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During the Leidenfrost effect, a stable vapor film can separate a hot solid from an evaporating liquid. Eventually, after formation and upon cooling, the vapor layer cannot be sustained and undergoes a violent collapse evidenced by…

Fluid Dynamics · Physics 2023-01-26 Dana Harvey , Justin C. Burton

When a liquid droplet impacts a hot solid surface, enough vapor may be generated under it as to prevent its contact with the solid. The minimum solid temperature for this so-called Leidenfrost effect to occur is termed the Leidenfrost…

The Leidenfrost effect is a phenomenon in which a liquid, poured onto a surface significantly hotter than the liquid's boiling point, produces a layer of vapor that prevents the liquid from rapid evaporation. Rather than making physical…

Statistical Mechanics · Physics 2022-11-24 Sergey Gavrilyuk , Henri Gouin

Drops placed on a surface with a temperature above the Leidenfrost point float atop an evaporative vapor layer. In this fluid dynamics video, it is shown that for roughened surfaces the Leidenfrost point depends on the drop size, which runs…

Fluid Dynamics · Physics 2010-10-19 Jonathan B. Boreyko , Chuan-Hua Chen

Above a critical temperature known as the Leidenfrost point (LFP), a heated surface can suspend a liquid droplet above a film of its own vapor. The insulating vapor film can be highly detrimental in metallurgical quenching and thermal…

Fluid Dynamics · Physics 2021-02-16 Tom Y. Zhao , Neelesh A. Patankar

In this study the Leidenfrost temperature during spray cooling of very hot substrates is experimentally measured. The spray parameters, i.e. the drop diameters and velocities and the mass flux, are very accurately measured. Astonishingly,…

Fluid Dynamics · Physics 2020-01-16 Fabian M. Tenzer , Julian Hofmann , Ilia V. Roisman , Cameron Tropea

In the Leidenfrost effect, liquid drops deposited on a hot surface levitate on a thin vapor cushion fed by evaporation of the liquid. This vapor layer forms a concave depression in the drop interface. Using laser-light interference coupled…

Soft Condensed Matter · Physics 2018-02-21 J. C. Burton , A. L. Sharpe , R. C. A. van der Veen , A. Franco , S. R. Nagel

We show that a volatile liquid drop placed at the surface of a non-volatile liquid pool warmer than the boiling point of the drop can experience a Leidenfrost effect even for vanishingly small superheats. Such an observation points to the…

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…

Fluid Dynamics · Physics 2023-05-24 Yuki Wakata , Xiaoliang Chen , Ning Zhu , Sijia Lyu , Xing Chao , Chao Sun

In the Leidenfrost effect a small drop of fluid is levitated above a sufficiently hot surface, on a persistent vapor layer generated by evaporation from the drop. The vapor layer thermally insulates the drop from the surface leading to…

Fluid Dynamics · Physics 2014-07-30 Thomas A. Caswell

We experimentally investigate the Leidenfrost effect at pressures ranging from 1 to 0.05 atmospheric pressure. As a direct consequence of the Clausius-Clapeyron phase diagram of water, the droplet temperature can be at ambient temperature…

Soft Condensed Matter · Physics 2013-08-06 Franck Celestini , Thomas Frisch , Yves Pomeau

The Leidenfrost phenomenon entails the levitation of a liquid droplet over a superheated surface, cushioned by its vapor layer. For water, superhydrophobic surfaces are believed to suppress the Leidenfrost point ($\it{T}$$_{\rm L}$)-the…

Fluid Dynamics · Physics 2021-12-15 Meng Shi , Ratul Das , Sankara Arunachalam , Himanshu Mishra

The Leidenfrost effect-prolonged evaporation of droplets on a superheated surface-happens only when the surface temperature is above a certain transitional value. Here, we show that specially engineered droplets - liquid marbles - can…

Soft Condensed Matter · Physics 2012-07-05 Cedric Aberle , Mark Lewis , Gan Yu , Nan Lei , Jie Xu

Droplet impact on hot surfaces results in either droplet-surface contact or droplet-surface non-contact, i.e., the Leidenfrost state. The Leidenfrost droplet is levitated upon its vapor, deteriorating the heat transfer. The Leidenfrost…

Fluid Dynamics · Physics 2021-05-14 Omar Lamini , Rui Wu , C. Y. Zhao

The Leidenfrost effect, namely the levitation and hovering of liquid drops on hot solid surfaces, generally requires a sufficiently high substrate temperature to activate the intense liquid vaporization. Here we report the agile modulations…

At impact of a liquid droplet on a smooth surface heated above the liquid's boiling point, the droplet either immediately boils when it contacts the surfaces (``contact boiling''), or without any surface contact forms a Leidenfrost vapor…

Fluid Dynamics · Physics 2012-01-24 Tuan Tran , Hendrik J. J. Staat , Andrea Prosperetti , Chao Sun , Detlef Lohse

An isolated Leidenfrost droplet levitating over its own vapor above a superheated flat substrate is considered theoretically, the superheating for water being up to several hundred degrees above the boiling temperature. The focus is on the…

Fluid Dynamics · Physics 2025-05-14 Benjamin Sobac , Alexey Rednikov , Pierre Colinet

Large Leidenfrost drops exhibit erratic bubble bursts to release vapor accumulated beneath the liquid, becoming amorphous and unstable. Here we report an original and remarkably simple method to stabilize and design a Leidenfrost puddle.…

Fluid Dynamics · Physics 2024-03-11 F. Pacheco-Vázquez , M. Aguilar-González , L. Victoria-García

In real applications, drops always impact on solid walls with various inclinations. For the oblique impact of a Leidenfrost drop, which has a vapor layer under its bottom surface to prevent its direct contact with the superheated substrate,…

Fluid Dynamics · Physics 2021-01-19 Yujie Wang , Ayoub El Bouhali , Sijia Lyu , Lu Yu , Yue Hao , Zhigang Zuo , Shuhong Liu , Chao Sun

Volatile drops deposited on a hot solid can levitate on a cushion of their own vapor, without contacting the surface. We propose to understand the onset of this so-called Leidenfrost effect through an analogy to non-equilibrium systems…

Fluid Dynamics · Physics 2021-09-22 Pierre Chantelot , Detlef Lohse
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