Leidenfrost, J.G. & Acqua, D. Essay on some common properties (Obenius, 1756).
Dhillon, NS, Buongiorno, J. & Varanasi, KK Critical heat flux maximum during boiling crisis on textured surfaces. nut. General. 68247 (2015).
Tran, T., Staat, H.J., Prosperetti, A., Sun, C. & Lohse, D. Drop impact on superheated surfaces. Physics. Pastor Rhett. 108036101 (2012).
Kwon, H., Bird, JC, Varanasi, KK Enhancing Leidenfrost points using micro-nano hierarchical surface structures. applied physics. Let. 103201601 (2013).
Jiang, M. et al. It suppresses the Leidenfrost effect at temperatures above 1,000℃ and achieves sustained thermal cooling. nature 601568–572 (2022).
Farokhnia, N., Sajadi, SM, Irajizad, P. & Ghasemi, H. Separation of hierarchical structures to suppress the Leidenfrost phenomenon. langmuir 332541–2550 (2017).
Yuya Wakata et al. How the roughness and thermal properties of a solid substrate determine the Leidenfrost temperature: Experiments and models. Physics. Rev. Fluid 8L061601 (2023).
Vakarelski, IU, Patankar, NA, Marston, JO, Chan, DY & Thoroddsen, ST Stabilization of Leidenfrost vapor layers by textured superhydrophobic surfaces. nature 489274–277 (2012).
Vakarelski, IU, Marston, JO, Chan, DY & Thoroddsen, ST Reducing air resistance due to the Leidenfrost vapor layer. Physics. Pastor Rhett. 106214501 (2011).
Saranadi, D. et al. Sustained drag reduction in turbulent flow using low-temperature Leidenfrost surfaces. Science. advanced 2e1600686 (2016).
Linke, H. et al. Self-propelled Leidenfrost droplet. Physics. Pastor Rhett. 96154502 (2006).
Ragbo, G., Le Meller, M., Cranet, C., Kéret, D. Leidenfrost’s Ratchet. nut. Physics. 7395–398 (2011).
Lee, J. et al. Directional transport of hot Janus droplets through structural topography. nut. Physics. 12606–612 (2016).
Liu, M. et al. We suppress random droplet motion on hot surfaces by designing symmetry-breaking Janus mushroom structures. Advanced meter. 32e1907999 (2020).
Lee, A. et al. Adjust the vapor film under the drops of Leidenfrost. nut. General. 142646 (2023).
Bormashenko, E. Motion of a liquid on the surface of a Leidenfrost droplet and the Hairy-Ball theorem. surfing. Inov. 7101–103 (2019).
Chen, M., Jia, Z., Zhang, T. & Fei, Y. Self-propulsion of Leidenfrost droplets on micropillar-like hot surfaces via gradient wettability. Applied surfing. Science. 433336–340 (2018).
Bouillant, A., Lafoux, B., Clanet, C. & Quéré, D. Thermophilic Leidenfrost. soft matter 178805–8809 (2021).
Lin, Y., Wu, X., Hu, Z., Chu, F. Leidenfrost droplet jet engine with bubble ejection. J. Colloidal Interface Science. 650112–120 (2023).
Bouillant, A. et al. Leidenfrost’s Wheel. nut. Physics. 141188–1192 (2018).
Graeber, G. et al. Leidenfrost splash trampoline. nut. General. 121727 (2021).
Lyu, S. and others. The ultimate fate of the Leidenfrost droplets is to explode or take off. Science. advanced 5eaav8081 (2019).
Bouillant, A., Cohen, C., Clanet, C. & Quéré, D. Self-excitation of Leidenfrost drops and its influence on stability. National Academy of Procedures. Science. united states of america 118e2021691118 (2021).
Biens, Alabama, C. Clarnett, D. Kelle, Leidenfrost dropped. Physics. fluid 151632–1637 (2003).
Del Cerro, DA et al. Reduction of Leidenfrost points on micropatterned metal surfaces. langmuir 2815106–15110 (2012).
Harvey, D., Harper, JM & Burton, JC Minimum Leidenfrost temperature on smooth surfaces. Physics. Pastor Rhett. 127104501 (2021).
Huang, W. et al. Low-temperature Leidenfrost-like jumps of sessile droplets on microstructured surfaces. nut. Physics. 201274–1281 (2024).
Kelle, D. Mechanics of Leidenfrost. Anne. Rev. Fluid Mech. 45197–215 (2013).
Arpaci, VS & Larsen, PS convection heat transfer (Prentice Hall, 1984).
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