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Main Authors: Cao, Peilin, Geng, Ying, Feng, Nan, Zhang, Xiang, Qi, Zhiwen, Song, Zhen, Gani, Rafiqul
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2503.17919
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author Cao, Peilin
Geng, Ying
Feng, Nan
Zhang, Xiang
Qi, Zhiwen
Song, Zhen
Gani, Rafiqul
author_facet Cao, Peilin
Geng, Ying
Feng, Nan
Zhang, Xiang
Qi, Zhiwen
Song, Zhen
Gani, Rafiqul
contents As current group contribution (GC) methods are mostly proposed for a wide size-range of molecules, applying them to property prediction of small refrigerant molecules could lead to unacceptable errors. In this sense, for the design of novel refrigerants and refrigeration systems, tailoring GC-based models specifically fitted to refrigerant molecules is of great interest. In this work, databases of potential refrigerant molecules are first collected, focusing on five key properties related to the operational efficiency of refrigeration systems, namely normal boiling point, critical temperature, critical pressure, enthalpy of vaporization, and acentric factor. Based on tailored small-molecule groups, the GC method is combined with machine learning (ML) to model these performance-related properties. Following the development of GC-ML models, their performance is analyzed to highlight the potential group-to-property contributions. Additionally, the refrigerant property databases are extended internally and externally, based on which examples are presented to highlight the significance of the developed models.
format Preprint
id arxiv_https___arxiv_org_abs_2503_17919
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Predicting performance-related properties of refrigerant based on tailored small-molecule functional group contribution
Cao, Peilin
Geng, Ying
Feng, Nan
Zhang, Xiang
Qi, Zhiwen
Song, Zhen
Gani, Rafiqul
Chemical Physics
Machine Learning
As current group contribution (GC) methods are mostly proposed for a wide size-range of molecules, applying them to property prediction of small refrigerant molecules could lead to unacceptable errors. In this sense, for the design of novel refrigerants and refrigeration systems, tailoring GC-based models specifically fitted to refrigerant molecules is of great interest. In this work, databases of potential refrigerant molecules are first collected, focusing on five key properties related to the operational efficiency of refrigeration systems, namely normal boiling point, critical temperature, critical pressure, enthalpy of vaporization, and acentric factor. Based on tailored small-molecule groups, the GC method is combined with machine learning (ML) to model these performance-related properties. Following the development of GC-ML models, their performance is analyzed to highlight the potential group-to-property contributions. Additionally, the refrigerant property databases are extended internally and externally, based on which examples are presented to highlight the significance of the developed models.
title Predicting performance-related properties of refrigerant based on tailored small-molecule functional group contribution
topic Chemical Physics
Machine Learning
url https://arxiv.org/abs/2503.17919