AI Article Synopsis
- This paper investigates how bubbles form in water using molecular dynamics simulation, focusing on the role of hydrogen bonds and energy changes as the nucleation process occurs on a grooved surface.
- As water molecules heat up, their thermal motion increases, leading to the breaking of hydrogen bonds, which converts kinetic energy into intermolecular potential energy, primarily overcoming electrostatic forces.
- The study also finds that increasing pressure raises the energy barrier for nucleation, which can hinder the formation of vapor nuclei and negatively affect the boiling process.
Article Abstract
In this paper, the bubble nucleation process of water was studied by molecular dynamics (MD) simulation. The nucleation mechanism of water on a grooved substrate was revealed from the perspective of hydrogen bond and energy change, and the effect of system pressure on nucleation was studied. The results show that the process of bubble nucleation of water molecules is essentially a process in which the thermal motion of water molecules gradually intensifies and the hydrogen bond continues to break with the increase in kinetic energy. As the hydrogen bond breaks, the kinetic energy of the water molecules is continuously converted to intermolecular potential energy. By analyzing the composition of the hydrogen bond energy, it is found that the electrostatic energy is much greater than the van der Waals energy, so the water nucleation process mainly overcomes the electrostatic force between molecules. With the gradual increase of pressure, although the kinetic energy distribution of molecules does not change significantly, it will cause the potential energy of water molecules to decrease significantly and then lead to the increase of the energy barrier that needs to be crossed for nucleation. Meanwhile, the rise of the nucleation barrier may result in the absence of obvious initial vapor nuclei inside the liquid so that the number of hydrogen bonds cannot be rapidly reduced, which is not conducive to boiling nucleation. The results of this study provide important implications for further understanding of the nucleate boiling process of water.
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| http://dx.doi.org/10.1021/acs.langmuir.4c01854 | DOI Listing |
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