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Main Authors: Strasser, Nina, Schrode, Benedikt, Torvisco, Ana, John, Sanjay, Kunert, Birgit, Bitschnau, Brigitte, Lindner, Florian Patrick, Slugovc, Christian, Zojer, Egbert, Resel, Roland
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2504.05189
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author Strasser, Nina
Schrode, Benedikt
Torvisco, Ana
John, Sanjay
Kunert, Birgit
Bitschnau, Brigitte
Lindner, Florian Patrick
Slugovc, Christian
Zojer, Egbert
Resel, Roland
author_facet Strasser, Nina
Schrode, Benedikt
Torvisco, Ana
John, Sanjay
Kunert, Birgit
Bitschnau, Brigitte
Lindner, Florian Patrick
Slugovc, Christian
Zojer, Egbert
Resel, Roland
contents Understanding the reversible intercalation of guest molecules into metal-organic frameworks is crucial for advancing their design for practical applications. In this work, we explore the impact of H$_{\mathrm{2}}\!$O as a guest molecule on the thermal expansion of the zinc-based metal-organic framework GUT-2. Dehydration is achieved by thermal treatment of hydrated GUT-2. Rietveld refinement performed on temperature-dependent X-ray powder diffraction data confirms the reversible structural transformation. Additionally, it allows the determination of anisotropic thermal expansion coefficients for both phases. The hydrated form exhibits near-zero thermal expansion along the polymer chain direction, moderate expansion In the direction of predominantly hydrogen bonds, and the highest expansion in the direction with only Van der Waals bonding. Upon activation, the removal of H$_{\mathrm{2}}\!$O molecules triggers a doubling of the thermal expansion coefficient in the direction, where the hydrogen bonds have been removed. Regarding the dynamics of the process, thermal activation in air occurs within 6 hours at a temperature of 50°C and takes only 30 minutes when heating to 90°C. In contrast, full rehydration under standard lab conditions (30 % relative humidity) requires two days. During the activation/dehydration processes no change of the widths of the X-ray diffraction peaks is observed, which shows that the underlying crystal structures remains fully intact during the transition processes. Fitting the transformations by the Avrami equation reveals a quasi one-dimensional evolution of the dehydrated areas for the activation process and a more intricate, predominantly two-dimensional mechanism for the rehydration.
format Preprint
id arxiv_https___arxiv_org_abs_2504_05189
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Influence of pore-confined water on the thermal expansion of a zinc-based metal-organic framework
Strasser, Nina
Schrode, Benedikt
Torvisco, Ana
John, Sanjay
Kunert, Birgit
Bitschnau, Brigitte
Lindner, Florian Patrick
Slugovc, Christian
Zojer, Egbert
Resel, Roland
Materials Science
Understanding the reversible intercalation of guest molecules into metal-organic frameworks is crucial for advancing their design for practical applications. In this work, we explore the impact of H$_{\mathrm{2}}\!$O as a guest molecule on the thermal expansion of the zinc-based metal-organic framework GUT-2. Dehydration is achieved by thermal treatment of hydrated GUT-2. Rietveld refinement performed on temperature-dependent X-ray powder diffraction data confirms the reversible structural transformation. Additionally, it allows the determination of anisotropic thermal expansion coefficients for both phases. The hydrated form exhibits near-zero thermal expansion along the polymer chain direction, moderate expansion In the direction of predominantly hydrogen bonds, and the highest expansion in the direction with only Van der Waals bonding. Upon activation, the removal of H$_{\mathrm{2}}\!$O molecules triggers a doubling of the thermal expansion coefficient in the direction, where the hydrogen bonds have been removed. Regarding the dynamics of the process, thermal activation in air occurs within 6 hours at a temperature of 50°C and takes only 30 minutes when heating to 90°C. In contrast, full rehydration under standard lab conditions (30 % relative humidity) requires two days. During the activation/dehydration processes no change of the widths of the X-ray diffraction peaks is observed, which shows that the underlying crystal structures remains fully intact during the transition processes. Fitting the transformations by the Avrami equation reveals a quasi one-dimensional evolution of the dehydrated areas for the activation process and a more intricate, predominantly two-dimensional mechanism for the rehydration.
title Influence of pore-confined water on the thermal expansion of a zinc-based metal-organic framework
topic Materials Science
url https://arxiv.org/abs/2504.05189