An Overview of the Recent Advances of Additive-Improved Mg(BH4)2 for Solid-State Hydrogen Storage Material

Sazelee, N.A.; Ali, N.A.; Ismail, M.

doi:10.3390/en15030862

Cited by 19 publications

(4 citation statements)

References 142 publications

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“…The most detailed study on this issue was published by Yartys and co-workers who applied in situ X-ray diffraction to reveal the phase evolution of different Mg-based systems during hydrogentation-dehydrogation; however, no data are available on the crystallite size during isothermal absorption [75,76]. For more complex systems, such as Mg-TM [77] or complex hydrides [78], hydrogen uptake is usually a multi-step process; therefore, fitting the absorption curve by a single function is not possible.…”

Section: Resultsmentioning

confidence: 99%

Time-Dependent Multi-Particle Model Describing the Hydrogen Absorption of Nanocrystalline Magnesium Powders: A Case Study

Révész,

Pintér

2024

Energies

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Classical kinetic models describing the hydrogen absorption of nanocrystalline metallic hydrides generally do not involve any parameter related to the change in the crystallite size during the hydrogenation at constant temperature. In the present investigation, ball-milled nanocrystalline Mg powders exhibiting lognormal crystallite size distribution have been subjected to hydrogen absorption in a Sievert-type apparatus. Partially absorbed states were achieved by interrupting the hydrogenation cycle at different hydrogen content, i.e., when 15%, 50%, and 90% of Mg powder transformed to MgH2. The evolution of the characteristic size of the nucleating MgH2 phase was determined from X-ray diffraction analysis. Considering the crystallite size distribution of the as-milled powder agglomerate as well as the growth during the isothermal hydrogenation process, a time-dependent multi-particle reaction function ∝CV¯t;R(t) was developed. It was shown unambiguously for this case study that the measured hydrogen absorption curve of the ball-milled Mg powder shows the best correlation with this model when it is compared to classical kinetic functions or the previously developed multi-particle reaction function excluding the change in the average crystallite size during hydrogenation.

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Section: Resultsmentioning

confidence: 99%

Time-Dependent Multi-Particle Model Describing the Hydrogen Absorption of Nanocrystalline Magnesium Powders: A Case Study

Révész,

Pintér

2024

Energies

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“…In order to foresee any use in automotive hydrogen storage systems, it would be optimal to allow H desorption from the materials using only residual heat from a fuel cell; some modeling proposed a dehydrogenation enthalpy of 27 kJ molH 2 –1 as an optimal value for this application . To achieve reversible operations at more practical conditions with complex metal hydrides, catalysts and additives are normally used. − Two other strategies more recently explored to achieve realistic operation conditions are the destabilization of the lightweight complex hydrides using a second hydride (the so-called reactive hydride composites , ) and the nanoconfinement of the hydride to modify the kinetics and/or thermodynamics . It is also worth remarking here that several metal hydride materials involve safety risks (burning when exposed to air/water, toxicity, skin burns, etc.…”

Section: Discussionmentioning

confidence: 99%

Exceptional Hydrogen Uptake in Crystalline In_xGa_1–xN Semiconductors

Ciatto,

Filippone,

Polimeni

et al. 2024

ACS Appl. Mater. Interfaces

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The irradiation of InN and In x Ga 1−x N samples with low-energy H ions results in exceptionally high hydrogen uptake in a crystalline semiconductor. This phenomenon is attributed to specific In−H complex formation. By exploiting spectral fingerprints of the In−H complexes observable in In L3-edge X-ray absorption spectroscopy, we provide direct evidence of complex formation. Density functional theory calculations assist in interpreting the X-ray absorption spectra and offer insights into the energetics of complex formation. We quantify the total amount of reversibly incorporated hydrogen in these semiconductors and discuss their strengths and weaknesses as innovative materials for hydrogen storage.

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“…The kinetic barriers of complex hydrides can be significantly reduced using various types of catalysts, and there have been several reviews describing the kinetic modification of complex hydrides by adding catalysts to NaAlH 4 , , LiAlH 4 , LiBH 4 , and Mg(BH 4 ) 2 . In particular, the kinetics of NaAlH 4 has been extensively studied since it allows pure H 2 release and exhibits a good cyclability upon a proper modification, and numerous works demonstrated that the dehydrogenation kinetic barrier of NaAlH 4 can be reduced by employing catalyst doping or nanoconfinement.…”

Section: Fundamentals Of Thermodynamic and Kinetic Barriers For Hydro...mentioning

confidence: 99%

Nanointerface Engineering of Metal Hydrides for Advanced Hydrogen Storage

Cho

2023

Chem. Mater.

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With global efforts to relieve the formidable impact of climate change, hydrogen is considered a viable replacement for fossil fuels without intermittency concerns of other renewable sources. Hydrogen storage plays a pivotal role in the implementation of hydrogen economy, coupling hydrogen production with fuel cell technologies. Storing hydrogen in the form of solid-state hydride materials has been studied as a future hydrogen storage technology for enabling a safe, energy-efficient, and high-energy-density system. However, hostile thermodynamic and kinetic properties of each hydride material result in insufficient hydrogen storage performance for practical applications, such as sluggish hydrogen absorption or desorption, high dehydrogenation temperatures, and sometimes limited reversibility; thus, these kinetic and thermodynamic characteristics need to be thoroughly understood depending on each hydride material. Among various strategies, nanostructuring has been regarded as a general approach to tackling such limitations regarding thermodynamic and kinetic characteristics of hydride materials. In particular, the formation of nanosized hydrides within a nanostructured scaffoldalso known as nanoconfinementis of great potential for advanced hydrogen storage because it can additionally leverage host–guest interactions at the nanointerfaces of hydride materials and scaffolds. In this context, the active tuning of such nanointerfaces brings about additional thermodynamic or kinetic changes in hydrogen sorption reactions compared to the unmodified nanoconfined hydride composites, holding great promise for tailored strategies for each metal hydride. In this Perspective, we summarize the major thermodynamic and kinetic barriers of each metal hydride and highlight the recent progress in overcoming such limits, mainly focusing on nanointerface engineering in nanoconfined metal hydrides. Further, we provide our insight and current challenges in understanding the underlying mechanisms of the interaction at the nanointerface, whereby the noticeable technological leaps can be emulated in practical systems.

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An Overview of the Recent Advances of Additive-Improved Mg(BH4)2 for Solid-State Hydrogen Storage Material

Cited by 19 publications

References 142 publications

Time-Dependent Multi-Particle Model Describing the Hydrogen Absorption of Nanocrystalline Magnesium Powders: A Case Study

Time-Dependent Multi-Particle Model Describing the Hydrogen Absorption of Nanocrystalline Magnesium Powders: A Case Study

Exceptional Hydrogen Uptake in Crystalline In_xGa_1–xN Semiconductors

Nanointerface Engineering of Metal Hydrides for Advanced Hydrogen Storage

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An Overview of the Recent Advances of Additive-Improved Mg(BH4)2 for Solid-State Hydrogen Storage Material

Cited by 19 publications

References 142 publications

Time-Dependent Multi-Particle Model Describing the Hydrogen Absorption of Nanocrystalline Magnesium Powders: A Case Study

Time-Dependent Multi-Particle Model Describing the Hydrogen Absorption of Nanocrystalline Magnesium Powders: A Case Study

Exceptional Hydrogen Uptake in Crystalline InxGa1–xN Semiconductors

Nanointerface Engineering of Metal Hydrides for Advanced Hydrogen Storage

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Product

Resources

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Exceptional Hydrogen Uptake in Crystalline In_xGa_1–xN Semiconductors