Fact-checked by Grok 2 weeks ago

Leidenfrost effect

The Leidenfrost effect is a thermophysical phenomenon in which a liquid droplet, upon contact with a solid surface heated substantially above the liquid's boiling point, undergoes rapid evaporation at its base, forming a self-sustaining vapor layer that levitates the droplet and prevents direct contact with the surface.^[1] This insulation dramatically reduces heat transfer, allowing the droplet to persist much longer than it would at lower temperatures, where it would rapidly boil away.^[2] First systematically described in 1756 by German physician and theologian Johann Gottlob Leidenfrost in his treatise De Aquae Communis Nonnullis Qualitatibus Tractatus (A Tract About Some Qualities of Common Water), the effect was observed through experiments with water droplets on hot metal plates, noting their unusual longevity and hovering behavior.^[3] The critical temperature threshold, known as the Leidenfrost point, marks the onset of this regime and varies with factors such as surface roughness, liquid properties, and pressure; for water on smooth metallic surfaces, it typically occurs around 200 °C, well above the boiling point of 100 °C at atmospheric pressure.^[4] Mechanistically, the effect arises during the film boiling stage of heat transfer, where the vapor cushion—generated by intense localized evaporation—acts as a thermal barrier, with the droplet's shape and motion influenced by buoyancy, gravity, and substrate geometry.^[5] The Leidenfrost effect holds significant implications in engineering and natural processes, often posing challenges in applications requiring efficient heat dissipation, such as metal quenching or nuclear reactor cooling, where the vapor layer hinders convective heat transfer and can lead to reduced cooling rates.^[6] Conversely, it enables unique behaviors like self-propelled droplet motion on ratcheted or oily surfaces, with potential uses in microfluidics, drag reduction for liquid transport, and even culinary techniques for handling hot pans.^[7] In nature, analogous phenomena occur during volcanic eruptions, where seawater interacting with magma forms insulating vapor layers.^[8] Recent research has focused on manipulating the effect through surface texturing to raise the Leidenfrost point, enhancing cooling efficiency in industrial settings.^[9]

Fundamentals

Definition and Basic Observation

The Leidenfrost effect is a phase-change phenomenon in which a liquid droplet, upon contact with a solid surface significantly hotter than the liquid's boiling point, rapidly vaporizes at the interface to form a thin, stable layer of vapor that suspends the droplet above the surface. This insulating vapor cushion prevents direct contact between the liquid and the hot solid, resulting in levitation of the droplet and a marked reduction in the evaporation rate compared to regimes where the liquid wets the surface.^[10] In everyday observations, the effect is evident when water droplets are splashed onto a sufficiently hot cooking pan, where they exhibit erratic skittering or dancing motion across the surface rather than spreading and evaporating quickly, often accompanied by a characteristic sizzling sound from intermittent vapor bursts. Similarly, in laboratory settings, the droplets appear to glide smoothly with minimal friction, highlighting the self-sustaining nature of the vapor layer.^[11]^[12] The key physical prerequisite for the Leidenfrost effect is the intense heat flux at the liquid-solid interface, which induces continuous evaporation and phase transition from liquid to vapor, establishing a regime known as film boiling. This occurs above the Leidenfrost point, the critical surface temperature threshold—typically around 170–200 °C for water on a clean metal surface—beyond which the vapor film becomes stable and persistent.^[10]^[5] Qualitatively, the Leidenfrost effect differs from nucleate boiling, where discrete bubbles nucleate, grow, and detach from the heated surface, promoting efficient heat transfer through vigorous liquid agitation. It also contrasts with transition boiling, an unstable intermediate regime characterized by partial vapor patches that cause fluctuating contact and lower heat transfer efficiency due to intermittent wetting and dry spots. In contrast, the Leidenfrost regime features a continuous, insulating vapor blanket that minimizes heat transfer and stabilizes the droplet's suspension.^[13]

Historical Background

The Leidenfrost effect was first systematically investigated and described by Johann Gottlob Leidenfrost, a German physician and scientist, in his 1756 treatise De Aquae Communis Nonnullis Qualitatibus Tractatus. In this Latin work published in Duisburg, Leidenfrost conducted experiments using a red-hot iron spoon to demonstrate how small water droplets, when placed on the intensely heated surface, would not immediately evaporate but instead form a cushion of vapor that suspended them above the metal, causing the drops to "dance" or move about erratically for extended periods—up to several minutes in some cases—compared to rapid boiling at lower temperatures.^[14] He attributed this to the insulating properties of the self-generated steam layer, providing one of the earliest scientific accounts of vapor-mediated levitation in liquids on hot solids.^[15] An earlier observation of a related phenomenon dates to 1732, when Dutch chemist and physician Hermann Boerhaave noted in his Elementa Chemiae that droplets of ethanol deposited on a superheated metal plate did not ignite immediately but instead glided across the surface due to a vapor film, surprising him as it delayed combustion.^[3] These 18th-century experiments, including Leidenfrost's more quantitative measurements of evaporation times and droplet behaviors, emphasized the role of vapor insulation in preventing direct liquid-solid contact during intense heating, laying groundwork for understanding boiling dynamics well before the development of formalized heat transfer theories.^[16] The effect received further attention in the 1930s as part of broader heat transfer research, particularly through Shiro Nukiyama's seminal 1934 experiments on pool boiling of water using a nichrome wire heater, where he constructed the first boiling curve plotting heat flux against surface temperature and identified a minimum heat flux region marking the transition to stable film boiling.^[17] This minimum point, now known as the Leidenfrost point, linked the isolated droplet observations of the 18th century to systematic boiling regimes, highlighting the phenomenon's implications for reduced heat transfer at high temperatures.^[18] Over time, the terminology shifted from the more general "film boiling," used in early 20th-century engineering contexts to describe the vapor-blanketed regime in bulk liquids, to the specific "Leidenfrost effect," which became prevalent in mid-20th-century literature to denote the levitation and prolonged lifetime of individual droplets on hot surfaces, honoring the original observer.^[19] This naming convention solidified in scientific publications by the 1940s and 1950s, distinguishing the droplet-specific manifestation from broader boiling classifications.^[20]

