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A Data-Science Approach to Predict the Heat Capacity of Nanoporous Materials

descriptionPublicationkeyboard_double_arrow_right Article , Other literature type 19 Apr 2022 United Kingdom, United States, Switzerland Publisher:American Chemical Society (ACS)Journal:Nature Materials, volume 21, pages 1,419-1,425 (issn: 1476-1122, eissn: 1476-4660,

Copyright policy )Funded by:SNSF | Understanding Coupled Ion..., UKRI | Industrial Decarbonisatio..., SNSF | Shaping metal-organic fra... +1 projects

Authors: Moosavi, Seyed Mohamad; Novotny, Balázs Álmos; Ongari, Daniele; Moubarak, Elias; Asgari, Mehrdad; Kadioglu, Özge; Charalambous, Charithea; +6 Authors

doi: 10.26434/chemrxiv-2022-5xt71 , 10.1038/s41563-022-01374-3

pmid: 36229651

pmc: PMC7613869

A Data-Science Approach to Predict the Heat Capacity of Nanoporous Materials

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Abstract

The heat capacity of a material is a fundamental property that is of significant practical importance. For example, in a carbon capture process, the heat required to regenerate a solid sorbent is directly related to the heat capacity of the material. However, for most materials suitable for carbon capture applications the heat capacity is not known, and thus the standard procedure is to assume the same value for all materials. In this work, we developed a machine-learning approach to accurately predict the heat capacity of these materials, i.e., zeolites, metal-organic frameworks, and covalent-organic frameworks. The accuracy of our prediction is confirmed with novel experimental data. Finally, for a temperature swing adsorption process that captures carbon from the flue gas of a coal-fired power plant, we show that for some materials the heat requirement is reduced by as much as a factor of two using the correct heat capacity.

Countries

United Kingdom, United States, Switzerland

Related Organizations

University of Cambridge
United Kingdom
Microsoft (United Kingdom)
United Kingdom
Heriot-Watt University
United Kingdom
Heriot-Watt University
United Kingdom
École Polytechnique Fédérale de Lausanne EPFL
Switzerland

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Keywords

Hot Temperature, design, chemistry, Article, Carbon, 620, Climate Action, Nanopores, Coal, adsorption, Nanoscience & Nanotechnology, metal-organic frameworks, Metal-Organic Frameworks, Power Plants

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