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Marangoni effect

The Marangoni effect is the or along an between two immiscible fluids, driven by a in the of that interface, causing fluid to flow from regions of lower to higher . This phenomenon, also known as the Gibbs–Marangoni effect, was first systematically investigated in the 1860s by Italian physicist Carlo Giuseppe Marangoni during his studies of oil drops spreading on surfaces. Surface tension gradients responsible for the Marangoni effect typically arise from either temperature variations, known as the thermocapillary effect, or concentration differences of solutes or , termed the solutocapillary effect. In the thermocapillary case, heating reduces , prompting surrounding cooler fluid to flow toward the heated region; similarly, in solutocapillary flows, depletion of surface-active components like lowers tension, inducing compensatory motion. The Marangoni effect manifests in everyday observations, such as the "tears of wine," where evaporation of alcohol from the meniscus of a wine glass creates a surface tension gradient that draws liquid upward along the glass walls, forming droplets that descend under gravity. It also influences industrial processes, including enhanced mass transfer in liquid-liquid extractions, fluid dynamics in welding pools to control melt flow, and evaporation dynamics in desalination systems for improved efficiency. In modern applications, the effect is harnessed in microfluidics for precise droplet manipulation in lab-on-a-chip technologies and in space-based experiments to study convection without gravitational interference.

Fundamentals

Definition

The Marangoni effect is the or that occurs along an between two immiscible fluids, such as a liquid-gas or liquid-liquid boundary, due to a in . This induces tangential stresses at the , causing fluid motion from regions of lower to regions of higher . Unlike buoyancy-driven , such as Rayleigh-Bénard , the Marangoni effect is specifically governed by interfacial properties rather than differences. Surface tension gradients driving the Marangoni effect arise primarily from variations in , known as the thermocapillary effect, or from differences in solute concentration, referred to as the solutocapillary or diffusocapillary effect. In advanced cases, gradients can also stem from , leading to electrocapillary flows. This phenomenon was first observed by James Thomson in 1855 while studying the "tears of wine" in alcoholic liquids. A simple illustration of the Marangoni effect involves a droplet placed on a heated surface, where the warmer edge of the droplet experiences reduced compared to the cooler center, prompting fluid to flow outward and causing the droplet to spread. This tangential motion enhances mixing and transport at the .

Historical Development

The Marangoni effect was first observed in 1855 by Scottish physicist James Thomson, who described fluid motion driven by temperature-induced variations in while studying the "" phenomenon in alcoholic . In his paper, Thomson noted that differences in caused to from regions of lower to higher tension, leading to observable streaming in thin films. This mechanism was independently explored and elaborated upon by Italian physicist Carlo Giuseppe Marangoni in his 1865 doctoral thesis at the , titled Sull'espansione delle goccie d'un liquido galleggianti sulla superficie di altro liquido. Marangoni conducted experiments with pendant drops and floating liquid droplets, demonstrating how surface tension gradients due to or composition differences induce interfacial flows, providing a qualitative explanation for such motions. Although Thomson's work predated Marangoni's, the effect is named after Marangoni for his systematic study and formalization of the underlying principles. Early references to the phenomenon were often termed "surface tension flow," but it evolved into the standardized "Marangoni effect" by the mid-20th century as theoretical analyses confirmed its role in . In 1958, John R. A. Pearson provided the first rigorous theoretical framework, analyzing the onset of cellular in thin layers driven by gradients rather than , deriving criteria for such instabilities. By the , the effect gained prominence in literature, notably through the 1959 work of C. V. Sternling and L. E. Scriven on interfacial , which modeled the "interfacial engine" mechanism and highlighted its implications for and instability.

