Temperature-regulated guest admission and release in microporous materials

Gang (Kevin) Li; Jin Shang; Qinfen Gu; Rohan V. Awati; Nathan Jensen; Andrew Grant; Xueying Zhang; David S. Sholl; Jefferson Z. Liu; Paul A. Webley; Eric F. May

doi:10.1038/ncomms15777

Temperature-regulated guest admission and release in microporous materials

Gang (Kevin) Li, Jin Shang, Qinfen Gu, Rohan V. Awati, Nathan Jensen, Andrew Grant, Xueying Zhang, David S. Sholl, Jefferson Z. Liu, Paul A. Webley, Eric F. May^*

^*Corresponding author for this work

School of Energy and Environment

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

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Abstract

While it has long been known that some highly adsorbing microporous materials suddenly become inaccessible to guest molecules below certain temperatures, previous attempts to explain this phenomenon have failed. Here we show that this anomalous sorption behaviour is a temperature-regulated guest admission process, where the pore-keeping group's thermal fluctuations are influenced by interactions with guest molecules. A physical model is presented to explain the atomic-level chemistry and structure of these thermally regulated micropores, which is crucial to systematic engineering of new functional materials such as tunable molecular sieves, gated membranes and controlled-release nanocontainers. The model was validated experimentally with H₂, N₂, Ar and CH₄ on three classes of microporous materials: trapdoor zeolites, supramolecular host calixarenes and metal-organic frameworks. We demonstrate how temperature can be exploited to achieve appreciable hydrogen and methane storage in such materials without sustained pressure. These findings also open new avenues for gas sensing and isotope separation.

Original language	English
Article number	15777
Journal	Nature Communications
Volume	8
Online published	9 Jun 2017
DOIs	https://doi.org/10.1038/ncomms15777
Publication status	Published - 2017

Funding

G.L. is the recipient of an Australian Research Council Discovery Early Career Researcher Award (DE140101824). This research was undertaken on the powder X-ray diffraction beamline at the Australian Synchrotron, Victoria, Australia. J.S., P.A.W. and J.Z.L. acknowledge the Australian Research Council for providing the funding (DP130103708) and acknowledge National Computational Infrastructure at Australian National University for providing the computational resource. D.S.S. was supported as part of the Center for Understanding and Control of Acid Gas-Induced Evolution of Materials for Energy (UNCAGE-ME), an Energy Frontier Research Center funded by U.S. Department of Energy, Office of Science, Basic Energy Sciences under Award #DE-SC0012577. E.F.M. and G.L. acknowledge support from the Australian Research Council through IC150100019. G.L., J.S. and E.F.M. thank Professors Yinong Liu and Michael Johns, Drs Michael Moldover and Hanjun Fang for helpful discussions.

Research Keywords

METAL-ORGANIC FRAMEWORK
UNIVALENT CATION FORMS
CARBON-DIOXIDE
CO2 ADSORPTION
MOLECULAR-SIEVE
ZEOLITE RHO
SEPARATION
ENERGY
EQUILIBRIUM
CAPTURE

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This full text is made available under CC-BY 4.0. https://creativecommons.org/licenses/by/4.0/

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title = "Temperature-regulated guest admission and release in microporous materials",

abstract = "While it has long been known that some highly adsorbing microporous materials suddenly become inaccessible to guest molecules below certain temperatures, previous attempts to explain this phenomenon have failed. Here we show that this anomalous sorption behaviour is a temperature-regulated guest admission process, where the pore-keeping group's thermal fluctuations are influenced by interactions with guest molecules. A physical model is presented to explain the atomic-level chemistry and structure of these thermally regulated micropores, which is crucial to systematic engineering of new functional materials such as tunable molecular sieves, gated membranes and controlled-release nanocontainers. The model was validated experimentally with H2, N2, Ar and CH4 on three classes of microporous materials: trapdoor zeolites, supramolecular host calixarenes and metal-organic frameworks. We demonstrate how temperature can be exploited to achieve appreciable hydrogen and methane storage in such materials without sustained pressure. These findings also open new avenues for gas sensing and isotope separation.",

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author = "Li, {Gang (Kevin)} and Jin Shang and Qinfen Gu and Awati, {Rohan V.} and Nathan Jensen and Andrew Grant and Xueying Zhang and Sholl, {David S.} and Liu, {Jefferson Z.} and Webley, {Paul A.} and May, {Eric F.}",

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AU - Shang, Jin

AU - Gu, Qinfen

AU - Awati, Rohan V.

AU - Jensen, Nathan

AU - Grant, Andrew

AU - Zhang, Xueying

AU - Sholl, David S.

AU - Liu, Jefferson Z.

AU - Webley, Paul A.

AU - May, Eric F.

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N2 - While it has long been known that some highly adsorbing microporous materials suddenly become inaccessible to guest molecules below certain temperatures, previous attempts to explain this phenomenon have failed. Here we show that this anomalous sorption behaviour is a temperature-regulated guest admission process, where the pore-keeping group's thermal fluctuations are influenced by interactions with guest molecules. A physical model is presented to explain the atomic-level chemistry and structure of these thermally regulated micropores, which is crucial to systematic engineering of new functional materials such as tunable molecular sieves, gated membranes and controlled-release nanocontainers. The model was validated experimentally with H2, N2, Ar and CH4 on three classes of microporous materials: trapdoor zeolites, supramolecular host calixarenes and metal-organic frameworks. We demonstrate how temperature can be exploited to achieve appreciable hydrogen and methane storage in such materials without sustained pressure. These findings also open new avenues for gas sensing and isotope separation.

AB - While it has long been known that some highly adsorbing microporous materials suddenly become inaccessible to guest molecules below certain temperatures, previous attempts to explain this phenomenon have failed. Here we show that this anomalous sorption behaviour is a temperature-regulated guest admission process, where the pore-keeping group's thermal fluctuations are influenced by interactions with guest molecules. A physical model is presented to explain the atomic-level chemistry and structure of these thermally regulated micropores, which is crucial to systematic engineering of new functional materials such as tunable molecular sieves, gated membranes and controlled-release nanocontainers. The model was validated experimentally with H2, N2, Ar and CH4 on three classes of microporous materials: trapdoor zeolites, supramolecular host calixarenes and metal-organic frameworks. We demonstrate how temperature can be exploited to achieve appreciable hydrogen and methane storage in such materials without sustained pressure. These findings also open new avenues for gas sensing and isotope separation.

KW - METAL-ORGANIC FRAMEWORK

KW - UNIVALENT CATION FORMS

KW - CARBON-DIOXIDE

KW - CO2 ADSORPTION

KW - MOLECULAR-SIEVE

KW - ZEOLITE RHO

KW - SEPARATION

KW - ENERGY

KW - EQUILIBRIUM

KW - CAPTURE

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M3 - RGC 21 - Publication in refereed journal

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SN - 2041-1723

VL - 8

JO - Nature Communications

JF - Nature Communications

M1 - 15777

ER -

Temperature-regulated guest admission and release in microporous materials

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Research Keywords

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