Electrodeposited Magnesium Nanoparticles Linking Particle Size to Activation Energy

Shen, Chaoqi; Aguey‐Zinsou, Kondo‐François

doi:10.3390/en9121073

Cited by 11 publications

(11 citation statements)

References 44 publications

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“…The hydrogen absorption process is one step in forming a MgH 2 layer based on the reaction between Mg and hydrogen on the surface of Mg particles. The significant kinetics difference between the Mg nanoparticles and the 325 mesh Mg is because the Mg nanomaterials show a large surface area and a small particle/grain size [6,25,45], meaning that Mg nanomaterials have a much greater contact area for the hydrogen reaction, and a much shorter diffusion distance for hydrogen diffusion during the hydrogen absorption reaction [1,6,46,47]. For real storage application, both absorption and desorption properties, including the hydrogen capacity and kinetics, are essential for hydrogen intake and subsequent supply to the SOFC component.…”

Section: Resultsmentioning

confidence: 99%

Heat Modeling and Material Development of Mg-Based Nanomaterials Combined with Solid Oxide Fuel Cell for Stationary Energy Storage

Shao

2017

Energies

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Mg-based materials have been investigated as hydrogen storage materials, especially for possible onboard storage in fuel cell vehicles for decades. Recently, with the development of large-scale fuel cell technologies, the development of Mg-based materials as stationary storage to supply hydrogen to fuel-cell components and provide electricity and heat is becoming increasingly promising. In this work, numerical analysis of heat balance management for stationary solid oxide fuel cell (SOFC) systems combined with MgH 2 materials based on a carbon-neutral design concept was performed. Waste heat from the SOFC is supplied to hydrogen desorption as endothermic heat for the MgH 2 materials. The net efficiency of this model achieves 82% lower heating value (LHV), and the efficiency of electrical power output becomes 68.6% in minimizing heat output per total energy output when all available heat of waste gas and system is supplied to warm up the storage. For the development of Mg-based hydrogen storage materials, various nano-processing techniques have been widely applied to synthesize Mg-based materials with small particle and crystallite sizes, resulting in good hydrogen storage kinetics, but poor thermal conductivity. Here, three kinds of Mg-based materials were investigated and compared: 325 mesh Mg powers, 300 nm Mg nanoparticles synthesized by hydrogen plasma metal reaction, and Mg 50 Co 50 metastable alloy with body-centered cubic structure. Based on the overall performances of hydrogen capacity, absorption kinetics and thermal conductivity of the materials, the Mg nanoparticle sample by plasma synthesis is the most promising material for this potential application. The findings in this paper may shed light on a new energy conversion and utilization technology on MgH 2-SOFC combined concept.

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Section: Resultsmentioning

confidence: 99%

Heat Modeling and Material Development of Mg-Based Nanomaterials Combined with Solid Oxide Fuel Cell for Stationary Energy Storage

Shao

2017

Energies

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“…We previously reported on the electrochemistry of MgBu2 and at a current of 0.5 mA cm −2 , this Mg precursor is readily reduced into metallic Mg (Shen and Aguey-Zinsou, 2016). The XRD pattern of the pristine CNTs ( Figure 1A) shows the (002) peak around 26 corresponding to the inter-planar spacing of 0.34 nm (Kawasaki et al, 2005).…”

Section: Resultsmentioning

confidence: 99%

Nanosized Magnesium Electrochemically Deposited on a Carbon Nanotubes Suspension: Synthesis and Hydrogen Storage

Shen

Aguey‐Zinsou

2017

Front. Energy Res.

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Herein, we report on a novel method for deposition of magnesium (Mg) nanoparticles at the surface of carbon materials. Through the suspension of carbon nanotubes (CNTs) in an electrolyte containing di-n-butylmagnesium as a precursor, Mg nanoparticles were effectively deposited at the surface of the CNTs as soon as these touched the working electrode. Through this process, CNTs supported Mg particles as small as 1 nm were synthesized and the distribution of the nanoparticles was found to be influenced by the concentration of the CNTs in the electrolyte. Hydrogenation of these nanoparticles at 100°C was found to lead to low temperature hydrogen release starting at 150°C, owing to shorter diffusion paths and higher hydrogen mobility in small Mg particles. However, these hydrogen properties drastically degraded as soon as the hydrogenation temperature exceeded 200°C and this may be related to the low melting temperature of ultrasmall Mg particles.

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“…Nanocrystalline materials, characterised by a crystal size < 100 nm, can be formed by techniques including vapour condensation, [179] sputtering, [180] thermal decomposition, [181] chemical precipitation [182] and so on. [183] But the advantage of mechanical milling is in the possibility of producing bulk quantities of material. However, from a commercial perspective, mechanical milling remains an expensive production method and alternatives in the forms of high pressure torsions, equal channel angular pressing, and cold rolling have been proposed.…”

Section: Nanostructured Hydridesmentioning

confidence: 99%

“…(a) Size dependence E a for Mg synthesised by chemical reduction [53a, 311a] and electrochemical deposition; [183] (b) correlation between A and E a for Mg nanoparticles. Values were extracted from the literature.…”

Section: Full Hydrogen Release In 120 Minmentioning

confidence: 99%

How to Design Hydrogen Storage Materials? Fundamentals, Synthesis, and Storage Tanks

Lai

Sun

Wang

et al. 2019

Advanced Sustainable Systems

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Electrodeposited Magnesium Nanoparticles Linking Particle Size to Activation Energy

Cited by 11 publications

References 44 publications

Heat Modeling and Material Development of Mg-Based Nanomaterials Combined with Solid Oxide Fuel Cell for Stationary Energy Storage

Heat Modeling and Material Development of Mg-Based Nanomaterials Combined with Solid Oxide Fuel Cell for Stationary Energy Storage

Nanosized Magnesium Electrochemically Deposited on a Carbon Nanotubes Suspension: Synthesis and Hydrogen Storage

How to Design Hydrogen Storage Materials? Fundamentals, Synthesis, and Storage Tanks

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