A three-fluid model for the dissipation of interfacial capillary-gravity waves

The methods to study capillary waves have been reviewed, together with the emerging practical applications of theirs and new theoretical developments in the field. The focus is on monochromatic ripples of frequency in the range 0.1-10 kHz. A capillary wave apparatus has been constructed that combines several recent advances on the technique. It is based on profilometry of waves decaying with distance, with a highspeed video camera detecting light refracted by the surface. A code to process the images has been developed that executes a regression analysis to determine the characteristics of the wave. High precision and accuracy have been achieved: standard deviation from the mean of ±0.5% for the wavelength and ±7% for the decay length; mean deviations from the theoretical values ±0.2% for the wavelength and ±5% for the decay length. An analytic approximation for the dispersion relation has been used to determine the Gibbs elasticity of a surfactant monolayer from the data for decay length vs. frequency. The elasticity of an octanol monolayer has been determined with precision of ±1 mN/m, in excellent agreement with the theoretical value. Surface tension can be measured from the wavelength data with precision of ±0.3 mN/m. It has been demonstrated that the effect of the surface elasticity on the wavelength is significant and accurate wavelength data can actually be used to determine the elasticity if the surface tension is known.

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“…( 21)-( 22) to the dispersion equation. Rajan [42] extended this work to another important casea flat film of a fluid between two other fluids.…”

Section: Flat Waves On a Surface Covered With A Surfactantmentioning

confidence: 96%

“…Particularly important are the waves on a cylindrical jet, in view of their role in inkjet printing [23]. Waves on droplets are another important example that has many applications [19,20,21]; confinement brings about new effects also in waves in liquid films [27,30,42].…”

Section: Wave Taxonomymentioning

confidence: 99%

Characterization of capillary waves: A review and a new optical method

2021

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“…This dynamicism leads to a complicated stress-strain relationship, lending the layer its Non-Newtonian descriptor. The water-soluble and water-insoluble surfactants which accumulate in the SSML often lead to high variations and deviation from standard oceanic elasticity (Lombardini et al, 1989), an effect that is strongly associated with surface wave suppression (Liu & Duncan, 2006;Rajan, 2020). Given observations of the damping ratio y(k), we may infer the value of the elasticity of the surface sea water (Alpers & Hühnerfuss, 1989;Lombardini et al, 1989;Cini et al, 1987).…”

Section: Inference Of Surface Rheologymentioning

confidence: 99%

“…These Surface-Active Substances (SAS), often referred to as surfactants, are organic compounds which accumulate at the air-side molecular layer above the air-water interface, a direct consequence of the orientation and water-repellent effect of the hydrophobic groups of surfactants accumulated in the SSML (van Oss et al, 2005). The presence of these compounds is strongly associated with the suppression of water waves (Lucassen-Reynders & Lucassen, 1970) and occurs through a number of mechanisms: (1) the reduction of the air-water surface tension (Ceniceros, 2003), the restoring force for capillary waves; (2) the enhancement of seawater's elastic modulus (Liu & Duncan, 2006;Rajan, 2020), increasing viscous damping; (3) the generation of longitudinal Marangoni waves (Hühnerfuss et al, 1983;Alpers & Hühnerfuss, 1989;Liu et al, 2007), which come into resonance with (and therefore attenuate) transverse surface gravity waves. Centimeter to meter-length ocean waves carry the majority of wave-supported stress; their suppression significantly reduces wind input into the wave field (wave form stress) (Hühnerfuss et al, 1983;Gade, Alpers, Hühnerfuss, Wismann, & Lange, 1998) and the dissipation of waves due to breaking Liu & Duncan, 2003).…”

Section: Introductionmentioning

confidence: 99%

The Suppression of Ocean Waves by Biogenic Slicks

Laxague,

Zappa,

Soumya

et al. 2024

Preprint

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Surface waves are significantly damped by biogenic surfactants which accumulate at the ocean's surface from the high latitudes to the tropics. The growth, development, and breaking of short wind-driven surface waves is a key mediator of the air-sea exchange of momentum, heat, and trace gases; consequently, the effect of surfactant compounds in the uppermost millimeters of the ocean in damping short surface waves bears on earth's climatic processes. The mechanisms through which surfactants suppress waves have been studied in great detail through careful laboratory experimentation in quasi one-dimensional wave tanks. However, the spatial scales over which this damping occurs in structurally complex surfactant slicks on the real ocean have not been resolved. Here we present the results of field observations of the spatial response of decimeter to millimeter-scale waves to biogenic surfactant slicks. We found that wave damping in organic material-rich coastal waters resulted in a net (spatio-temporally averaged) reduction of ~50% in momentum input to the wave field relative to the open ocean for low to moderate wind speeds. This significant effect had thus far evaded quantification due in large part to the enormous range of scales required for its description-- spanning the sea surface microlayer to the ocean submesoscale. These results are of critical importance to describing the energy exchange between ocean and atmosphere and in forecasting the coupled earth system.

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“…Comprehending the dissipation and dynamics of internal waves occurring at the boundary between viscous fluids holds significant importance. Surfactant, pollutant, and fluid film impacts at interfaces are now hot subjects [17][18][19][20][21][22][23][24][25][26][27][28][29][30][31][32][33][34][35]. Current research on surface waves remains ongoing, with a predominant emphasis on multi-layer models [18], damping rate [2,5,7,[17][18][19][20]36,37], and experimental verifications [17,20].…”

Section: Introductionmentioning

confidence: 99%

Bifurcation Analysis and Propagation Conditions of Free-Surface Waves in Incompressible Viscous Fluids of Finite Depth

Ghahraman

Bene

2023

Fluids

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Viscous linear surface waves are studied at arbitrary wavelength, layer thickness, viscosity, and surface tension. We find that in shallow enough fluids no surface waves can propagate. This layer thickness is determined for some fluids, water, glycerin, and mercury. Even in any thicker fluid layers, propagation of very short and very long waves is forbidden. When wave propagation is possible, only a single propagating mode exists for a given horizontal wave number. In contrast, there are two types of non-propagating modes. One kind of them exists at all wavelength and material parameters, and there are infinitely many such modes for a given wave number, distinguished by their decay rates. The other kind of non-propagating mode that is less attenuated may appear in zero, one, or two specimens. We notice the presence of two length scales as material parameters, one related to viscosity and the other to surface tension. We consider possible modes for a given material on the parameter plane layer thickness versus wave number and discuss bifurcations among different mode types. Motion of surface particles and time evolution of surface elevation is also studied at various parameters in glycerin, and a great variety of behaviour is found, including counterclockwise surface particle motion and negative group velocity in wave propagation.

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A three-fluid model for the dissipation of interfacial capillary-gravity waves

Cited by 23 publications

References 35 publications

Characterization of capillary waves: A review and a new optical method

Characterization of capillary waves: A review and a new optical method

The Suppression of Ocean Waves by Biogenic Slicks

Bifurcation Analysis and Propagation Conditions of Free-Surface Waves in Incompressible Viscous Fluids of Finite Depth

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