Hydrogen storage properties of nanoconfined LiBH 4 –NaBH 4

Javadian, Payam; Sheppard, Drew A.; Buckley, Craig E.

doi:10.1016/j.ijhydene.2015.08.075

Cited by 45 publications

(35 citation statements)

References 39 publications

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“…The temperature of the maximum hydrogen release rate of the mixed (T = 356˝C) and melt infiltrated samples (T = 364˝C) occur at significantly reduced temperatures (∆T~130˝C) as compared to that of bulk LiBH 4 -NaAlH 4 (T = 496˝C). This effect has previously been reported for other nanoconfined binary hydride systems that showed a reduction in the temperature of the maximum hydrogen release rate compared to bulk, e.g., LiBH 4 -Mg(BH 4 ) 2 (∆T max~´6 0˝C), LiBH 4 -Ca(BH 4 ) 2 (∆T max~´9 5˝C) and LiBH 4 -NaBH 4 (∆T max~´1 07˝C) [33][34][35].…”

Section: Decomposition Of Bulk and Nanocomposites Of 2libh 4 -Naalhsupporting

confidence: 78%

Hydrogen Desorption Properties of Bulk and Nanoconfined LiBH4-NaAlH4

2016

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Nanoconfinement of 2LiBH 4 -NaAlH 4 into a mesoporous carbon aerogel scaffold with a pore size, BET surface area and total pore volume of D max = 30 nm, S BET = 689 m 2 /g and V tot = 1.21 mL/g, respectively is investigated. Nanoconfinement of 2LiBH 4 -NaAlH 4 facilitates a reduction in the temperature of the hydrogen release by 132˝C, compared to that of bulk 2LiBH 4 -NaAlH 4 and the onset of hydrogen release is below 100˝C. The reversible hydrogen storage capacity is also significantly improved for the nanoconfined sample, maintaining 83% of the initial hydrogen content after three cycles compared to 47% for that of the bulk sample. During nanoconfinement, LiBH 4 and NaAlH 4 reacts to form LiAlH 4 and NaBH 4 and the final dehydrogenation products, obtained at 481˝C are LiH, LiAl, AlB 2 and Al. After rehydrogenation of the nanoconfined sample at T = 400˝C and p(H 2 ) = 126 bar, amorphous NaBH 4 is recovered along with unreacted LiH, AlB 2 and Al and suggests that NaBH 4 is the main compound that can reversibly release and uptake hydrogen.

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Section: Decomposition Of Bulk and Nanocomposites Of 2libh 4 -Naalhsupporting

confidence: 78%

Hydrogen Desorption Properties of Bulk and Nanoconfined LiBH4-NaAlH4

2016

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“…By increasing the surface-to-bulk atomic ratio, changes in the thermodynamics are foreseen. However, handling nanoparticles of metals or hydrides is very challenging and this is commonly done using a porous scaffold to stabilise the particles and to prevent them from coalescence [66].…”

Section: Nanoconfinementmentioning

confidence: 99%

Review of magnesium hydride-based materials: development and optimisation

et al. 2016

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Magnesium hydride has been studied extensively for applications as a hydrogen storage material owing to the favourable cost and high gravimetric and volumetric hydrogen densities. However, its high enthalpy of decomposition necessitates high working temperatures for hydrogen desorption while the slow rates for some processes such as hydrogen diffusion through the bulk create challenges for large-scale implementation. The present paper reviews fundamentals of the Mg-H system and looks at the recent advances in the optimisation of magnesium hydride as a hydrogen storage material through the use of catalytic additives, incorporation of defects and an understanding of the rate-limiting processes during absorption and desorption.

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“…A full rehydrogenation has not been obtained because of the limited H 2 pressure applied in the experimental conditions. As for previous studied mixtures [27][28][29][30][31], a hydrogen pressure of 100 bar is expected to fully rehydrogenate the systems. The nanoconfinement of the studied mixtures into a nanoporous scaffold to obtain nanostructured materials [13,15,19,20,[22][23][24][25]31,32] might be explored to improve the thermodynamics and kinetics of hydrogen sorption reactions and cyclability.…”

Section: Discussionmentioning

confidence: 90%

Reactive Hydride Composite of Mg2NiH4 with Borohydrides Eutectic Mixtures

et al. 2018

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Abstract:The development of materials showing hydrogen sorption reactions close to room temperature and ambient pressure will promote the use of hydrogen as energy carrier for mobile and stationary large-scale applications. In the present study, in order to reduce the thermodynamic stability of MgH 2 , Ni has been added to form Mg 2 NiH 4 , which has been mixed with various borohydrides to further tune hydrogen release reactions. De-hydrogenation/re-hydrogenation properties of Mg 2 NiH 4 -LiBH 4 -M(BH 4 ) x (M = Na, K, Mg, Ca) systems have been investigated. Mixtures of borohydrides have been selected to form eutectics, which provide a liquid phase at low temperatures, from 110 • C up to 216 • C. The presence of a liquid borohydride phase decreases the temperature of hydrogen release of Mg 2 NiH 4 but only slight differences have been detected by changing the borohydrides in the eutectic mixture.

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Hydrogen storage properties of nanoconfined LiBH 4 –NaBH 4

Cited by 45 publications

References 39 publications

Hydrogen Desorption Properties of Bulk and Nanoconfined LiBH4-NaAlH4

Hydrogen Desorption Properties of Bulk and Nanoconfined LiBH4-NaAlH4

Review of magnesium hydride-based materials: development and optimisation

Reactive Hydride Composite of Mg2NiH4 with Borohydrides Eutectic Mixtures

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