Abstract
As humanity transitions to a low-carbon future, hydrogen, with its high energy density and zero carbon emissions, is gaining prominence, and efficient hydrogen storage is thus a critical area of research. Storing hydrogen in a solid form by forming hydrates, ensuring straightforward formation and dissociation, environmental friendliness, and stability, is emerging as a new technology. In particular, the use of thermodynamic promoters such as tetrahydrofuran (THF) to form binary hydrogen hydrates enables hydrogen storage under much milder conditions compared to traditional compression and liquefaction processes. However, slow hydrate formation kinetics currently hinder commercialization, necessitating breakthroughs in this area. This study reports extremely rapid and high hydrogen uptake in binary hydrogen + THF hydrates by utilizing a water-in-oil emulsion. A hydrogen storage capacity of approximately 51.23 mmol H2/mol H2O and the hydrogen uptake rate of 91.71 mol min−1 m−3 water were achieved, significantly outperforming existing studies conducted at pressures below 15 MPa. This remarkable kinetics was achieved by controlling the distribution of THF within a ternary emulsion system composed of water, isooctane, and THF. Phase equilibrium measurements and a series of kinetic tests validated that using an excess of THF over stoichiometric amounts can lead to such high and rapid hydrogen uptake. Consequently, a hydrate formation mechanism in the emulsified system was suggested based on the results of a Raman analysis, water droplet size measurements, and 1H NMR analysis. These results will pave the way for further advances in practical hydrate-based hydrogen storage technology.
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