TY - JOUR
T1 - The size dependence of hydrogen mobility and sorption kinetics for carbon-supported MgH2 particles
AU - Au, Yuen S.
AU - Obbink, Margo Klein
AU - Srinivasan, Subramanian
AU - Magusin, Pieter C M M
AU - De Jong, Krijn P.
AU - De Jongh, Petra E.
PY - 2014/6/18
Y1 - 2014/6/18
N2 - MgH2 is a promising material for reversible solid-state hydrogen storage. It is known that particle size can have a strong impact on hydrogen dynamics and sorption characteristics, but more detailed insight has been hampered by the great challenge to prepare small and well-defined particles and study their hydrogen storage properties upon cycling. The preparation of MgH2 nanoparticles supported on high surface area carbon aerogels with pore sizes varying from 6-20 nm is reported. Two distinctly different MgH2 particle populations are observed: X-ray diffraction invisible nanoparticles with sizes below 20 nm, and larger, crystalline, MgH2 particles. They release hydrogen at temperatures 140 °C lower than bulk MgH2. The size-dependent hydrogen kinetics is for the first time corroborated by intrinsic hydrogen dynamics data obtained by solid state 1H NMR. Fast cycling is possible (80% of the capacity absorbed within 15 min at 18 bar and 300 °C), without a change in the hydrogen sorption properties, showing that the growth of the nanoparticles is effectively prevented by the carbon support. A clear correlation is found between the hydrogen desorption temperature and the size of the MgH2 nanoparticles. This illustrates the potential of the use of supported nanoparticles for fast, reversible, and stable hydrogen cycling. Supported MgH2 nanoparticles on carbon with different sizes are synthesized and show faster hydrogen mobility and sorption kinetics. Nanoparticles with sizes below 20 nm have a significant lower hydrogen release temperature and the mobility is three orders of magnitude faster compared to micrometer sized MgH2. The smaller the MgH2 particles, the lower the hydrogen release temperatures become.
AB - MgH2 is a promising material for reversible solid-state hydrogen storage. It is known that particle size can have a strong impact on hydrogen dynamics and sorption characteristics, but more detailed insight has been hampered by the great challenge to prepare small and well-defined particles and study their hydrogen storage properties upon cycling. The preparation of MgH2 nanoparticles supported on high surface area carbon aerogels with pore sizes varying from 6-20 nm is reported. Two distinctly different MgH2 particle populations are observed: X-ray diffraction invisible nanoparticles with sizes below 20 nm, and larger, crystalline, MgH2 particles. They release hydrogen at temperatures 140 °C lower than bulk MgH2. The size-dependent hydrogen kinetics is for the first time corroborated by intrinsic hydrogen dynamics data obtained by solid state 1H NMR. Fast cycling is possible (80% of the capacity absorbed within 15 min at 18 bar and 300 °C), without a change in the hydrogen sorption properties, showing that the growth of the nanoparticles is effectively prevented by the carbon support. A clear correlation is found between the hydrogen desorption temperature and the size of the MgH2 nanoparticles. This illustrates the potential of the use of supported nanoparticles for fast, reversible, and stable hydrogen cycling. Supported MgH2 nanoparticles on carbon with different sizes are synthesized and show faster hydrogen mobility and sorption kinetics. Nanoparticles with sizes below 20 nm have a significant lower hydrogen release temperature and the mobility is three orders of magnitude faster compared to micrometer sized MgH2. The smaller the MgH2 particles, the lower the hydrogen release temperatures become.
KW - carbon support
KW - hydrogen mobility
KW - hydrogen sorption kinetics
KW - hydrogen storage
KW - magnesium hydrides
KW - nanoparticles
UR - http://www.scopus.com/inward/record.url?scp=84902366403&partnerID=8YFLogxK
U2 - 10.1002/adfm.201304060
DO - 10.1002/adfm.201304060
M3 - Article
AN - SCOPUS:84902366403
SN - 1616-301X
VL - 24
SP - 3604
EP - 3611
JO - Advanced Functional Materials
JF - Advanced Functional Materials
IS - 23
ER -