Complex Hydrides for Energy Storage, Conversion, and Utilization

He, Teng; Cao, Hujun; Chen, Ping

doi:10.1002/adma.201902757

Cited by 165 publications

(70 citation statements)

References 277 publications

(168 reference statements)

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“…Molten salt preparation of metal hydrides should also be highly interesting for applications such as advanced catalysis 103 and energy storage. 104…”

Section: Green Production and Utilisation Of Hydrogen In Molten Saltsmentioning

confidence: 99%

Clean production and utilisation of hydrogen in molten salts

Kamali

2020

RSC Adv.

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“…Molten salt preparation of metal hydrides should also be highly interesting for applications such as advanced catalysis 103 and energy storage. 104…”

Section: Green Production and Utilisation Of Hydrogen In Molten Saltsmentioning

confidence: 99%

Clean production and utilisation of hydrogen in molten salts

Kamali

2020

RSC Adv.

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“…[10] However, the lack of safe and efficient hydrogen storage method is recognized as one of the major technological barriers for the large-scale hydrogen implementation. [11] Catalyst-assisted hydrolysis of ammonia borane (AB) with releasing 3 equiv. of H 2 has been shown to be one of the promising hydrogen carriers for storage and transportation.…”

Section: Introductionmentioning

confidence: 99%

Syntheses of Pt‐Ni Hollow Nanoalloy for Hydrogen Generation from Catalytic Hydrolysis of Ammonia Borane

Zhao

Pei

et al. 2020

ChemCatChem

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Efficient bimetallic nano‐catalysts consisting of both noble metals and non‐noble metals, are highly desired for the development of new hydrogen storage materials. In this work, supported Pt−Ni nanoalloys with hollow structures were successfully synthesized using galvanic replacement method and exhibited excellent catalytic activity with a turnover frequency as high as 302.3 molH2 ⋅ molmetal−1 ⋅ min−1 for the hydrolysis of ammonia borane. The chemical composition and structure of the alloy can be rationally controlled by the synthetic conditions, which further tune the catalytic activities of hydrogen evolution.

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“…Alanates are reported to be the most interesting systems followed by borohydride and amide 2 . During the past decades, the Ti‐doped NaAlH 4 system has led to extensive study on alanates as a reversible hydrogen storage material 22,23 . To date, numerous researches have focused on LiAlH 4 from the group of alanates due to the inferior desorption temperature.…”

Section: Introductionmentioning

confidence: 99%

Improved hydrogen storage performances of LiAlH ₄ + Mg( BH ₄ ) ₂ composite with TiF ₃ addition

et al. 2020

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Summary This paper studies on the preparation of the alanate‐borohydride combined system, LiAlH4 + Mg(BH4)2 with diverse molar ratios (1:1, 1:2, and 2:1) using the ball milling technique. The findings show that there is a mutual destabilization between the hydrides where the newly combined system has superior hydrogen storage performances as opposed to the unary components (LiAlH4 and Mg[BH4]2). Analysis on the initial decomposition temperature and isothermal de/hydrogenation kinetics has proven that the 2LiAlH4 + Mg(BH4)2 system possesses better performance. In an endeavor to ameliorate the performances of the hydrogen storage of 2LiAlH4 + Mg(BH4)2, the destabilized system was doped with TiF3. Three major steps of desorption were detected during the heating process in the 2LiAlH4 + Mg(BH4)2 system with and without the addition of TiF3, which are correlated to the decomposition of Mg(AlH4)2, MgH2 and LiBH4. It is found that 2LiAlH4 + Mg(BH4)2 + 5 wt.% TiF3 has decreased the initial decomposition temperature at about 60°C, which is 55°C lower than the non‐catalyzed 2LiAlH4 + Mg(BH4)2 system. The isothermal absorption/desorption kinetics of the 2LiAlH4 + Mg(BH4)2 system have also been enhanced by the addition of TiF3. The activation energy for Mg(AlH4)2‐, MgH2‐, and LiBH4‐relevant decomposition after doped 2LiAlH4 + Mg(BH4)2 with TiF3 are reduced to 36.5, 23.3, and 17.6 kJ mol−1. Studies on the structural characteristics analysis of the 2LiAlH4 + Mg(BH4)2 + TiF3 sample hint to the fact that the formation of the MgF2, LiF, TiH2 and Ti‐Al species, during desorption, is the main responsible factor for the observed thermodynamics change of the reactions by modifying the dehydrogenation and hydrogenation pathway. The catalytic role played by TiF3 may have encouraged the interaction between Mg(AlH4)2, MgH2, and LiBH4, further ameliorate the de/hydrogenation of the 2LiAlH4 + Mg(BH4)2 + TiF3 destabilized system.

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Complex Hydrides for Energy Storage, Conversion, and Utilization

Cited by 165 publications

References 277 publications

Clean production and utilisation of hydrogen in molten salts

Clean production and utilisation of hydrogen in molten salts

Syntheses of Pt‐Ni Hollow Nanoalloy for Hydrogen Generation from Catalytic Hydrolysis of Ammonia Borane

Improved hydrogen storage performances of LiAlH ₄ + Mg( BH ₄ ) ₂ composite with TiF ₃ addition

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Complex Hydrides for Energy Storage, Conversion, and Utilization

Cited by 165 publications

References 277 publications

Clean production and utilisation of hydrogen in molten salts

Clean production and utilisation of hydrogen in molten salts

Syntheses of Pt‐Ni Hollow Nanoalloy for Hydrogen Generation from Catalytic Hydrolysis of Ammonia Borane

Improved hydrogen storage performances of LiAlH 4 + Mg( BH 4 ) 2 composite with TiF 3 addition

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Improved hydrogen storage performances of LiAlH ₄ + Mg( BH ₄ ) ₂ composite with TiF ₃ addition