Pancake bouncing of impacting nanodroplets on smooth and nanopillared surfaces
Reducing the contact time of impacting droplets on solid surfaces has become a research focus due to its promising application prospects in self-cleaning, anti-erosion, and anti-icing. In this study, the pancake bouncing of nanodroplets is investigated through molecular dynamics simulations, achievi...
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sg-ntu-dr.10356-1806452024-10-16T01:25:19Z Pancake bouncing of impacting nanodroplets on smooth and nanopillared surfaces Ma, Qiang Wang, Yi-Feng Wu, Chuan-Wei Yang, Yan-Ru Zheng, Shao-Fei Tran, Tuan Wang, Xiao-Dong School of Mechanical and Aerospace Engineering Engineering Pancake bouncing Nanodroplet Reducing the contact time of impacting droplets on solid surfaces has become a research focus due to its promising application prospects in self-cleaning, anti-erosion, and anti-icing. In this study, the pancake bouncing of nanodroplets is investigated through molecular dynamics simulations, achieving a remarkable reduction in contact time. Two distinct patterns of pancake bouncing are identified when nanodroplets impact smooth and nanopillared surfaces with different bouncing mechanisms. The first pancake bouncing pattern with holes on smooth surfaces is attributed to internal-flow collision induced by multiple retraction centers. The second pancake bouncing pattern on nanopillared surfaces results from the storage and release of sufficient surface energy due to liquid penetration and requires satisfying both the timescale and energy criterion. Subsequently, theoretical models for two criteria are developed, which promote two parameter groups (−(s2 + 2ws)h(wcosθ0)−1 and We–1/3Re–1/3R02) corresponding to the surface and droplet. Based on these two parameter groups, a phase diagram is established and indicates the triggering conditions for the second pancake bouncing patterns. Finally, it is further revealed that by increasing the pillar height from smooth to nanopillared surfaces, the bouncing regime is transformed from the first pancake bouncing pattern, regular bouncing, to the second pancake bouncing pattern. This study was partially supported by the National Natural Science Foundation of China (No. 51936004), the Science Fund for Creative Research Groups of the National Natural Science Foundation of China (No. 51821004), the Science and Technology Planning Project of Ordos (No. 2022YY020), and China Scholarship Council (No. 202306730050). 2024-10-16T01:25:19Z 2024-10-16T01:25:19Z 2024 Journal Article Ma, Q., Wang, Y., Wu, C., Yang, Y., Zheng, S., Tran, T. & Wang, X. (2024). Pancake bouncing of impacting nanodroplets on smooth and nanopillared surfaces. International Communications in Heat and Mass Transfer, 159, 108108-. https://dx.doi.org/10.1016/j.icheatmasstransfer.2024.108108 0735-1933 https://hdl.handle.net/10356/180645 10.1016/j.icheatmasstransfer.2024.108108 2-s2.0-85204563326 159 108108 en 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 Pancake bouncing Nanodroplet |
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Engineering Pancake bouncing Nanodroplet Ma, Qiang Wang, Yi-Feng Wu, Chuan-Wei Yang, Yan-Ru Zheng, Shao-Fei Tran, Tuan Wang, Xiao-Dong Pancake bouncing of impacting nanodroplets on smooth and nanopillared surfaces |
| description |
Reducing the contact time of impacting droplets on solid surfaces has become a research focus due to its promising application prospects in self-cleaning, anti-erosion, and anti-icing. In this study, the pancake bouncing of nanodroplets is investigated through molecular dynamics simulations, achieving a remarkable reduction in contact time. Two distinct patterns of pancake bouncing are identified when nanodroplets impact smooth and nanopillared surfaces with different bouncing mechanisms. The first pancake bouncing pattern with holes on smooth surfaces is attributed to internal-flow collision induced by multiple retraction centers. The second pancake bouncing pattern on nanopillared surfaces results from the storage and release of sufficient surface energy due to liquid penetration and requires satisfying both the timescale and energy criterion. Subsequently, theoretical models for two criteria are developed, which promote two parameter groups (−(s2 + 2ws)h(wcosθ0)−1 and We–1/3Re–1/3R02) corresponding to the surface and droplet. Based on these two parameter groups, a phase diagram is established and indicates the triggering conditions for the second pancake bouncing patterns. Finally, it is further revealed that by increasing the pillar height from smooth to nanopillared surfaces, the bouncing regime is transformed from the first pancake bouncing pattern, regular bouncing, to the second pancake bouncing pattern. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Ma, Qiang Wang, Yi-Feng Wu, Chuan-Wei Yang, Yan-Ru Zheng, Shao-Fei Tran, Tuan Wang, Xiao-Dong |
| format |
Article |
| author |
Ma, Qiang Wang, Yi-Feng Wu, Chuan-Wei Yang, Yan-Ru Zheng, Shao-Fei Tran, Tuan Wang, Xiao-Dong |
| author_sort |
Ma, Qiang |
| title |
Pancake bouncing of impacting nanodroplets on smooth and nanopillared surfaces |
| title_short |
Pancake bouncing of impacting nanodroplets on smooth and nanopillared surfaces |
| title_full |
Pancake bouncing of impacting nanodroplets on smooth and nanopillared surfaces |
| title_fullStr |
Pancake bouncing of impacting nanodroplets on smooth and nanopillared surfaces |
| title_full_unstemmed |
Pancake bouncing of impacting nanodroplets on smooth and nanopillared surfaces |
| title_sort |
pancake bouncing of impacting nanodroplets on smooth and nanopillared surfaces |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/180645 |
| _version_ |
1814777809387651072 |