计算机科学
人工神经网络
吉布斯自由能
嵌入
热力学过程
统计物理学
图形
焓
生物系统
分子图
人工智能
材料性能
热力学系统
热力学状态
功能(生物学)
热力学平衡
财产(哲学)
可预测性
相(物质)
算法
相变
自编码
理论计算机科学
相图
分子动力学
机器学习
物理系统
图论
热力学
基本热力学关系
能量(信号处理)
集合预报
熵(时间箭头)
拓扑(电路)
数据挖掘
热力学积分
作者
Jinyoung Park,Ruth M. Muthoka,Sunghyun Jang,Yongjin Lee
标识
DOI:10.1021/acs.iecr.5c02302
摘要
Accurately predicting thermodynamic properties across various conditions remains a critical challenge, particularly in scenarios involving sparse data or complex molecular interactions. This study proposes a multistage hybrid modeling framework that integrates Graph Neural Networks (GNN) and Physics-Informed Neural Networks (PINN) to predict essential thermodynamic properties, including enthalpy and entropy, for pure substances under various conditions. The model is developed in three distinct stages. First, a GNN encoder captures atomic-level interactions (both bonded and nonbonded) from molecular structures, generating structurally enriched molecular embeddings while leveraging critical constants and reduced state variables through a masking strategy that enables learning from single-phase data sets. Second, a regression submodel utilizes these embeddings to accurately predict saturation pressure (Psat) from molecular structure and temperature, modeling phase equilibrium behavior. Finally, the third stage employs PINN-based fine-tuning, embedding thermodynamic constraints─such as Gibbs free energy equality at phase equilibrium and enthalpy–entropy coupling─as penalties in the loss function to enforce thermodynamic consistency. This integrated GNN–PINN approach accurately predicts vapor- and liquid-phase enthalpies, entropies, and saturation pressures, maintaining robust performance even at equilibrium conditions. The model offers a physically consistent and reliable method for predicting thermodynamic properties, effectively capturing complex molecular interactions while adhering to fundamental physical laws.
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