Physical Mechanism

Surface Tension Gradients

Surface tension, denoted as \sigma, represents the energy required to increase the surface area of a liquid by a unit amount, equivalent to the force per unit length acting along the interface, with units of J/m² or N/m. This property arises from the cohesive forces between liquid molecules, which are stronger at the surface compared to the bulk. For most liquids, \sigma decreases with increasing temperature, as thermal agitation weakens intermolecular bonds, leading to a negative temperature coefficient d\sigma/dT < 0. Similarly, the addition of surfactants typically reduces \sigma with increasing concentration up to the critical micelle concentration, due to the amphiphilic molecules adsorbing at the interface and disrupting cohesion. Spatial variations in along a , or gradients \nabla \sigma, form the core of the Marangoni effect's driving mechanism. These gradients arise from inhomogeneous distributions of (\nabla T) or concentration (\nabla c) at the interface, expressed conceptually as \nabla \sigma = (\partial \sigma / \partial T) \nabla T + (\partial \sigma / \partial c) \nabla c. For thermal gradients, since d\sigma/dT < 0, warmer regions exhibit lower \sigma, while for surfactant-induced gradients, higher concentrations lead to lower \sigma where d\sigma/dc < 0. Such inhomogeneities can occur due to localized heating, evaporation creating concentration differences (as briefly seen in the phenomenon), or uneven distribution. The \nabla \sigma generates a tangential at the , \tau = \nabla \sigma, which acts parallel to and drives motion from regions of low \sigma to high \sigma. This stress pulls liquid toward areas of higher , inducing interfacial flow that propagates into the bulk , assuming no-slip conditions at the as per basic principles. The resulting motion balances against viscous forces within the , where the viscous opposes the Marangoni stress, determining the overall and . In low- fluids, this balance allows rapid, pronounced flows, while higher viscosity dampens the effect. Experimental demonstrations using surfactants highlight the controllability of these gradients and the potential for flow reversal relative to thermal cases. In drying droplets of surfactant-laden solutions, such as those with trace amounts of Triton X-100, the adsorption of surfactants at the evaporating edge creates a concentration gradient with lower \sigma at the periphery, inducing inward Marangoni flow toward the center—opposite to the outward thermal Marangoni flow driven by temperature gradients in pure liquids. This reversal has been visualized through particle tracking in optical microscopy, showing uniform central deposition instead of edge rings, confirming the dominance of solutal over thermal gradients in such systems.

Mathematical Description

The mathematical description of the Marangoni effect begins with the Navier-Stokes equations for , augmented by boundary conditions at the to account for gradients. At a flat (z=0), the no-penetration condition imposes zero normal velocity, w = 0, while the tangential velocity is driven by the gradient through the stress balance \nabla \sigma = \mu \frac{\partial \mathbf{u}_\parallel}{\partial z}, where \sigma is the , \mu is the dynamic , and \mathbf{u}_\parallel is the tangential velocity component. To analyze the onset of Marangoni-driven instabilities, such as in a thin liquid layer heated from below, the problem is nondimensionalized, introducing the Marangoni number Ma = -\frac{d\sigma}{dT} \frac{\Delta T \, h}{\mu \alpha}, which compares thermocapillary forces to viscous and diffusive forces; here, d\sigma/dT is the temperature dependence of (typically negative), \Delta T is the temperature difference across the layer of thickness h, and \alpha is the . For the solutocapillary case, driven by concentration gradients, the analogous solutal Marangoni number is Ma_s = -\frac{d\sigma}{dc} \frac{\Delta c \, h}{\mu D}, where d\sigma/dc is the concentration dependence of , \Delta c is the concentration difference, and D is the solute coefficient. Linear stability analysis of the base conduction state reveals the threshold. Assuming small perturbations to , , and , the governing equations are linearized, and analysis yields a whose neutral curve determines the critical Marangoni number; for insulating upper boundaries in the Bénard-Marangoni problem, Ma_c \approx 79.6. For complex geometries or nonlinear regimes, (CFD) simulations solve the full Navier-Stokes equations with Marangoni boundary conditions, enabling prediction of flow patterns beyond analytical limits.