Physical Mechanisms

Vapor Cushion Formation

The vapor cushion in the Leidenfrost effect arises when a liquid droplet contacts a solid surface heated well above the liquid's boiling point, leading to instantaneous evaporation of the liquid at the interface and the formation of a continuous insulating vapor film that suspends the droplet, preventing direct liquid-solid contact. This rapid vapor generation occurs because the high surface temperature exceeds the Leidenfrost point, where the evaporation rate is sufficient to establish a stable layer without collapse. The sustainability of this vapor film relies on an energy balance at the liquid-vapor interface, where heat from the hot surface conducts through the thin vapor layer to provide the latent heat necessary for ongoing evaporation, while the generated vapor flows radially outward from beneath the droplet to maintain the cushion's integrity. This outward vapor flow is driven by the pressure gradient created by evaporation, ensuring hydrodynamic stability by counteracting gravitational forces on the droplet. The resulting equilibrium often produces a slightly flattened spherical shape for the levitated droplet, as the upward vapor pressure balances the droplet's weight against surface tension constraints.^[3] The thickness of the vapor cushion, typically on the order of tens to hundreds of micrometers, depends critically on the surface temperature, with higher temperatures enhancing evaporation and thus increasing layer thickness to better insulate the droplet. Liquid properties such as viscosity and density also play key roles, as higher viscosity impedes vapor outflow and promotes thicker films, while density differences between liquid and vapor influence the pressure support; ambient pressure further modulates thickness by affecting boiling dynamics and vapor escape. These factors collectively determine the cushion's robustness, with seminal studies emphasizing their role in the transition to stable levitation.^[21]^[22]

Leidenfrost Point and Critical Temperature

The Leidenfrost point refers to the minimum temperature of a solid surface required to sustain a stable vapor film beneath a liquid droplet, marking the onset of the Leidenfrost effect where the droplet levitates due to the insulating vapor layer. This critical threshold corresponds to the transition from the transition boiling regime, characterized by intermittent liquid-solid contact and high heat flux, to the film boiling regime, where the continuous vapor cushion drastically reduces heat transfer. For water droplets on smooth metallic surfaces, the Leidenfrost point typically occurs at a surface temperature of approximately 190–200°C, representing a superheat of about 90–100°C above the saturation temperature of 100°C at atmospheric pressure.^[23]^[2] The value of the Leidenfrost point is influenced by several key factors, including the properties of the liquid, the characteristics of the surface, and the geometric orientation of the system. Different liquids exhibit varying Leidenfrost temperatures primarily due to differences in surface tension, latent heat of vaporization, and density; for instance, alcohols like ethanol have a lower Leidenfrost point than water—often around 140–160°C total temperature—because their reduced surface tension facilitates the formation of the vapor layer at smaller superheats.^[24] Surface material and topography also play a crucial role, with increased roughness on hydrophilic surfaces elevating the Leidenfrost point by promoting more frequent liquid-solid contacts that destabilize the vapor film until higher temperatures are reached.^[25] Additionally, system orientation affects the point, as horizontal configurations generally yield lower Leidenfrost temperatures compared to vertical ones in scenarios like spray cooling, where gravity influences vapor escape and droplet spreading.^[26] Experimental determination of the Leidenfrost point commonly involves controlled heating of a plate or substrate to constant temperatures while observing droplet behavior. In the sessile droplet method, a fixed-volume droplet is placed on the hot surface, and its evaporation lifetime is measured; below the Leidenfrost point, rapid spreading and short lifetimes occur due to nucleate boiling, whereas above it, levitation leads to longer lifetimes and minimal contact.^[5] Wire immersion tests, used particularly for pool boiling contexts, involve quenching a heated wire in the liquid and monitoring the heat flux or visual stability to identify the transition to stable film boiling. These methods trace back to foundational boiling studies and allow precise mapping of the point across conditions.^[27] A basic estimation of the Leidenfrost temperature follows the form T_L = T_\text{sat} + \Delta T_c where T_\text{sat} is the liquid's saturation temperature and \Delta T_c is the empirical critical superheat at the Leidenfrost point, derived from boiling curves such as Nukiyama's classic diagram of heat flux versus wall superheat. In Nukiyama's framework, \Delta T_c corresponds to the superheat at the minimum heat flux in the transition boiling region, typically determined experimentally for specific systems rather than through a universal theoretical derivation, as it encapsulates complex interactions like vapor generation and instability.^[27]^[5]

