A theoretical model for mass transition rate at liquid-vapor sharp interface
Phase change phenomena like evaporation and boiling have traditionally relied on accommodation coefficients, determined experimentally over centuries. This paper presents a new formula for the mass transition rate at a sharp interface, derived from the diffuse interface model in a two-phase system....
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sg-ntu-dr.10356-1823312025-01-22T02:18:34Z A theoretical model for mass transition rate at liquid-vapor sharp interface Pan, Lun Sheng Klaseboer, Evert Lou, Jing Kang, Chang-Wei Li, Jun Zhang, Xiaowu Feng, Huicheng Li, Hongying School of Mechanical and Aerospace Engineering Engineering Phase change Mass transition Phase change phenomena like evaporation and boiling have traditionally relied on accommodation coefficients, determined experimentally over centuries. This paper presents a new formula for the mass transition rate at a sharp interface, derived from the diffuse interface model in a two-phase system. The mass transition rate is proportional to the difference in chemical potentials between liquid and vapor which is consistent with the classical thermodynamic phase transition criteria. By using the saturation state at the interfacial temperature as a reference, unmeasurable parts of the chemical potentials are eliminated. The proposed model consists of two terms: the first accounts for the relative pressure between the liquid's vapor pressure and the vapor pressure at the interface, while the second reflects the contributions of surface tension and curvature. An alternative formulation expresses relative pressure as the temperature difference between the interfacial temperature and the saturation temperature corresponding to the vapor's interfacial pressure. Unlike traditional models, the proposed formula does not require accommodation coefficients, which typically vary by case. Validation against literature data for both flat and curved surfaces as well as micro-scale test setup shows reasonable agreement, demonstrating the model's effectiveness. Agency for Science, Technology and Research (A*STAR) This work is supported by Agency for Science, Technology and Research (A*STAR), Singapore under the grant #C210415009. 2025-01-22T02:18:34Z 2025-01-22T02:18:34Z 2025 Journal Article Pan, L. S., Klaseboer, E., Lou, J., Kang, C., Li, J., Zhang, X., Feng, H. & Li, H. (2025). A theoretical model for mass transition rate at liquid-vapor sharp interface. International Communications in Heat and Mass Transfer, 161, 108480-. https://dx.doi.org/10.1016/j.icheatmasstransfer.2024.108480 0735-1933 https://hdl.handle.net/10356/182331 10.1016/j.icheatmasstransfer.2024.108480 2-s2.0-85211096316 161 108480 en C210415009 International Communications in Heat and Mass Transfer © 2024 Elsevier Ltd. All rights are reserved, including those for text and data mining, AI training, and similar technologies. |
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Engineering Phase change Mass transition |
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Engineering Phase change Mass transition Pan, Lun Sheng Klaseboer, Evert Lou, Jing Kang, Chang-Wei Li, Jun Zhang, Xiaowu Feng, Huicheng Li, Hongying A theoretical model for mass transition rate at liquid-vapor sharp interface |
| description |
Phase change phenomena like evaporation and boiling have traditionally relied on accommodation coefficients, determined experimentally over centuries. This paper presents a new formula for the mass transition rate at a sharp interface, derived from the diffuse interface model in a two-phase system. The mass transition rate is proportional to the difference in chemical potentials between liquid and vapor which is consistent with the classical thermodynamic phase transition criteria. By using the saturation state at the interfacial temperature as a reference, unmeasurable parts of the chemical potentials are eliminated. The proposed model consists of two terms: the first accounts for the relative pressure between the liquid's vapor pressure and the vapor pressure at the interface, while the second reflects the contributions of surface tension and curvature. An alternative formulation expresses relative pressure as the temperature difference between the interfacial temperature and the saturation temperature corresponding to the vapor's interfacial pressure. Unlike traditional models, the proposed formula does not require accommodation coefficients, which typically vary by case. Validation against literature data for both flat and curved surfaces as well as micro-scale test setup shows reasonable agreement, demonstrating the model's effectiveness. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Pan, Lun Sheng Klaseboer, Evert Lou, Jing Kang, Chang-Wei Li, Jun Zhang, Xiaowu Feng, Huicheng Li, Hongying |
| format |
Article |
| author |
Pan, Lun Sheng Klaseboer, Evert Lou, Jing Kang, Chang-Wei Li, Jun Zhang, Xiaowu Feng, Huicheng Li, Hongying |
| author_sort |
Pan, Lun Sheng |
| title |
A theoretical model for mass transition rate at liquid-vapor sharp interface |
| title_short |
A theoretical model for mass transition rate at liquid-vapor sharp interface |
| title_full |
A theoretical model for mass transition rate at liquid-vapor sharp interface |
| title_fullStr |
A theoretical model for mass transition rate at liquid-vapor sharp interface |
| title_full_unstemmed |
A theoretical model for mass transition rate at liquid-vapor sharp interface |
| title_sort |
theoretical model for mass transition rate at liquid-vapor sharp interface |
| publishDate |
2025 |
| url |
https://hdl.handle.net/10356/182331 |
| _version_ |
1823108699854471168 |