Key Phenomena

Tears of Wine

The , also known as wine legs, manifest as scalloped droplets or ridges that form on the interior surface of a wine glass after swirling, climbing upward against before descending in a periodic manner. This visually striking phenomenon exemplifies the Marangoni effect on a , driven by evaporation-induced flows that create alternating bands of liquid accumulation. The underlying mechanism begins at the liquid-air meniscus, where the more volatile ethanol in the wine evaporates faster than water, resulting in a depleted alcohol concentration and thus higher surface tension at the exposed surface compared to the bulk liquid below, which retains more ethanol and lower surface tension. This gradient induces a tangential stress that pulls the lower-tension bulk liquid upward along the glass wall to equalize the tension, forming a thin climbing film. As the film ascends, continued and cooling at the top further increase local , sustaining the upward flow until the accumulated liquid reaches a critical height where overcomes the Marangoni , causing the film to thicken into droplets or ridges that then drain back down the wall. The repeats as new gradients reform at the base, perpetuating the rise and fall of the until the concentration diminishes sufficiently. Several factors influence the prominence of wine tears: higher alcohol content enhances the effect because ethanol reduces more dramatically than (e.g., surface tension drops from about 72 mN/m for to around 22 mN/m for pure ), leading to steeper gradients. The curved shape of a typical promotes ridge formation by concentrating the flow, while higher temperatures accelerate and thus the climbing rate; in contrast, pure shows only faint, slow-moving traces due to minimal composition-driven variations. The phenomenon has been observed for centuries in wine consumption, but its scientific explanation via gradients was first articulated by James Thomson in 1855 and elaborated by Carlo Marangoni in his 1871 doctoral thesis on liquid spreading. For experimental replication outside a , an -water (e.g., 10-20% ethanol by volume) can be placed on an inclined plate partially submerged in a of the same , producing analogous climbing films and periodic droplet detachment driven by the same solutocapillary mechanism.

Bénard-Marangoni Convection

Bénard-Marangoni convection arises in a thin horizontal layer of liquid heated from below, with the upper surface exposed to air or another fluid phase, creating a vertical temperature gradient that drives instability through both buoyancy and surface tension effects. In this setup, the liquid layer typically has a depth on the order of millimeters, where conduction maintains a nearly linear temperature profile in the quiescent state. The onset of instability combines Rayleigh-Bénard effects due to and Marangoni effects from gradients, with the latter dominating in sufficiently thin films where is negligible, generally for depths less than 1 mm. As the temperature difference across the layer increases, the conductive state becomes beyond a critical Marangoni number, leading to the formation of organized convective patterns. The resulting patterns consist of hexagonal convection cells, stabilized by nonlinear interactions between the flow and temperature perturbations, where hot fluid rises at the centers of the cells, cools along the edges, and descends at the boundaries between cells. These hexagons emerge as the preferred planform due to the coupling of vertical buoyancy-driven flows with horizontal surface tension-driven flows, with a characteristic wavelength approximately twice the layer depth. Experimental observations of these cells were first reported by Henri Bénard in 1900, who heated thin layers of and observed regular hexagonal patterns forming spontaneously above a critical , though the role of was not recognized at the time. The Marangoni contribution was later clarified theoretically by J.R.A. Pearson in 1958, who analyzed the stability of a non-deformable and predicted the onset for pure thermocapillary instability. For a non-deformable surface, the critical Marangoni number is Ma_c = 79.6, corresponding to the point where perturbations grow, with the critical wave number around 2, yielding the observed size. At higher Marangoni numbers, the steady hexagonal patterns can transition to oscillatory instabilities, where traveling waves or time-dependent deformations disrupt the stationary cells, often due to interactions with surface deformations or ambient gas flow. The presence of can suppress the onset by reducing gradients or enhance it by introducing additional concentration-driven Marangoni effects, altering the critical conditions and pattern stability. Modern studies employ infrared thermography to visualize the fields on the , revealing the dynamic evolution of hot spots at cell centers and confirming the predicted hexagonal structures in without invasive tracers.