Droplet Dynamics

Pressure Distribution in Leidenfrost Droplets

In Leidenfrost droplets, the pressure field exhibits distinct profiles both at the interface with the vapor cushion and within the liquid phase. At the droplet base, vapor generation from evaporation creates an elevated pressure that supports levitation, with the maximum occurring near the center and decreasing radially due to the outward radial flow of vapor driven by this gradient. This configuration ensures the droplet's weight is balanced by the integrated pressure over the contact area. Within the liquid interior, a hydrostatic pressure gradient prevails, linearly increasing from the droplet's apex to its base under the influence of gravity, typically on the order of ρgh where h is the droplet height and ρ is the liquid density.^[28]^[29] Numerical models provide detailed insights into these pressure contours by solving the Navier-Stokes equations for two-phase incompressible flow, incorporating phase change at the vapor-liquid interface through volume-of-fluid or level-set methods. These simulations account for the coupled dynamics of liquid and vapor phases, revealing how pressure varies across the thin vapor layer and into the droplet. A simplified form of the momentum equation used in such models is

\nabla P = -\rho \mathbf{g} + \mu \nabla^2 \mathbf{v},

where the pressure gradient balances gravitational and viscous forces, with emphasis on the interface where surface tension and evaporation influence the boundary conditions. Validation against experimental data shows these models accurately predict radial pressure decay and hydrostatic contributions, aiding in understanding stability.^[30]^[31] Pressure imbalances arising from these distributions significantly influence droplet morphology and dynamics. The elevated base pressure compresses the liquid-vapor interface, inducing dimpling or flattening at the droplet's underside, which alters the overall spherical shape into a more oblate form. Non-uniformities in the radial pressure profile, often due to asymmetric evaporation, cause fluctuations in levitation height, typically ranging from tens to hundreds of micrometers, promoting instability. These variations drive the skittering motion, where the droplet erratically translates across the surface as pressure gradients propel it laterally.^[32]^[29] Experimental validation of these pressure profiles relies on high-speed imaging techniques, such as schlieren or X-ray methods, which visualize density gradients and interface deformations correlating with inferred pressure fields. Direct measurements using microfabricated pressure sensors embedded in the hot surface have detected peaks in the vapor layer, often exceeding ambient pressure by 10-100 Pa, that scale with local evaporation rates. For instance, studies on water droplets at 300-400°C show pressure maxima aligning with regions of intense vapor production, confirming the radial decrease and its role in sustaining levitation. These observations, combined with particle image velocimetry for flow mapping, provide quantitative support for the modeled distributions without direct intrusion into the droplet.^[33]

Surface Tension and Temperature Interactions

The surface tension of liquids in the Leidenfrost regime exhibits a strong dependence on temperature, which profoundly influences droplet cohesion, shape, and dynamics. Surface tension \sigma typically decreases linearly with increasing temperature according to the relation

\sigma(T) \approx \sigma_0 \left(1 - \beta (T - T_0)\right),

where \sigma_0 is the surface tension at a reference temperature T_0 and \beta is the temperature coefficient (approximately $2 \times 10^{-3} K^{-1} for water near room temperature).^[34] This reduction in surface tension with rising liquid temperature diminishes droplet cohesion, thereby affecting its spreading extent and structural stability while levitating on the vapor cushion.^[24] At the liquid-vapor interface, surface tension interacts with the supporting vapor pressure to dictate the droplet's effective contact angle and levitation height. The vapor pressure lifts the droplet, counteracting gravity, while surface tension minimizes interfacial energy, promoting a near-spherical shape with an apparent contact angle of approximately 180°, indicative of complete non-wetting due to the insulating vapor layer.^[35] This balance ensures stable levitation, but variations in surface tension alter the interfacial stress distribution, influencing the minimal separation distance between the droplet and the hot surface. Experimental observations reveal that higher surface temperatures elevate the droplet's internal liquid temperature, lowering overall surface tension and accelerating evaporation through enhanced vapor generation, which in turn modifies droplet trajectories and promotes greater mobility.^[32] On hotter substrates, the reduced cohesion from diminished surface tension can lead to more dynamic spreading at the droplet's edges before stabilization, contrasting with more compact forms at lower superheats near the Leidenfrost point. Temperature-induced surface tension gradients within Leidenfrost droplets drive Marangoni flows, where the warmer bottom region exhibits lower surface tension compared to the cooler top, inducing thermocapillary convection from low- to high-tension areas along the interface.^[36] These flows enhance internal circulation, homogenizing temperature and solute distribution while contributing to instabilities such as azimuthal rotation or zigzag motion in small droplets.^[37] Seminal experimental studies from the early 21st century, including high-speed imaging of water droplets on heated plates, have quantified these gradients, showing Marangoni velocities scaling with the temperature difference across the droplet height and directly linking them to altered evaporation rates and self-propulsion behaviors.^[32]

Heat Transfer Aspects

Empirical Correlations for Heat Transfer

Empirical correlations for heat transfer in the Leidenfrost state draw from established film boiling models, providing quantitative estimates of the reduced heat flux due to the insulating vapor layer. These models treat the vapor cushion as a thin film through which heat is primarily conducted, with buoyancy-driven flow influencing the film thickness. Key assumptions include laminar flow in the vapor layer, neglect of inertia terms in the momentum equation, and steady-state conditions, valid when the surface temperature significantly exceeds the Leidenfrost point.^[38] A seminal correlation is Bromley's equation for film boiling heat transfer coefficient, originally derived for horizontal cylinders but adapted for Leidenfrost droplets by using the droplet diameter D as the characteristic length. The heat transfer coefficient h is expressed as

h = C \left[ \frac{k_v^3 \rho_v (\rho_l - \rho_v) g h_{fg}}{\mu_v D (T_w - T_{sat})} \right]^{1/4},

where C \approx 0.62 is an empirical constant, k_v, \rho_v, and \mu_v are the thermal conductivity, density, and viscosity of the vapor, \rho_l is the liquid density, g is gravity, h_{fg} is the latent heat of vaporization (often modified as h_{fg} + 0.4 c_{p,v} (T_w - T_{sat}) to account for sensible heating), and T_w - T_{sat} is the wall superheat. The heat flux is then q = h (T_w - T_{sat}). This form accounts for conduction across the vapor film balanced by buoyancy-induced vapor flow. The equation assumes saturated conditions and low vapor velocities, with radiation effects added separately as q_{rad} = \epsilon \sigma (T_w^4 - T_{sat}^4).^[38]^[28] For horizontal surfaces relevant to Leidenfrost observations, the Nusselt number adaptation provides a dimensionless form:

