Universality of oscillating boiling in Leidenfrost transition

Khavari, Mohammad; Tran, Tuan

doi:10.1103/physreve.96.043102

Cited by 19 publications

(22 citation statements)

References 39 publications

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“…The existence of this threshold for floating is supported by the fact that, down the lowest velocities we can reliably probe (∼100 μm=s), we observe no floating for a plate temperature of 155°C. These data warrant comparison with the dynamic Leidenfrost transition observed for liquid droplets impacting a heated substrate, where a similar separation between contact and noncontact plays out as a function of impact speed and temperature [4,5,23]. Physically, one suspects that with the extremely low velocities we probe here, the mechanism is dependent upon whether or not sufficient viscous stress can build up in the vapor layer to prevent the sphere from touching-similar to what happens for liquids impacting at low velocities [23].…”

supporting

confidence: 65%

“…2(d)]. Interestingly, similar oscillations have been observed for liquids [5,23], but in those experiments no energy harvesting is observed and instead droplets are quickly destroyed by the vigorous contact boiling.…”

supporting

confidence: 64%

“…These data warrant comparison with the dynamic Leidenfrost transition observed for liquid droplets impacting a heated substrate, where a similar separation between contact and noncontact plays out as a function of impact speed and temperature [4,5,23]. Physically, one suspects that with the extremely low velocities we probe here, the mechanism is dependent upon whether or not sufficient viscous stress can build up in the vapor layer to prevent the sphere from touching-similar to what happens for liquids impacting at low velocities [23]. Important distinctions exist, however, that preclude exact comparison.…”

mentioning

confidence: 67%

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From Bouncing to Floating: The Leidenfrost Effect with Hydrogel Spheres

2018

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The Leidenfrost effect occurs when a liquid or stiff sublimable solid near a hot surface creates enough vapor beneath it to lift itself up and float. In contrast, vaporizable soft solids, e.g., hydrogels, have been shown to exhibit persistent bouncing-the elastic Leidenfrost effect. By carefully lowering hydrogel spheres towards a hot surface, we discover that they are also capable of floating. The bounce-to-float transition is controlled by the approach velocity and temperature, analogously to the "dynamic Leidenfrost effect." For the floating regime, we measure power-law scalings for the gap geometry, which we explain with a model that couples the vaporization rate to the spherical shape. Our results reveal that hydrogels are a promising pathway for controlling floating Leidenfrost objects through shape.

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supporting

confidence: 65%

supporting

confidence: 64%

mentioning

confidence: 67%

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From Bouncing to Floating: The Leidenfrost Effect with Hydrogel Spheres

2018

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“…In general, the larger the Weber number, the higher the wall-surface temperature required to initiate rebounding and consequently TL increases [62], [63]. It is of interest to note that similar behaviour has been observed in [64], although the impact velocity was employed in the phase diagram rather than Weber number. However according to [60], the Leidenfrost temperature shows a weak dependence on the Weber number, yet it can be approximated as a constant value of T*≈2.1 (TW≈165°C).…”

Section: Classification Of Post-impact Regimesmentioning

confidence: 67%

Experimental Study of Diesel-Fuel Droplet Impact on a Similarly Sized Polished Spherical Heated Solid Particle

et al. 2017

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The head-to-head impact of diesel-fuel droplets on a polished spherical brass target has been investigated experimentally. High-speed imaging was employed to visualize the impact process for wall surface temperatures and Weber and Reynolds numbers in the ranges of 140-340 °C, 30-850, and 210-1135, respectively. The thermohydrodynamic outcome regimes occurring for the aforementioned ranges of parameters were mapped on a We-T diagram. Seven clearly distinguishable postimpact outcome regimes were identified, which are conventionally called the coating, splash, rebound, breakup-rebound, splash-breakup-coating, breakup-coating, and splash-breakup-rebound regimes. In addition, the effects of the Weber number and surface temperature on the wettability dynamics were examined; the temporal variations of the dynamic contact angle, dimensionless spreading diameter, and liquid film thickness forming on the solid particle were measured and are reported.

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“…The prediction of the Leidenfrost temperature T L is however still an unsolved problem. It is known that T L depends on the type of liquid 21 as well as the roughness 22,23 and thermal conductivity 21,[24][25][26][27] of the plate. We also know that it increases with increasing impact velocity of the drop.…”

Section: Introductionmentioning

confidence: 99%