Applications and Implications

Role in

The Marangoni effect plays a pivotal role in enhancing and processes by inducing interfacial that significantly increases the effective across fluid interfaces. In scenarios, such as sessile microdroplets, the thermocapillary-driven Marangoni flow can amplify internal velocities by up to 100 times compared to pure , thereby boosting rates by approximately 2.5% through altered distributions and convective mixing. Similarly, in gas-liquid systems, the addition of surface-active agents triggers Marangoni instabilities that disturb the , leading to enhanced coefficients by promoting turbulent-like over stagnant layers. This enhancement is particularly pronounced in low-Reynolds-number flows where diffusive alone yields insufficient rates, as the surface gradients drive recirculating flows that renew the continuously. Solutal Marangoni effects, arising from concentration gradients in or multicomponent mixtures, couple strongly with to influence transport dynamics, notably in drying processes for . In evaporating polymer solutions like polyisobutylene/, solutal gradients induce Bénard-Marangoni cells that dominate over thermal effects in thin layers, accelerating solute redistribution and preventing uneven deposition. This mechanism underpins "Marangoni drying," where a vapor-phase solvent (e.g., ) creates a gradient on a water-wetted , pulling a thin liquid film to dryness without particle or , achieving ultraclean surfaces in thin-film applications. In multicomponent systems, these effects extend to complex rheologies, where Marangoni flows interact with non-Newtonian behaviors, such as in layered fluids, altering effective and transport rates during or formation. The Marangoni effect often competes with other transport mechanisms, dominating in regimes where diffusion is rate-limiting or buoyancy is suppressed, such as in microscale or thin-layer configurations. At low diffusion rates, Marangoni convection surpasses pure Fickian transport when the Marangoni number exceeds a critical threshold, introducing advective contributions that scale the overall transfer. In thicker layers, buoyancy-driven flows may prevail, but in microgravity or sub-millimeter scales, surface tension gradients override gravitational effects, as buoyancy forces diminish while Marangoni stresses persist. This competition is evident in evaporating films, where Marangoni flows compete with buoyancy to shape cellular patterns, with Marangoni dominating in low-bond-number scenarios typical of thin geometries. Quantitatively, the Marangoni effect elevates in falling films, where the scales as Sh \sim Ma^{1/4}, reflecting the boundary-layer induced by interfacial velocities proportional to the fourth root of the Marangoni number. Accurate modeling in thus requires incorporating Marangoni stresses into boundary-layer approximations, such as for thin films, to predict enhanced transfer coefficients and avoid underestimating convective contributions in processes like or .

Modern Applications

In , the Marangoni effect enables droplet propulsion and enhanced mixing in devices through thermocapillary pumping, where temperature-induced gradients drive autonomous micromotors without external mechanical components. Research from the demonstrated that such systems can achieve controlled droplet velocities up to several millimeters per second, facilitating precise fluid manipulation for biochemical assays. In materials processing, the Marangoni effect improves uniformity during by counteracting gravitational instabilities through solutal or gradients that promote even spreading. In welding, it influences to reduce defects like , with reversed Marangoni via addition enhancing by up to 50% in austenitic steels. Similarly, in such as powder bed fusion, Marangoni-driven flows mitigate keyhole instabilities, leading to denser microstructures with fewer cracks. In , the Marangoni effect contributes to on substrates via durotaxis, where gradients from variations direct collective spreading, as observed in epithelial rearrangements. For , surfactant-induced Marangoni flows in emulsions enable targeted and therapeutic transport across interfaces, improving release in pulmonary applications compared to passive . In , solutocapillary Marangoni flows drive of particles at liquid interfaces, forming ordered monolayers for photonic materials with tunable lattice constants. Post-2020 advancements include thermocapillary shaping of thin liquid films using light-programmed thermal gradients for sub-micron patterns in . In energy applications, the Marangoni effect enhances in phase-change materials by inducing that accelerates rates by a factor of two or more under microgravity conditions, relevant for thermal storage systems. It also boosts in collectors through interfacial flows that improve absorber wetting and reduce thermal resistance. Recent developments as of 2024 include its use in fabricating cells to control and achieve uniform films for higher . Emerging applications in leverage programmed Marangoni gradients for shape-changing actuators, enabling untethered locomotion in liquids with response times under 1 second. Recent gel-based designs integrate chemical fuels for sustained deformation, addressing gaps in biotech interfaces by mimicking biological . A key challenge in these applications is suppressing unwanted Marangoni effects in -laden systems to maintain , as insoluble can dampen thermal flows by increasing interfacial rigidity when concentrations exceed critical levels. This suppression is essential for preventing instabilities in emulsions and coatings, though it requires precise control of adsorption kinetics.