\text{Nu} = \frac{h D}{k_v} = 0.62 (\text{Gr} \text{Pr})^{1/4},

where h is the heat transfer coefficient, \text{Gr} = \frac{g (\rho_l - \rho_v) D^3}{\rho_v \nu_v^2} is the Grashof number based on buoyancy in the vapor (with kinematic viscosity \nu_v = \mu_v / \rho_v), and \text{Pr} = \frac{c_{p,v} \mu_v}{k_v} is the vapor Prandtl number. This correlation stems from boundary-layer analysis assuming a stable vapor film thickness determined by hydrodynamic stability. It simplifies for cases where the Jakob number \text{Ja} = \frac{c_{p,v} (T_w - T_{sat})}{h_{fg}} is small, indicating latent heat dominance.^[39] These correlations were originally developed for pool boiling scenarios, such as on horizontal cylinders or flat plates immersed in a large liquid pool, where the vapor film forms continuously. In droplet Leidenfrost scenarios, they apply reasonably when the droplet size exceeds the vapor film thickness (typically D > 1 mm for water), treating the droplet base as analogous to a heated surface; however, for very small droplets, surface tension effects and transient evaporation deviate from predictions, requiring refinements. Limitations arise at high pressures (e.g., >1 MPa), where increased vapor density reduces film thickness and enhances buoyancy less predictably, leading to underprediction of heat transfer by up to 50% without pressure-dependent adjustments to properties or constants.^[28]^[40] The foundations trace to 1950s analyses by Bromley for cylindrical geometries, emphasizing integral momentum and energy balances in the vapor film. Subsequent refinements by Berenson in 1961 incorporated Taylor-Helmholtz instability for horizontal plates, using the critical wavelength as the characteristic length to better capture bubble departure and film renewal. These have been iteratively adapted for Leidenfrost specifics, such as droplet-scale geometries, in aerospace and cryogenic applications.^[38]^[39]

Film Boiling Regime Characteristics

In the film boiling regime of the Leidenfrost effect, a stable vapor film forms between the hot surface and the liquid, acting as an insulator that drastically reduces heat transfer compared to nucleate boiling. This regime occurs at high surface superheats, typically above the Leidenfrost point, where the continuous vapor layer prevents direct liquid-surface contact, resulting in heat fluxes that are substantially lower—on the order of one-fiftieth to one-hundredth of those achieved during peak nucleate boiling, for water around 10-20 kW/m² at the Leidenfrost minimum compared to ~1 MW/m² at critical heat flux. The characteristic minimum in the boiling curve corresponds to this Leidenfrost point, marking the onset of stable film boiling and the lowest heat transfer rate before recovery at even higher temperatures.^[41]^[42] Hysteresis is a prominent feature of the film boiling regime, arising from the path-dependent nature of transitions between boiling modes during heating and cooling cycles. When heating a surface, the shift from transition to film boiling occurs at a higher superheat than the Leidenfrost point itself, due to the persistence of partial liquid contact. Conversely, during cooling from film boiling conditions, the stable vapor film maintains the regime down to lower superheats, delaying the return to transition boiling and creating a loop in the boiling curve. This hysteresis effect, first observed in experimental setups, underscores the stability of the vapor film once established and influences practical processes like quenching.^[43]^[42]^[18] The stability of the film boiling regime is governed by interfacial dynamics, particularly the interplay between Rayleigh-Taylor instabilities and vapor generation. The vapor-liquid interface is inherently prone to Rayleigh-Taylor instability, where denser liquid above lighter vapor can lead to fingering and film collapse under gravity. However, continuous vapor production from evaporation at the interface generates upward flow that suppresses these instabilities, maintaining the film's integrity by counteracting perturbation growth through shear and momentum transfer. This balance ensures the regime's persistence until sufficient cooling or external perturbations disrupt it.^[44]^[45]^[46] Experimental characterization of the film boiling regime is epitomized by Nukiyama's seminal boiling curve, derived from controlled-power experiments on nichrome wire immersed in water under atmospheric pressure. This curve plots heat flux against surface superheat, revealing the Leidenfrost minimum heat flux as the trough separating transition and stable film boiling, with values around 10-20 kW/m² for water depending on conditions. The curve highlights the regime's low-heat-transfer plateau, where flux increases gradually with superheat due to radiation and convection through the vapor film, providing a foundational framework for understanding boiling transitions.^[47]^[18]^[17]

