Hsin-Yu Yu scite author profile

Water and other small molecules frequently coordinate within metal‐organic frameworks (MOFs). These coordinated molecules may actively engage in mass transfer, moving together with the transport molecules, but this phenomenon has yet to be examined. In this study, we explore a unique water transfer mechanism in UTSA‐280, where an incoming water molecule can displace a coordinated molecule for mass transfer. We refer to this process as the 'knock‐off' mechanism. Despite UTSA‐280 possessing one‐dimensional channels, the knock‐off transport enables water movement along the other two axes, effectively simulating a pseudo‐three‐dimensional mass transfer. Even with a relatively narrow pore width, the knock‐off mechanism enables a water flux in the UTSA‐280 membrane. The knock‐off mechanism also renders UTSA‐280 superior water/ethanol diffusion selectivity for pervaporation. To validate this unique mechanism, we conducted 1H and 2H solid‐state NMR on UTSA‐280 after the adsorption of deuterated water. We also derived potential energy diagrams from the density functional theory to gain atomic‐level insight into the knock‐off and the direct‐hopping mechanisms. The simulation findings reveal that the energy barrier of the knock‐off mechanism is marginally lower than the direct‐hopping pathway, implying its potential role in enhancing water diffusion in UTSA‐280.

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Fast Water Transport in UTSA‐280 via a Knock‐Off Mechanism

Hsu

¹

,

Yu

²

,

Lee

³

et al. 2023

Angewandte Chemie

0

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Water and other small molecules frequently coordinate within metal‐organic frameworks (MOFs). These coordinated molecules may actively engage in mass transfer, moving together with the transport molecules, but this phenomenon has yet to be examined. In this study, we explore a unique water transfer mechanism in UTSA‐280, where an incoming water molecule can displace a coordinated molecule for mass transfer. We refer to this process as the 'knock‐off' mechanism. Despite UTSA‐280 possessing one‐dimensional channels, the knock‐off transport enables water movement along the other two axes, effectively simulating a pseudo‐three‐dimensional mass transfer. Even with a relatively narrow pore width, the knock‐off mechanism enables a water flux in the UTSA‐280 membrane. The knock‐off mechanism also renders UTSA‐280 superior water/ethanol diffusion selectivity for pervaporation. To validate this unique mechanism, we conducted 1H and 2H solid‐state NMR on UTSA‐280 after the adsorption of deuterated water. We also derived potential energy diagrams from the density functional theory to gain atomic‐level insight into the knock‐off and the direct‐hopping mechanisms. The simulation findings reveal that the energy barrier of the knock‐off mechanism is marginally lower than the direct‐hopping pathway, implying its potential role in enhancing water diffusion in UTSA‐280.

show abstract

Hsin-Yu Yu

Factors structuring the macrobenthos community in tidal algal reefs

Fast Water Transport in UTSA‐280 via a Knock‐Off Mechanism

Fast Water Transport in UTSA‐280 via a Knock‐Off Mechanism

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