References

  1. [1]
    Marangoni Effect - an overview | ScienceDirect Topics
    The Marangoni effect is a force caused by inhomogeneities in surface energy, causing liquid flow from low to high surface tension areas.Missing: history | Show results with:history<|control11|><|separator|>
  2. [2]
    The Marangoni effect: A fluid phenom (w/ Video) - Phys.org
    Mar 11, 2011 · This phenomenon is named after Italian physicist Carlo Marangoni who first studied the phenomenon in the 19th century. Video of the Marangoni ...
  3. [3]
    Tears of Wine and the Marangoni Effect | COMSOL Blog
    Mar 24, 2015 · Italian physicist Carlo Marangoni later studied the topic for his doctoral research and published his findings in 1865. The Marangoni effect ...Missing: discovery | Show results with:discovery
  4. [4]
    What Is the Marangoni Effect? - COMSOL
    Jul 2, 2015 · The Marangoni effect takes place when there is a gradient of surface tension at the interface between two phases – in most situations, a liquid-gas interface.Missing: scientific | Show results with:scientific
  5. [5]
    On the Rayleigh-Bénard-Marangoni problem: Theoretical and ...
    Now is recognized that the Marangoni effect is the main cause of instability and convection in the Bénard original experiments [23]. Previous considerations ...
  6. [6]
    [PDF] Marangoni instabilities associated with heated surfactant ... - HAL
    Sep 16, 2024 · When a concentration gradient is responsible for the variation in surface tension, the Marangoni effect is known as the solutocapillary effect, ...
  7. [7]
    Solutal Marangoni effect and chemical reactions on interfacial ...
    Jul 31, 2025 · In addition, Marangoni flow can also result from the interplay of thermocapillary and solutocapillary effects under thermodiffusion conditions.
  8. [8]
    Marangoni effects under electric fields - ScienceDirect.com
    An electric field when applied across liquid-liquid interface was found to cause, due to different susceptibilities of the two phases, what the authors ...
  9. [9]
    Marangoni effect
    James Thomson (1855) "On certain curious Motions observable at the Surfaces of Wine and other Alcoholic Liquors," Philosophical Magazine, 10 : 330-333.
  10. [10]
    Rapid droplet spreading on a hot substrate - AIP Publishing
    Sep 1, 2021 · Due to heat transfer between the substrate and droplet, the temperature at the droplet surface is not uniform, leading to variation in surface ...
  11. [11]
    Marangoni - an overview | ScienceDirect Topics
    This generates tangential forces, which are called Marangoni forces, named after the Italian physicist Carlo Guiseppe Marangoni (1840–1925). These forces ...Missing: history | Show results with:history
  12. [12]
    XLII. On certain curious motions observable at the surfaces of wine ...
    On certain curious motions observable at the surfaces of wine and other alcoholic liquors. James Thomson A.M. C.E. Belfast. Pages 330-333 | Published online ...
  13. [13]
    https://www.tandfonline.com/doi/abs/10.1080/14786445508641982
  14. [14]
    Marangoni Force - an overview | ScienceDirect Topics
    Marangoni forces: James Thomson (1855) proposed this force in his article “On certain curious Motions at the Surfaces of Wine and other Alcoholic Liquors” [93].<|separator|>
  15. [15]
    On convection cells induced by surface tension | Journal of Fluid ...
    Mar 28, 2006 · On convection cells induced by surface tension. Published online by Cambridge University Press: 28 March 2006. J. R. A. Pearson.
  16. [16]
    [PDF] Surface tension
    Surface tension is thus identical to the surface energy density. This is also reflected in the equality of the natural units for the two quantities, N/m = J/m2.
  17. [17]
    Measurement of Surface Interfacial Tension as a Function of ...
    Dec 14, 2011 · For most fluids, surface (interfacial) tension decreases with the increase of temperature. Surface tension gradients created as a result of ...
  18. [18]
    Surfactant Self-Assembling and Critical Micelle Concentration - NIH
    In the first plateau, surface tension is close to that of pure water (72 mN/m) since the low surfactant concentration does not affect the surface tension. The ...
  19. [19]
    [PDF] LECTURE 4: Marangoni flows - MIT
    Marangoni flows are those driven by surface tension gradients. In general, surface tension σ de- pends on both the temperature and chemical composition at the ...
  20. [20]
    Marangoni Effect Reverses Coffee-Ring Depositions
    Marangoni Effect Reverses Coffee-Ring Depositions. Click to copy article link ... Marangoni Effect Reverses Coffee-Ring Depositions. 0 views. 0 shares. 0 ...
