Physics-informed graph neural networks for predicting cetane number with systematic data quality analysis

Kim, Yeonjoon; Cho, Jaeyoung; Naser, Nimal; Kumar, Sabari; Jeong, Keunhong; McCormick, Robert L.; St. John, Peter C.; Kim, Seonah

doi:10.1016/j.proci.2022.09.059

Title: Physics-informed graph neural networks for predicting cetane number with systematic data quality analysis

Journal Article · Sat Nov 19 00:00:00 EST 2022 · Proceedings of the Combustion Institute

DOI:https://doi.org/10.1016/j.proci.2022.09.059· OSTI ID:1905807

Kim, Yeonjoon ^[1];

^[2];

^[1]; Jeong, Keunhong ^[1];

^[2];

^[3]

Colorado State Univ., Fort Collins, CO (United States)
National Renewable Energy Lab. (NREL), Golden, CO (United States)
Colorado State Univ., Fort Collins, CO (United States); National Renewable Energy Lab. (NREL), Golden, CO (United States)

Designing alternative fuels for advanced compression ignition engines necessitates a predictive model for cetane number (CN). In this study, the physics-informed graph neural networks are introduced for a reliable CN prediction by considering molecular features pertinent to the physical properties of molecules that affect CN. The reliability of measured data is another key factor to consider for improving the predictive model. Various experimental instruments for measuring CN exist, including standard and non-standard methods. In this regard, a systematic data quality analysis was carried out for the total 630 CNs collected from literature and new measurements in this study using Advanced Fuel Ignition Delay Analyzer (AFIDA). The results from this data curation process were reflected in the model by imposing lower sample weights on the data coming from less reliable measurement techniques. This approach effectively maximized the prediction accuracy while incorporating data from all available sources. Using the sample weights decreased the mean absolute error (MAE) up to 0.8 CN units. The accuracy was also improved by introducing the CN-related physical properties (the number of hydrogen bond donors and acceptors); the test set MAE is 5.74 and 7.01 for the model with and without such properties, respectively. Investigating molecular structural effects on CN was also carried out to gain chemical insights into factors used to design new fuel candidates. The dimensionality reduction analysis of feature vectors showed a clear clustering in terms of functional groups and CN and the structural effect derived from the model was consistent with the physicochemical insights. Finally, this physics-informed model and data curation would be helpful for accurate CN prediction and inform rational fuel design.

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Research Organization:: National Renewable Energy Laboratory (NREL), Golden, CO (United States)

Sponsoring Organization:: USDOE; ExxonMobil; National Science Foundation (NSF)

Grant/Contract Number:: AC36-08GO28308; TG-CHE210034

OSTI ID:: 1905807

Report Number(s):: NREL/JA-2700-81974; MainId:82747; UUID:a832aa97-a492-457d-90db-0a02862ece39; MainAdminID:68284

Journal Information:: Proceedings of the Combustion Institute, Vol. 39, Issue 4; ISSN 1540-7489

Publisher:: ElsevierCopyright Statement

Country of Publication:: United States

Language:: English

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