Variations

Reactive Leidenfrost Phenomena

Reactive Leidenfrost phenomena arise when chemical reactions at the liquid-hot surface interface generate additional gases or vapors, thereby modifying the vapor cushion and overall dynamics beyond purely thermal evaporation. These reactions typically involve exothermic processes that produce heat and non-condensable gases, such as hydrogen, which supplement the steam layer and can enhance levitation stability or induce motion. A prominent example is the interaction of alkali metals, like sodium, with water. When a small piece of sodium is gently placed on the water surface under controlled conditions, the initial reaction 2Na + 2H₂O → 2NaOH + H₂ releases heat that melts the metal and generates hydrogen gas, creating a vapor layer that levitates the molten droplet. This reactive vapor cushion, stabilized by the Leidenfrost effect, allows the droplet to skate across the surface in a self-propelled manner before eventually bursting. The process temporarily forms a transparent molten hydroxide drop, which is further supported by the insulating vapor layer despite its density. Another instance occurs with organic liquids, such as alcohols (e.g., ethanol or ethylene glycol), on heated oxidized copper plates. The alcohols chemically reduce the copper oxide layer at the interface, forming native copper spots and releasing aldehydes or ketones as byproducts. This reaction alters the surface wettability and expands the effective contact area, with spot sizes sometimes exceeding the droplet radius, leading to modified levitation and potential directional motion. Critical reaction temperatures vary by liquid, ranging from 205°C for isopropyl alcohol to 465–485°C for tert-butyl alcohol. These interfacial reactions significantly impact droplet dynamics by accelerating evaporation through combined thermal and chemical heat inputs, while gas production from reactions like hydrogen evolution distorts the pressure distribution in the vapor layer, often promoting asymmetry and self-propulsion. Unlike the baseline Leidenfrost vapor cushion formed solely by boiling, reactive cases integrate gas evolution that can sustain levitation longer or induce oscillatory paths. Research in the 2010s, including Jungwirth et al.'s 2016 study on controlled alkali metal reactions achieving non-explosive regimes with glowing red-hot drops reaching ~600°C, and Celestini et al.'s 2016 work on redox mechanisms in alcohol-copper systems, highlighted these exothermic-driven propulsion effects.

Inverse and Suppressed Effects

The inverse Leidenfrost effect occurs when a relatively warm droplet is placed on a cryogenic liquid bath, such as liquid nitrogen, leading to levitation due to a vapor cushion formed by the rapid evaporation of the colder liquid.^[48] In this scenario, the temperature difference drives the evaporation of the bath liquid beneath the droplet, creating an insulating vapor layer that prevents direct contact and allows the droplet to hover and move across the surface.^[48] For instance, a room-temperature water droplet on a liquid nitrogen pool exhibits this levitation, with the effect governed by the heat transfer from the droplet to the bath, resulting in self-propulsion velocities that can be modeled based on vapor dynamics.^[49] Suppression of the standard Leidenfrost effect, where a hot surface insulates a liquid droplet via its own vapor, can be achieved through engineered surface modifications or external fields that disrupt the stable vapor film. Textured surfaces featuring micro-pillars enable capillary wicking, where liquid infiltrates the structures and pierces the vapor layer, thereby raising the Leidenfrost point—the minimum temperature for vapor cushion formation—by up to 100–150°C compared to smooth surfaces. Similarly, applying an electric field across the droplet and hot surface generates electrostatic forces that attract the liquid toward the substrate, destabilizing the insulating vapor gap and suppressing the effect even at temperatures well above the typical Leidenfrost point of around 230°C for water.^[50] These mechanisms enhance contact between the liquid and surface, promoting nucleate boiling and improved heat transfer for applications like high-temperature cooling. In the 2020s, studies on hierarchical nanostructures, combining micro-pillars with nanoscale features, have demonstrated further inhibition, allowing suppression of the Leidenfrost state up to 1150°C on water droplets by leveraging ultra-high porosity and superhydrophilicity to facilitate rapid liquid infiltration and vapor escape.^[22] As of 2024, further breakthroughs using bio-inspired hierarchical textures have extended suppression capabilities, revealing fundamental limits in the Leidenfrost regime for enhanced cooling.^[11] Such advancements, often using decoupled multiscale designs, provide sustained nucleate boiling without transition to film boiling, significantly boosting cooling efficiency.

Applications and Developments

Engineering and Industrial Uses

In cooling systems for nuclear reactors, the Leidenfrost effect plays a dual role by forming a vapor layer that insulates overheated fuel rods, potentially preventing meltdown during emergencies but significantly reducing heat transfer efficiency and prolonging cooling times.^[51] This phenomenon is particularly relevant in spray cooling scenarios, where maintaining surface temperatures below the Leidenfrost point is essential for effective emergency core cooling.^[52] Similarly, in electronics cooling, the effect hampers high-heat-flux dissipation in devices like microprocessors, as the insulating vapor film limits convective heat transfer and can lead to thermal runaway if not mitigated.^[53] In metallurgy and casting processes, the Leidenfrost effect enables droplet levitation, which prevents molten metal from adhering to hot mold surfaces and reduces defects like sticking or uneven solidification.^[54] For instance, in continuous casting of steel, the effect influences secondary spray cooling by creating a vapor barrier that stabilizes droplet behavior on the strand surface, aiding uniform heat extraction while avoiding direct contact damage.^[55] This levitation also benefits high-pressure die casting of aluminum, where lubricants exploit the effect to minimize tool wear and improve release properties at temperatures around 320–340°C.^[56] In culinary applications, the Leidenfrost effect contributes to searing techniques by generating a vapor cushion that insulates food from the pan surface, allowing high-temperature cooking without immediate burning or sticking.^[57] This is evident when water droplets skitter across a preheated stainless steel pan above approximately 200°C, mimicking the behavior during meat searing where surface moisture evaporates to form a protective layer, promoting even browning.^[12] A key challenge in these applications is the low heat transfer rate inherent to the vapor film, which limits quenching efficiency in processes like metal heat treatment and can extend cooling durations by orders of magnitude compared to nucleate boiling regimes.^[52] In industrial quenching, this insulation delays the transition to more effective cooling modes, potentially causing uneven material properties or safety risks, though strategies to suppress the effect—such as surface texturing—help restore higher transfer rates.^[54]