  21. [21]
    [PDF] Numerical simulation of pure solutal Marangoni convection in a ...
    The solutal Marangoni number is defined as μν σ. LC. C. Ma l h. C. ) (. -. -. = (13) where σC = ∂σ/∂C (<0) is the surface tension coefficient of the ...
  22. [22]
    Bounds on heat transport in Bénard-Marangoni convection
    Apr 5, 2010 · In 1958, Pearson showed that the steady conduction solution, u = 0 and T = − z , is linearly unstable when the Marangoni number exceeds 79.61Missing: effect | Show results with:effect
  23. [23]
    Numerical study of the Marangoni effect induced by soluble ...
    Feb 5, 2024 · In this study, we present a numerical investigation into the phenomenon of rising droplets in immiscible fluids, focusing on the Marangoni ...
  24. [24]
    Why My Wine Glass Cries - Physics Magazine
    Mar 17, 2020 · An understanding of these tears has long been based on the so-called Marangoni effect—an evaporation-induced liquid flow. But a team from the ...
  25. [25]
    Tears of wine: The dance of the droplets - ScienceDirect.com
    Thomson. On certain curious motions observable at the surfaces of wine and other alcoholic liquors. Philos Mag Ser. (1855). J. Maxwell. Theory of heat: longmans.
  26. [26]
    Tears of wine created by gravity induced shock waves - Physics World
    Apr 21, 2020 · For more than a century, physicists have known that wine climbs the side of a glass in a process called Marangoni flow. In 1855, James Thompson ...
  27. [27]
    (PDF) Introductory analysis of Bénard–Marangoni convection
    Aug 6, 2025 · We describe experiments on Bénard–Marangoni convection which permit a useful understanding of the main concepts involved in this phenomenon.
  28. [28]
    Stability analysis of Rayleigh–Bénard–Marangoni convection in ...
    Oct 1, 2024 · Bénard–Marangoni (BM) convection, driven by surface tension, primarily occurs in thin liquid layers or under microgravity conditions. Utilizing ...
  29. [29]
    Wavelength selection in B\'enard-Marangoni convection | Phys. Rev. A
    Feb 1, 1987 · The pattern changes in an almost continuous way and shows a wavelength increase when Γ becomes greater. The wavelengths for a container where Γ ...Missing: ≈ 2h source
  30. [30]
    Thermocapillary instabilities in a liquid layer subjected to an oblique ...
    Nov 13, 2020 · $Ma_c=79.6$ exists for the imposed purely VTG (Pearson Reference Pearson1958). ... The continuation of the finite-wavelength mode also falls under ...
  31. [31]
    Henri Bénard and pattern-forming instabilities - ScienceDirect.com
    The first quantitative experimental study of thermal convection was carried out by Henri Bénard, who published his first results in two articles in the Comptes ...
  32. [32]
    Steady and oscillatory side-band instabilities in Marangoni ...
    It is shown that the monotonic instability is always subcritical, while the long-wave oscillatory instability can be supercritical, leading to the formation of ...
  33. [33]
    Role of surfactant-induced Marangoni effects in droplet dynamics on ...
    Accumulation of surfactants near the receding contact line reverses the local concentration gradient, attempts to change its direction along the interface, and ...
  34. [34]
    Full article: In Situ Observation of Thermal Marangoni Convection on ...
    May 17, 2012 · Temperature gradient induced Marangoni convection is observed in situ in the present study with the help of an infrared (IR) thermal imager ( ...
  35. [35]
    Influence of Marangoni Effect on Heat and Mass Transfer during ...
    Nov 13, 2022 · This paper builds a coupled thermal mass model of droplet evaporation and tests the accuracy of the numerical model through theoretical results.
  36. [36]
    Improved Absorption in Gas−Liquid Systems by the Addition of a ...
    The purpose of this study is to apply this Marangoni effect to the gas−liquid contact system to understand the effect of the induced interfacial disturbance and ...
  37. [37]
    [PDF] University of Groningen Marangoni convection, mass transfer and ...
    This thesis is concerned with the influence of the Marangoni effect on mass transfer across a liquid-gas interface. The phenomenon of liquid flowing along ...
  38. [38]
    Free convection in drying binary mixtures: Solutal versus thermal ...
    Solutal Marangoni phenomena occurring during drying of polymer solutions are investigated through numerical simulations.
  39. [39]
    Marangoni drying: A new extremely clean drying process | Langmuir
    Marangoni drying: A new extremely clean drying process. Click to copy ... Dip coating in the presence of an opposing Marangoni stress. The European ...
