How roughness and thermal properties of a solid substrate determine the Leidenfrost temperature: Experiments and a model

Wakata, Yuki; Zhu, Ning; Chen, Xiaoliang; Lyu, Sijia; Lohse, Detlef; Chao, Xing; Sun, Chao

doi:10.1103/physrevfluids.8.l061601

Phys. Rev. Fluids

2023

DOI: 10.1103/physrevfluids.8.l061601

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How roughness and thermal properties of a solid substrate determine the Leidenfrost temperature: Experiments and a model

Yuki Wakata

Ning Zhu

Xiaoliang Chen

et al.

Abstract: In this Letter, we systematically investigate the Leidenfrost temperature for hot solid substrates with various thermal diffusivities and surface roughnesses. Based on the experimental results, we build a phenomenological model that considers the thermal diffusivity of a solid substrate and derive a relationship between the surface roughness and the resulting vapor film thickness. The generality of this model is supported by experimental data for different liquids and solid substrates. Our model thus allows fo… Show more

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2024

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Cited by 3 publications

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Heat transport and flow structure in vertical convection over rough sidewalls

Meng,

Wu,

Chong

et al. 2024

Physics of Fluids

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We employ the direct numerical simulation to study the heat transfer behavior and flow structures in a vertical convection system with rough sidewalls. The parameters are chosen with Rayleigh number spanning the range of 1×108≤Ra≤3×1010 and Prandtl number fixed at 1.0. The results reveal that the impact of rough walls on the Nusselt number Nu and the Reynolds number Re is influenced by the height of the rough element h. When h is not sufficiently high, the roughness impedes the flows within the boundary layer and traps massive heat between rough elements, and both Nu and Re are lower than those in the smooth-wall case. However, the extent of the Nu and Re reduction regimes decreases as Ra increases. For sufficiently large Ra, the reduction regime for both Nu and Re may vanish, and roughness breaks up the limitation of the thermal boundary layer and facilitates the eruption of thermal plumes from roughness tips, resulting in the enhancement of both Nu and Re. Based on these results, the critical heights hc for Nu and hcr for Re are identified. Both exhibit similar scaling behavior with Ra, with hc consistently being larger than hcr for the same value of Ra.

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Heat transport and flow structure in vertical convection over rough sidewalls

Meng,

Wu,

Chong

et al. 2024

Physics of Fluids

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Thermal hysteresis in wettability and the Leidenfrost phenomenon

Kita,

Kida,

Ariyoshi

et al. 2024

Phys. Rev. Research

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The Leidenfrost temperature (TL), at which the liquid drop lifetime peaks on a superheated surface, is believed to be wettability dependent. Here, we show that the wettability effect on TL is subject to the history of the surface temperature. Observing a water drop evaporating on a polished stainless-steel surface heated from 100 to 400∘C in argon gas, we find TL≈265∘C. We then repeat the experiment along decreasing temperature and find a TL increase by 10 K, i.e., TL≈275∘C. This thermal hysteresis is due to a reduced contact angle during heating. Once hydrophilized, the hysteresis disappears until the contact angle recovers. Similar observations are made in the air where oxidation is possible. Published by the American Physical Society 2024

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Fluid Dynamics of Airtanker Firefighting

Legendre

2024

Annu. Rev. Fluid Mech.

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Airtanker firefighting is the most spectacular tool used to fight wildland fires. However, it employs a rudimentary large-scale spraying technology operating at a high speed and a long distance from the target. This review gives an overview of the fluid dynamics processes that govern this practice, which are characterized by rich and varied physical phenomena. The liquid column penetration in the air, its large-scale fragmentation, and an intense surface atomization give shape to the rainfall produced by the airtanker and the deposition of the final product on the ground. The cloud dynamics is controlled by droplet breakup, evaporation, and wind dispersion. The process of liquid deposition onto the forest canopy is full of open questions of great interest for rainfall retention in vegetation. Of major importance, but still requiring investigation, is the role of the complex non-Newtonian viscoelastic and shear-thinning behavior of the retardant dropped to stop the fire propagation. The review describes the need for future research devoted to the subject. Expected final online publication date for the Annual Review of Fluid Mechanics, Volume 56 is January 2024. Please see http://www.annualreviews.org/page/journal/pubdates for revised estimates.

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How roughness and thermal properties of a solid substrate determine the Leidenfrost temperature: Experiments and a model

Cited by 3 publications

References 36 publications

Heat transport and flow structure in vertical convection over rough sidewalls

Heat transport and flow structure in vertical convection over rough sidewalls

Thermal hysteresis in wettability and the Leidenfrost phenomenon

Fluid Dynamics of Airtanker Firefighting

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