Recent Research Advances

Recent research has focused on engineered surfaces to suppress the Leidenfrost effect, enabling enhanced heat dissipation at high temperatures. In 2024, researchers at Virginia Tech developed micropillared surfaces that lower the Leidenfrost point to approximately 130°C, enabling Leidenfrost-like jumping of water microdroplets at reduced temperatures and improving heat dissipation through enhanced evaporation and droplet mobility.^[11] Similarly, studies on superhydrophilic hierarchical micro/nano structures on copper surfaces have demonstrated suppression of the Leidenfrost effect, achieving droplet contact and evaporation without levitation even at temperatures exceeding 300°C.^[58] Numerical simulations have advanced understanding of Leidenfrost dynamics in complex scenarios, particularly droplet impacts on superheated liquid pools. A 2025 direct numerical simulation study examined the early-stage dynamics of a Leidenfrost droplet impacting a superheated liquid pool, focusing on vapor generation and drainage in the gas cushion that delays contact. Unlike impacts on solid surfaces, the minimum film thickness is governed by vapor pressure equilibrium with capillary pressure at the spreading front, with evaporation significantly affecting liquid-vapor interface motion. The work derives self-similar solutions for film evolution under moderate and high superheat conditions.^[59] These simulations provide insights into multiphase flow behaviors. Investigations into thermal hysteresis have elucidated how surface wettability influences Leidenfrost persistence. A 2024 study published in Physical Review Research demonstrated that thermal hysteresis in wettability arises from temperature-dependent contact angle reductions during heating, causing the Leidenfrost temperature to vary by up to 50°C between heating and cooling cycles on the same surface.^[60] Once the surface hydrophilizes, the hysteresis vanishes until the contact angle recovers upon cooling, explaining prolonged Leidenfrost states in practical scenarios and guiding surface design for consistent heat transfer. Emerging applications leverage modified Leidenfrost behaviors for advanced cooling technologies. In 2025, research at MIT explored enhancing cryogenic quenching processes through low-effusivity polymeric coatings and microstructures to improve heat transfer, with applications in nuclear core cooling and in-space refueling of cryogenic fuels, potentially involving mitigation of vapor film effects like the Leidenfrost phenomenon.^[61] For electronics, engineered surfaces inducing controlled Leidenfrost failure have been proposed to enhance heat shedding in high-power devices, addressing thermal management challenges in compact systems at temperatures above 200°C.

