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MgH 2 nanoparticles confined in reduced graphene oxide pillared with organosilica: a novel type of hydrogen storage material.

Feng YanEstela Moretón AlfonsínPeter NgeneSytze de GraafOreste De LucaHuatang CaoKonstantinos SpyrouLiqiang LuEleni ThomouYutao PeiBart J KooiDimitrios Panagiotis GournisPetra E de JonghPetra Rudolf
Published in: Nanoscale (2024)
Hydrogen is a promising alternative fuel that can push forward the energy transition because of its high energy density (142 MJ kg -1 ), variety of potential sources, low weight and low environmental impact, but its storage for automotive applications remains a formidable challenge. MgH 2 , with its high gravimetric and volumetric density, presents a compelling platform for hydrogen storage; however, its utilization is hindered by the sluggish kinetics of hydrogen uptake/release and high temperature operation. Herein we show that a novel layered heterostructure of reduced graphene oxide and organosilica with high specific surface area and narrow pore size distribution can serve as a scaffold to host MgH 2 nanoparticles with a narrow diameter distribution around ∼2.5 nm and superior hydrogen storage properties to bulk MgH 2 . Desorption studies showed that hydrogen release starts at relatively low temperature, with a maximum at 348 °C and kinetics dependent on particle size. Reversibility tests demonstrated that the dehydrogenation kinetics and re-hydrogenation capacity of the system remains stable at 1.62 wt% over four cycles at 200 °C. Our results prove that MgH 2 confinement in a nanoporous scaffold is an efficient way to constrain the size of the hydride particles, avoid aggregation and improve kinetics for hydrogen release and recharging.
Keyphrases
  • reduced graphene oxide
  • gold nanoparticles
  • visible light
  • body mass index
  • high temperature
  • risk assessment
  • climate change
  • human health
  • tissue engineering
  • life cycle
  • case control