A pore-network model couples transient mass transfer and capillary heterogeneity to simulate dynamic Ostwald ripening in Bentheimer sandstone, reproducing cluster coarsening and drainage-driven growth observed in experiments.
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A model identifies dissolved hydrogen transport as the overlooked limiter in LOHC dehydrogenation, producing two kinetic regimes based on whether hydrogen exits via bubbles or diffusion, with bubbling onset set by supersaturation and capillarity.
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Time-dependent pore-network modelling of Ostwald ripening in porous media
A pore-network model couples transient mass transfer and capillary heterogeneity to simulate dynamic Ostwald ripening in Bentheimer sandstone, reproducing cluster coarsening and drainage-driven growth observed in experiments.
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How back reaction, hydrogen transport, and capillarity control the performance of hydrogen release from liquid organic carriers
A model identifies dissolved hydrogen transport as the overlooked limiter in LOHC dehydrogenation, producing two kinetic regimes based on whether hydrogen exits via bubbles or diffusion, with bubbling onset set by supersaturation and capillarity.