References

[1]
Final fate of a Leidenfrost droplet: Explosion or takeoff - PMC
May 3, 2019 · When a liquid droplet is placed on a very hot solid, it levitates on its own vapor layer, a phenomenon called the Leidenfrost effect. Although ...
[2]
Study reveals final fate of levitating Leidenfrost droplets
May 6, 2019 · The research shows why levitating droplets on hot surfaces eventually explode if they start out large enough.
[3]
[PDF] BOILING AND THE LEIDENFROST EFFECT
Let me explain in terms of my experiments. When the temperature of the plate is less than the Leidenfrost point, the water spreads over the plate and rapidly ...
[4]
Levitating droplet cluster is NOT the Leidenfrost effect
Nov 11, 2017 · The Leidenfrost effect occurs at high temperatures above the boiling point of water. Typically, the Leidenfrost temperature is about 200 ºC ...
[5]
[PDF] The Leidenfrost Point: Experimental Study and Assessment of ...
Segev and Bankoff (1980) offered a more plausible explanation of the Leidenfrost phenomenon based on wetting characteristics. They proposed that wetting of ...
[6]
[PDF] Increasing Leidenfrost point using micro-nano hierarchical surface ...
Jan 26, 2016 · The Leidenfrost effect is undesirable in cooling applications as the vapor layer on which the liquid levitates acts as a heat transfer ...
[7]
Why boiling droplets can race across hot oily surfaces | MIT News
Aug 12, 2021 · A droplet of boiling water on a hot surface will sometimes levitate on a thin vapor film, a well-studied phenomenon called the Leidenfrost ...
[8]
New method reveals minimum heat for levitating drops
Sep 9, 2021 · In nature, Leidenfrost vapor layers can form at the interface between water and magma ascending from an undersea volcano. The effect has even ...
[9]
Virginia Tech researcher's breakthrough discovery uses engineered ...
May 24, 2024 · This has been referred to since its discover in the 18th century as the Leidenfrost effect, named for German physician Johann Gottlob ...
[10]
The thermo-wetting instability driving Leidenfrost film collapse - PMC
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 ...
[11]
Exploring the relationship between cooking and scientific discovery
Jun 15, 2023 · This can be seen when water droplets skitter on a hot pan instead of instantly evaporating. “The subtle squiggly structures that you see ...
[12]
The Boiling Phenomena and their Proper Identification and ...
May 20, 2020 · The various boiling behaviours such as nucleate, transition and film are controlled and defined by evaporation rate and associated heat transfer ...
[13]
(PDF) De Aquae Communis Nonnullis Qualitatibus Tractatus J.G. ...
PDF | Scan of the rare Tractatus of Johann Gottlob Leidenfrost made ... De Aquae Communis Nonnullis Qualitatibus Tractatus J.G. Leidenfrost 1756. May ...
[14]
Culinary fluid mechanics and other currents in food science
Jun 15, 2023 · Leidenfrost, J. G., 1756, De Aquae Communis Nonnullis Qualitatibus Tractatus (Ovenius, Frankfurt). Leighton, A., A. Leviton, and O. E ...
[15]
[PDF] Edward Yu. Bormashenko Physics of Wetting
Feb 13, 2023 · ... Johann Gottlob Leidenfrost published a ... [1] Leidenfrost J. G. De Aquae Communis Nonnullis Qualitatibus Tractatus, Duisburg, 1756.
[16]
Revisiting Nukiyama's experiment to enhance understanding of ...
In the early 1930s, Nukiyama (1934) conducted a landmark experiment of boiling on a nichrome wire in a saturated pool of water. His experimental setup allowed ...
[17]
[PDF] Historical Review of the Hydrodynamic Theory of Boiling
Engineers began to recognize the enormous potential of boiling for transferring heat under low temperature differences, during the 1930's. Over.Missing: 18th | Show results with:18th
[18]
Leidenfrost Effect - an overview | ScienceDirect Topics
The Leidenfrost effect refers to the phenomenon where a drop of liquid levitates above a hot solid surface due to the vapor layer generated by the heat, ...
[19]
BOILING - Thermopedia
For the simple case of a drop resting on a hot horizontal surface, this phenomenon is known as the Leidenfrost effect (observed by Leidenfrost in 1756) (see ...
[20]
Leidenfrost point and estimate of the vapour layer thickness
The Leidenfrost point is measured and the heat laws are used to estimate the thickness of the vapour layer, d≈0.06 mm, which prevents the drop from touching the ...Missing: vapor | Show results with:vapor
[21]
[PDF] Review of the dynamic Leidenfrost point temperature for droplet ...
The lower limit for the Leidenfrost effect, or the demar- cation between film boiling and transition boiling, is generally known as the Leidenfrost point (LFP) ...
[22]
Exploring the Leidenfrost Effect | COMSOL Blog
Nov 12, 2013 · The Leidenfrost effect, also known as film boiling, occurs when a liquid comes into contact with a solid that is at a temperature well above the liquid's ...
[23]
How ambient conditions affect the Leidenfrost temperature
Feb 19, 2021 · By sufficiently heating a solid, a sessile drop can be prevented from contacting the surface by floating on its own vapour. While certain ...Missing: Hermann | Show results with:Hermann
[24]
The cold Leidenfrost regime - PMC - PubMed Central - NIH
Jun 28, 2019 · Specifically, the Leidenfrost point is found to be around T* ≈ 130°C, a temperature both much smaller than TL ≈ 210°C and substantially higher ...
[25]
(PDF) Experimental investigation of spray cooling of horizontally and ...
May 24, 2022 · Leidenfrost temperature is lower for horizontal spray than vertically down flowing spray. and horizontally oriented. temperatures for each ...
[26]
Leidenfrost Temperature - an overview | ScienceDirect Topics
The Leidenfrost temperature depends on the surface quality, amount of water, etc. In continuous casting of steel, it is approximately in the range of 700–900 °C ...
[27]
[PDF] Creeping flow solution of the leidenfrost phenomenon
Physically, for a given pressure distribution under the drop less flow is required to keep the same pressure level for smaller values of 6, as prescribed by ...<|control11|><|separator|>
[28]
Leidenfrost droplet trampolining | Nature Communications
Mar 19, 2021 · Here we report a remarkable self-propulsion mechanism of Leidenfrost droplets against gravity, that we term Leidenfrost droplet trampolining.Results And Discussion · Trampolining Mechanism · Methods
[29]
[PDF] Computational modelling of Leidenfrost drops - WRAP: Warwick
The Leidenfrost effect, where a drop levitates on a vapour film above a hot solid, is simulated using an efficient computational model that captures the ...
[30]
Numerical study on the Leidenfrost behavior of a droplet stream ...
Jul 15, 2022 · The secondary droplets are distributed more towards the impingement point as the ambient pressure increases. This results in an easier ...
[31]
Self-propulsion of Leidenfrost Drops between Non-Parallel Structures
