ti₀_.₃₅V_0.65)_0.86Fe_0.14H_y powder was prepared by melting, annealing and H₂-assisted-crushed method to avoid passivation. Then [(Ti₀_.₃₅V_0.65)_0.86Fe_0.14H_y]_x/100-NaAlH₄ composite system were synthesized using a two-step in-situ-milling method with the proportion of n (NaH):n (Al):n (Graphene):n (alloy) = 100:100:5:x (x = 2,5,8). It was found that lattice distortion had occurred on the alloy after 190hindividually milling, and the hydrogen storage capacity had decreased significantly to 1.10 wt%. However, after long-term composite milling, the alloy could still reduce the hydrogen pressure required for the synthesis of NaAlH₄, besides it could effectively reduce the hydriding/dehydriding temperature and improve the kinetic properties. This may due to the alloy's ability to dissociate H₂ and transfer H at room temperature, thereby enhancing the opportunity for direct contact between the matrix and H. In this study, x = 5 was the optimal alloy addition ratio, its dehydrogenation capacity at the 1st cycle reached 5.04 wt%; and at the 2nd and subsequent cycles, it remained rather stable at 4.40 wt%.

源语言	英语
页（从-至）	17593-17604
页数	12
期刊	International Journal of Hydrogen Energy
卷	48
期	46
DOI	https://doi.org/10.1016/j.ijhydene.2023.01.207
出版状态	已出版 - 29 5月 2023
已对外发布	是

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10.1016/j.ijhydene.2023.01.207

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@article{4e8a906d9978405a9255e6eddbe65f46,

title = "Effect of (Ti0.35V0.65)0.86Fe0.14Hy on synthesis and hydrogen storage properties of NaAlH4",

abstract = "The (Ti0.35V0.65)0.86Fe0.14Hy powder was prepared by melting, annealing and H2-assisted-crushed method to avoid passivation. Then [(Ti0.35V0.65)0.86Fe0.14Hy]x/100-NaAlH4 composite system were synthesized using a two-step in-situ-milling method with the proportion of n (NaH):n (Al):n (Graphene):n (alloy) = 100:100:5:x (x = 2,5,8). It was found that lattice distortion had occurred on the alloy after 190hindividually milling, and the hydrogen storage capacity had decreased significantly to 1.10 wt%. However, after long-term composite milling, the alloy could still reduce the hydrogen pressure required for the synthesis of NaAlH4, besides it could effectively reduce the hydriding/dehydriding temperature and improve the kinetic properties. This may due to the alloy's ability to dissociate H2 and transfer H at room temperature, thereby enhancing the opportunity for direct contact between the matrix and H. In this study, x = 5 was the optimal alloy addition ratio, its dehydrogenation capacity at the 1st cycle reached 5.04 wt%; and at the 2nd and subsequent cycles, it remained rather stable at 4.40 wt%.",

keywords = "Ball milling, BCC phase, Composite system, Hydrogen storage materials, NaAlH",

author = "Wang, {Ya Dong} and Li, {Chang Run} and Wen, {Jia Bao} and Meng, {Wei He} and Ke Wang and Zhao, {Sen Miao} and Liu, {Hai Zhen} and Huang, {Cun Ke} and Jin Guo",

note = "Publisher Copyright: {\textcopyright} 2023 Hydrogen Energy Publications LLC",

year = "2023",

month = may,

day = "29",

doi = "10.1016/j.ijhydene.2023.01.207",

language = "英语",

volume = "48",

pages = "17593--17604",

journal = "International Journal of Hydrogen Energy",

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}

TY - JOUR

T1 - Effect of (Ti0.35V0.65)0.86Fe0.14Hy on synthesis and hydrogen storage properties of NaAlH4

AU - Wang, Ya Dong

AU - Li, Chang Run

AU - Wen, Jia Bao

AU - Meng, Wei He

AU - Wang, Ke

AU - Zhao, Sen Miao

AU - Liu, Hai Zhen

AU - Huang, Cun Ke

AU - Guo, Jin

PY - 2023/5/29

Y1 - 2023/5/29

N2 - The (Ti0.35V0.65)0.86Fe0.14Hy powder was prepared by melting, annealing and H2-assisted-crushed method to avoid passivation. Then [(Ti0.35V0.65)0.86Fe0.14Hy]x/100-NaAlH4 composite system were synthesized using a two-step in-situ-milling method with the proportion of n (NaH):n (Al):n (Graphene):n (alloy) = 100:100:5:x (x = 2,5,8). It was found that lattice distortion had occurred on the alloy after 190hindividually milling, and the hydrogen storage capacity had decreased significantly to 1.10 wt%. However, after long-term composite milling, the alloy could still reduce the hydrogen pressure required for the synthesis of NaAlH4, besides it could effectively reduce the hydriding/dehydriding temperature and improve the kinetic properties. This may due to the alloy's ability to dissociate H2 and transfer H at room temperature, thereby enhancing the opportunity for direct contact between the matrix and H. In this study, x = 5 was the optimal alloy addition ratio, its dehydrogenation capacity at the 1st cycle reached 5.04 wt%; and at the 2nd and subsequent cycles, it remained rather stable at 4.40 wt%.

AB - The (Ti0.35V0.65)0.86Fe0.14Hy powder was prepared by melting, annealing and H2-assisted-crushed method to avoid passivation. Then [(Ti0.35V0.65)0.86Fe0.14Hy]x/100-NaAlH4 composite system were synthesized using a two-step in-situ-milling method with the proportion of n (NaH):n (Al):n (Graphene):n (alloy) = 100:100:5:x (x = 2,5,8). It was found that lattice distortion had occurred on the alloy after 190hindividually milling, and the hydrogen storage capacity had decreased significantly to 1.10 wt%. However, after long-term composite milling, the alloy could still reduce the hydrogen pressure required for the synthesis of NaAlH4, besides it could effectively reduce the hydriding/dehydriding temperature and improve the kinetic properties. This may due to the alloy's ability to dissociate H2 and transfer H at room temperature, thereby enhancing the opportunity for direct contact between the matrix and H. In this study, x = 5 was the optimal alloy addition ratio, its dehydrogenation capacity at the 1st cycle reached 5.04 wt%; and at the 2nd and subsequent cycles, it remained rather stable at 4.40 wt%.

KW - Ball milling

KW - BCC phase

KW - Composite system

KW - Hydrogen storage materials

KW - NaAlH

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DO - 10.1016/j.ijhydene.2023.01.207

M3 - 文章

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SN - 0360-3199

VL - 48

SP - 17593

EP - 17604

JO - International Journal of Hydrogen Energy

JF - International Journal of Hydrogen Energy

IS - 46

ER -

Effect of (Ti0.35V0.65)0.86Fe0.14Hy on synthesis and hydrogen storage properties of NaAlH4

摘要

联合国可持续发展目标

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引用此

Effect of (Ti₀_.₃₅V_0.65)_0.86Fe_0.14H_y on synthesis and hydrogen storage properties of NaAlH₄