  40. [40]
    https://www.sciencedirect.com/science/article/abs/pii/S0017931013002883
  41. [41]
    Marangoni effect induced convection in material processing under ...
    The experiment on Marangoni flow visualization is being performed in order to investigate the characteristics of convection in uni-dimensional melt growth ...<|control11|><|separator|>
  42. [42]
    Three-dimensional Marangoni cell in self-induced evaporating ...
    Jan 13, 2014 · This means that despite the phenomenon being Marangoni driven, buoyancy effects are important and the competition between buoyancy and ...<|separator|>
  43. [43]
    Dynamics of a falling film with solutal Marangoni effect | Phys. Rev. E
    Sep 15, 2008 · The boundary-layer approximation is performed by assuming that the strong surface tension effects induce large wavelengths (in comparison ...
  44. [44]
    Thermocapillarity in Microfluidics—A Review - PMC - PubMed Central
    Researchers have proved that thermocapillarity can produce flow circulations (Marangoni instabilities), affect the evaporation physics, and most importantly ...Missing: propulsion autonomous
  45. [45]
    Marangoni Effect-Driven Motion of Miniature Robots and Generation ...
    We study self-propelled dynamics of a droplet due to a Marangoni effect and chemical reactions in a binary fluid with a dilute third component of chemical ...
  46. [46]
    Thermal Marangoni-driven dynamics of spinning liquid films
    Aug 19, 2019 · Temperature gradients are known to affect thin liquid films through their influence on the local fluid surface tension as Marangoni stresses. We ...Missing: welding | Show results with:welding
  47. [47]
    Marangoni effects in welding - Journals
    It is shown that for normal GTA/TIG welding conditions the Heiple–Roper theory is valid, ie that weld penetration is controlled by the fluid flow in the weld ...
  48. [48]
    Simulation of the Marangoni Effect and Phase Change Using ... - MDPI
    The Marangoni effect and natural convection are the driving forces of flow in the melt pool of a welding or additive manufacturing process. Both effects are ...Missing: film printing
  49. [49]
    [PDF] Marangoni effect and cell spreading - arXiv
    The cell SS generation during CCM occurs via natural and forced convection. The natural convection is caused by inhomogeneous distribution of the tissue surface.Missing: drug delivery emulsions
  50. [50]
    Surfactant-induced Marangoni transport of lipids and therapeutics ...
    The roles of key system variables are identified, including surfactant solubility, drop miscibility with the subphase, and the thickness, composition and ...
  51. [51]
    Self-Organization Emerging from Marangoni and Elastocapillary ...
    Aug 25, 2022 · In this paper, we investigate how Marangoni flow and capillary effects together establish self-organization at air–water interfaces, via self- ...
  52. [52]
    Programmable thermocapillary shaping of thin liquid films | Flow
    Aug 23, 2022 · We present a method that leverages projected light patterns as a mechanism for freeform deformation of a thin liquid film via the thermocapillary effect.
  53. [53]
    The “Effect of Marangoni Convection on Heat Transfer in Phase ...
    The experiment “Effect of Marangoni Convection on Heat Transfer in Phase Change Materials” aims to investigate the efficacy of thermal Marangoni convection.Missing: collectors | Show results with:collectors
  54. [54]
    Enhancement of thermoelectric energy harvesting of thermal ...
    Feb 15, 2023 · The porous matrix weakens the Marangoni effect by decreasing the surface shear stress while increasing the effective thermal conductivity.Missing: collectors | Show results with:collectors
  55. [55]
    Bio-inspired untethered fully soft robots in liquid actuated by induced ...
    We report the agile untethered mobility of a fully soft robot in liquid based on induced energy gradients and also develop corresponding fabrication and ...Missing: shape- | Show results with:shape-
  56. [56]
    Gel-Based Marangoni Actuators: Mechanisms, Material Designs ...
    Sep 11, 2025 · The Marangoni effect was first systematically proposed by the Italian physicist Carlo Marangoni in 1865. It is a type of interfacial fluid ...Missing: doctoral | Show results with:doctoral<|control11|><|separator|>
  57. [57]
    Competition between thermal and surfactant-induced Marangoni ...
    Sep 15, 2022 · It is found that insoluble surfactants can suppress the thermal Marangoni flow if their concentration is sufficiently large and evaporation and diffusion are ...