Sep 20, 2017 · As observed from our theoretical model, the motion is caused by uneven distribution of liquid pressure inside a squeezed drop. This self ...
[32]
High-speed X-ray imaging of the Leidenfrost collapse - Nature
Feb 7, 2019 · Leidenfrost droplets have also been studied using high-speed imaging of laser interference patterns. This method is able to quantify variations ...
[33]
[PDF] International Tables of the Surface Tension of Water - NB Vargaftik ...
This paper presents a table for the surface tension of water from 0.01 to 374 °C and an interpolating equation which represents the values in the table to ...Missing: linear | Show results with:linear
[34]
[PDF] leidenfrost drops - ORBi
This chapter is concerned with drop levitation on a vapor layer when a volatile liquid is brought into contact with a very hot solid.
[35]
Leidenfrost flows: instabilities and symmetry breakings
Jul 12, 2022 · As the surface tension gradient induces Marangoni flow from low surface tension to the higher one along the surface boundary, the flow ...
[36]
Azimuthal rotation induced by the Marangoni force makes small ...
In summary, we observed a zigzag motion of submillimeter ( R < 0.6 mm ) water Leidenfrost droplets moving on a flat horizontal silicon wafer heated at 250 ∘ C .
[37]
Heat Transfer in Stable Film Boiling - eScholarship
Download PDF. Main. PDF. Share. EmailFacebook. Heat Transfer in Stable Film Boiling. 1949. Bromley, LeRoy A. ... Main Content Metrics Author & Article Info.
[38]
Film-Boiling Heat Transfer From a Horizontal Surface
Taylor-Helmholtz Hydrodynamic Instability and its significance with regard to film boiling heat transfer from a horizontal surface is discussed.
[39]
Subcooled pool film boiling heat transfer from small horizontal ...
Studies of saturated film boiling at pressures close to the critical pressure show that analytical models and correlations developed for normal pressures (P ≪ ...Missing: limitations | Show results with:limitations
[40]
Film Boiling - an overview | ScienceDirect Topics
Bromley developed a theory to predict the heat transfer coefficient for stable film boiling on the outside of a horizontal cylinder, and the basic analysis ...
[41]
[PDF] On the Frontier of Boiling Curve and beyond Design of its Origin
Nukiyama was the first who in 1934 experimentally identified different regimes of pool-boiling and invented the Boiling Curve [1]. By controlling the power ( ...Missing: recognition | Show results with:recognition
[42]
Mesoscale simulations of boiling curves and boiling hysteresis ...
Boiling hysteresis between increasing heating and decreasing heating are also simulated numerically. It is confirmed numerically that boiling hysteresis exists ...
[43]
[PDF] 6.5.5 Film Boiling
However, these flows are usually quite unsteady since the vapor/liquid interface is unstable to Rayleigh-Taylor instability (see section 6.2.5). The result ...<|control11|><|separator|>
[44]
Three-dimensional simulation of film boiling on a horizontal surface ...
Oct 1, 2024 · ... suppresses the Rayleigh-Taylor instability, causing a delay or even complete suppression of vapor bubble detachment. These additional ...
[45]
The non-boiling vapour film - ScienceDirect.com
The Rayleigh–Taylor instability can be completely suppressed by a phase transition at a certain critical heat flux of subcooling. This is shown in experimental ...
[46]
[PDF] TED Plaza Some Remarks on the Nukiyama Curve
It was about 70 years ago when Shiro Nukiyama published his pioneering paper on “Maximum and. Minimum Values of Heat Q Transmitted from Metal to Boiling ...
[47]
Inverse Leidenfrost Effect: Levitating Drops on Liquid Nitrogen
Apr 7, 2016 · In this scenario, heat transfer occurs through film-boiling: a nitrogen vapor layer develops that may cause the drop to levitate at the bath ...Missing: terminology shift mid-
[48]
Self-propulsion of inverse Leidenfrost drops on a cryogenic bath
Jan 22, 2019 · ... the drop velocities can be accurately reproduced. Keywords: drops; inverse Leidenfrost effect; liquid nitrogen bath; self-propulsion.
[49]
Electrostatic suppression of the Leidenfrost state using AC electric ...
Oct 5, 2017 · The objective of this study is to understand the physics underlying reduced suppression of the Leidenfrost state under AC electric fields. First ...
[50]
Delayed Leidenfrost phenomenon during impact of elastic fluid ...
Nov 4, 2020 · This hints towards a transition regime between the Leidenfrost phenomenon and contact boiling, wherein the vapour cushion is potent enough to ...Delayed Leidenfrost... · Abstract · 3. Results And Discussions<|control11|><|separator|>
[51]
[PDF] Leidenfrost droplets on microstructured surfaces
This latterly- called Leidenfrost effect was first reported in 1732 by Boerhaave [1] who noted that ethanol droplets deposited on superheated metal surfaces ...Missing: history | Show results with:history
[52]
A paradigm shift in liquid cooling by multitextured surface design - NIH
Mar 4, 2022 · To inhibit the Leidenfrost effect above 1,000°C for sustained thermal cooling, the multitextured STA is designed with three features (Figure 1): ...
[53]
Prediction of Leidenfrost Temperature in Spray Cooling for ... - MDPI
The Leidenfrost temperature, TL, is of paramount importance to metal alloy quenching since it marks the transition from very poor heat transfer in film boiling ...
[54]
Secondary cooling in continuous casting and Leidenfrost ...
The paper presents new experimental findings regarding specification of the Leidenfrost temperature, which is the point between high and low surface temperature ...
[55]
[PDF] ALUMINIUM DIE CASTING: LUBRICATION TECHNOLOGY AND ...
Soft water wets at about 320°C while hard water has a Leidenfrost point of about 340°C. Conventional die lubricants made with soft water show similar results.
[56]
[PDF] SEMINAR IN PHYSICS
Apr 8, 2016 · The Leidenfrost Effect can be observed when cooking with a hot pan. If the surface of the pan is hot the water will boil away, ...
[57]
Inhibiting the Leidenfrost effect by hierarchical micro and nano ...
In this work, we propose a hierarchical micro/nano structure with a simple process and low cost, which is characterized by superhydrophilicity and high ...
[58]
Direct numerical simulations of Leidenfrost drop impacting onto ...
Mar 13, 2025 · Through direct numerical simulations, we closely examine the transient dynamics of vapour flow confined within the thin film, with a particular focus on the ...
[59]
Thermal hysteresis in wettability and the Leidenfrost phenomenon
Sep 12, 2024 · It was nearly 270 years ago when Leidenfrost made the careful observation of a drop of water hovering on its own vapor cushion when deposited on ...Missing: terminology | Show results with:terminology
[60]
Using classic physical phenomena to solve new problems | MIT News
Oct 31, 2025 · When a cryogen is used to cool down a surface, it undergoes what is known as the Leidenfrost effect, which means it first forms a thin vapor ...