氢键在软纳滤孔聚合物吸附诱导溶胀滞后中的作用。

Role of hydrogen bonding in hysteresis observed in sorption-induced swelling of soft nanoporous polymers.

机构信息

Chair of Building Physics, Department of Mechanical and Process Engineering, ETH Zurich, 8093, Zurich, Switzerland.

Laboratory for Multiscale Studies in Building Physics, Swiss Federal Laboratories for Materials Science and Technology, Ueberlandstrasse 129, 8600, Duebendorf, Switzerland.

出版信息

Nat Commun. 2018 Aug 29;9(1):3507. doi: 10.1038/s41467-018-05897-9.

DOI:10.1038/s41467-018-05897-9

PMID:30158573

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6115358/

Abstract

Hysteresis is observed in sorption-induced swelling in various soft nanoporous polymers. The associated coupling mechanism responsible for the observed sorption-induced swelling and associated hysteresis needs to be unraveled. Here we report a microscopic scenario for the molecular mechanism responsible for hysteresis in sorption-induced swelling in natural polymers such as cellulose using atom-scale simulation; moisture content and swelling exhibit hysteresis upon ad- and desorption but not swelling versus moisture content. Different hydrogen bond networks are examined; cellulose swells to form water-cellulose bonds upon adsorption but these bonds do not break upon desorption at the same chemical potential. These findings, which are supported by mechanical testing and cellulose textural assessment upon sorption, shed light on experimental observations for wood and other related materials.

摘要

在各种软纳滤聚合物中，吸附诱导溶胀存在滞后现象。需要揭示导致观察到的吸附诱导溶胀和相关滞后的相关耦合机制。在这里，我们使用原子尺度模拟报告了一个关于天然聚合物（如纤维素）中吸附诱导溶胀滞后的分子机制的微观情景；在吸附和解吸过程中，水分含量和溶胀表现出滞后，但溶胀与水分含量无关。我们研究了不同的氢键网络；纤维素在吸附时膨胀形成水-纤维素键，但这些键在相同化学势下解吸时不会断裂。这些发现得到了吸附时机械测试和纤维素结构评估的支持，为木材和其他相关材料的实验观察提供了启示。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3f70/6115358/3d98a0f5e184/41467_2018_5897_Fig1_HTML.jpg

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氢键在软纳滤孔聚合物吸附诱导溶胀滞后中的作用。

Role of hydrogen bonding in hysteresis observed in sorption-induced swelling of soft nanoporous polymers.

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