The power of multifunctional metal hydrides: A key enabler beyond hydrogen storage

Salman, Muhammad; Lai, Qiwen; Luo, Xinyi; Pratthana, Chulaluck; Rambhujun, Nigel; Costalin, Mehdi; Wang, Ting; Sapkota, Prabal; Liu, Wei; Grahame, Aiden; Tupe, Joseph; Aguey‐Zinsou, Kondo‐François

doi:10.1016/j.jallcom.2022.165936

Cited by 22 publications

(8 citation statements)

References 347 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This, however, is a promising technology if more hydrogen can be released that way. MgH 2 is also often considered, as it is more stable, safer and has lower release temperatures than LiH (Salman et al, 2022). MgH 2 can store about 7.6 wt% of hydrogen (Hoecke et al, 2021;Salman et al, 2022).…”

Section: Elemental Hydridesmentioning

confidence: 99%

“…MgH 2 is also often considered, as it is more stable, safer and has lower release temperatures than LiH (Salman et al, 2022). MgH 2 can store about 7.6 wt% of hydrogen (Hoecke et al, 2021;Salman et al, 2022). It again has a rather high decomposition temperature (573 K) and it is hard to completely hydrogenate magnesium, as it is a surface reaction (Hoecke et al, 2021).…”

Section: Elemental Hydridesmentioning

confidence: 99%

See 1 more Smart Citation

A review of the potential of hydrogen carriers for zero emission, low signature ship propulsion systems

Rheenen¹,

Padding²,

Slootweg³

et al. 2022

Preprint

View full text Add to dashboard Cite

Increasing pressure on the reduction or elimination of the use of fossil fuels in shipping requires the application of new maritime fuel alternatives. Green and circular produced hydrogen as a maritime fuel in fuel cell systems offers a great solution for these concerns. A fuel cell system has a zero emission performance, solid state silent process cycle, graceful degradation and no single point of failure. From a naval perspective, these characteristics very much support operational requirements like a silent propulsion and very low thermal and acoustic signatures as well as the possibility of an air independent system. Storage of hydrogen, however, is an issue. Traditional hydrogen storage in gas or liquefied aggregation has low volumetric density, low flame point, fire and explosion risks and transport challenges. The aim of this literature review is to investigate several hydrogen carriers and evaluate their characteristics on maritime and naval performance. This includes their volumetric and gravimetric density, dehydrogenation process, safety, logistic availability and handling. Over 15 different (types of) hydrogen carriers have been researched. Borohydrides, specifically sodium borohydride appeared to have several advantages, but still has issues with its hydrogenation process and handling due to it being a solid. The liquid organic hydrogen carrier dibenzyl toluene, on the other hand, does not meet the required energy density, but does have favourable additional properties, such as easy hydrogenation and good handling. Both of these are also subject of current research and development: For example, Hydrogenious LOHC Maritime AS, in combination with Østensjø Rederi, is working on a megawatt application for maritime, which should be finished in 2025. The Dutch government funds the SH2IPDRIVE project and the European Interreg North West Europe organization funds the H2SHIPS research project to analyse the shipboard use of these hydrogen carriers and to establish the design and engineering optimization opportunities.

show abstract

Section: Elemental Hydridesmentioning

confidence: 99%

Section: Elemental Hydridesmentioning

confidence: 99%

A review of the potential of hydrogen carriers for zero emission, low signature ship propulsion systems

Rheenen¹,

Padding²,

Slootweg³

et al. 2022

Preprint

View full text Add to dashboard Cite

show abstract

“…3 Metal hydrides have been reported to be suitable for diverse applications including fuel cells, hydrogen storage, and solid state batteries but they also show exceptional properties for TCES, with volumetric energy storage densities up to 2423 kW h th m −3 and operating temperatures ranging from 200 to 1000 °C. [4][5][6] A recent paper by Adams et al highlighted the advantages of metal hydrides for TCES, and addressed the challenges related to their implementation in large-scale systems in terms of reaction modelling, reactor material selection and design. 7 Hardy et al modelled a high-temperature TCES system operating with a metal hydride pair for solar energy storage; of which the outcomes conrmed that appropriate operating conditions and sizing are crucial to ensure the viability of the system and avoid failure due to thermal ratcheting.…”

Section: Introductionmentioning

confidence: 99%

Calcium hydride with aluminium for thermochemical energy storage applications

Desage,

Humphries,

Paskevicius

et al. 2024

Sustainable Energy Fuels

View full text Add to dashboard Cite

show abstract

“…Another method is to store hydrogen in metal hydrides. Metal hydrides are the most promising candidate material for solid hydrogen storage [ 26 ]. Among them, Ni-based alloys have gained much attention for hydrogen storage and related applications [ 27 ].…”

Section: Introductionmentioning

confidence: 99%

“…Ni–Pd–P alloys have extraordinary stability [ 28 ]. Adding B to these alloys increases the crystallization temperature and hardness [ 26 , 29 , 30 , 31 , 32 ]. Crystalline boron is stable and inert to acids.…”

Section: Introductionmentioning

confidence: 99%

Electrochemical Performance and Hydrogen Storage of Ni–Pd–P–B Glassy Alloy

et al. 2022

View full text Add to dashboard Cite

The search for hydrogen storage materials is a challenging task. In this work, we tried to test metallic glass-based pseudocapacitive material for electrochemical hydrogen storage potential. An alloy ingot with an atomic composition of Ni60Pd20P16B4 was prepared via arc melting of extremely pure elements in an Ar environment. A ribbon sample with a width of 2 mm and a thickness of 20 mm was produced via melt spinning of the prepared ingot. Electrochemical dealloying of the ribbon sample was conducted in 1 M H2SO4 to prepare a nanoporous glassy alloy. The Brunauer–Emmett–Teller (BET) and Langmuir methods were implemented to obtain the total surface area of the nanoporous glassy alloy ribbon. The obtained values were 6.486 m2/g and 15.082 m2/g, respectively. The Dubinin–Astakhov (DA) method was used to calculate pore radius and pore volume; those values were 1.07 nm and 0.09 cm3/g, respectively. Cyclic voltammetry of the dealloyed samples revealed the pseudocapacitive nature of this alloy. Impedance of the dealloying sample was measured at different frequencies through use of electrochemical impedance spectroscopy (EIS). A Cole–Cole plot established a semicircle with a radius of ~6 Ω at higher frequency, indicating low interfacial charge-transfer resistance, and an almost vertical Warburg slope at lower frequency, indicating fast diffusion of ions to the electrode surface. Charge–discharge experiments were performed at different constant currents (75, 100, 125, 150, and 200 mA/g) under a cutoff potential of 2.25 V vs. Ag/AgCl electrode in a 1 M KOH solution. The calculated maximum storage capacity was 950 mAh/g. High-rate dischargeability (HRD) and capacity retention (Sn) for the dealloyed glassy alloy ribbon sample were evaluated. The calculated capacity retention rate at the 40th cycle was 97%, which reveals high stability.

show abstract

The power of multifunctional metal hydrides: A key enabler beyond hydrogen storage

Cited by 22 publications

References 347 publications

A review of the potential of hydrogen carriers for zero emission, low signature ship propulsion systems

A review of the potential of hydrogen carriers for zero emission, low signature ship propulsion systems

Calcium hydride with aluminium for thermochemical energy storage applications

Electrochemical Performance and Hydrogen Storage of Ni–Pd–P–B Glassy Alloy

Contact Info

Product

Resources

About