In Situ Tracking of Wetting-Front Transient Heat Release on a Surface-Mounted Metal-Organic Framework

Overview

Journal Adv Mater

Date 2021 Feb 24

PMID 33624896

Citations 3

Authors

Weijin Li

Guang Yang

Alexandros Terzis

Soumya Mukherjee

Chao He

Xingtao An

Jingyi Wu

Bernhard Weigand

Roland A Fischer

Affiliations

Soon will be listed here.

Abstract

Transient heat generation during guest adsorption and host-guest interactions is a natural phenomenon in metal-organic framework (MOF) chemistry. However, in situ tracking of such MOF released heat is an insufficiently researched field due to the fast heat dissipation to the surroundings. Herein, a facile capillary-driven liquid-imbibition approach is developed for in situ tracking of transient heat release at the wetting front of surface-mounted MOFs (SURMOFs) on cellulosic fiber substrates. Spatiotemporal temperature distributions are obtained with infrared thermal imaging for a range of MOF-based substrates and imbibed liquids. Temperature rises at the wetting front of water and binary mixtures with organic solvents are found to be over 10 K with an ultrafast and distinguishable thermal signal response (<1 s) with a detectable concentration limit ≤1 wt%. As an advancement to the state-of-the-art in trace-solvent detection technologies, this study shows great prospects for the integration of SURMOFs in future sensor devices. Inspired by this prototypal study, SURMOF-based transient heat signal transduction is likely to be extended to an ever-expanding library of SURMOFs and other classes of surface-grafted porous materials, translating into a wide range of convenient, portable, and ubiquitous sensor devices.

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In Situ Tracking of Wetting-Front Transient Heat Release on a Surface-Mounted Metal-Organic Framework.

Li W, Yang G, Terzis A, Mukherjee S, He C, An X Adv Mater. 2021; 33(14):e2006980.

PMID: 33624896 PMC: 11468584. DOI: 10.1002/adma.202006980.

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