A laboratory study of longitudinal waves in surfactant films in a water wave tank

Liu, Xinan; Duncan, James H.; Korenowski, G. M.; Kelly, Joseph S.

doi:10.1029/2006jc003867

Cited by 6 publications

(4 citation statements)

References 24 publications

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“…This confirms previous investigations which reveal that the surface tension gradient generated by a nonuniform concentration of surfactant on a free water surface influences the propagation (e.g., amplitude and wavelength) of capillary waves. − …”

Section: Results and Discussionsupporting

confidence: 90%

Surfactant-Enhanced Spreading of Sessile Water Drops on Polypropylene Surfaces

2016

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Spreading of water drops resting in equilibrium on polypropylene surfaces was initiated by dispensing surfactant-laden droplets on their apex. Upon contact of the two drops two processes were kicked-off: surfactant from the droplets spread along the water/air interface of the sessile drops and a train of capillary waves propagated along the sessile drops. The contact line of the sessile drops remained initially pinned and started spreading only when surfactant reached it while the capillary waves did not have an apparent effect on initiating drop spreading. However, surfactant influenced the propagation velocity of the capillary waves. Though the spreading dynamics of such nonhomogeneously mixed surfactant/water drops on polypropylene surfaces was initially different from that of homogeneously mixed drops, the later spreading dynamics was similar and was dominated by viscosity and surface tension in both cases. These results can help in discriminating the path of action of surfactants in bulk and at the water/air interface, which is also relevant for understanding phenomena such as superspreading.

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Section: Results and Discussionsupporting

confidence: 90%

Surfactant-Enhanced Spreading of Sessile Water Drops on Polypropylene Surfaces

2016

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“…Observations of the damping coefficient in the coastal region for U 10N ≤ 6 m s −1 (Figure 9c) are consistent with key predictions of classic Marangoni-Gibbs wave damping theory. To wit: peak damping occurs for wavenumbers 50 rad m −1 < k < 100 rad m −1 , centimeter-to-decimeter scales for which the dispersion curves for surface transverse and longitudinal waves intersect (Liu et al, 2007). Furthermore, postpeak α D (k) falls off as k −3/4 for surface gravity waves and curves upwards with increasing wavenumber as capillarity becomes the dominant restoring force; the dotted curve on Figure 9c indicates the damping coefficient predicted from theory (Lucassen, 1982;Alpers & Hühnerfuss, 1989), with an arbitrary vertical offset.…”

Section: The Clear Differences In Ssml Chemistry Between Coastal and ...mentioning

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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“…Information about dilation properties of fluid/fluid interfaces can be also obtained from the longitudinal wave dampening. These are propagated mainly by interfacial tension gradients, allowing one to probe the dilational rheology of fluid/fluid interfaces at lower values of deformation frequencies than when capillary waves are used [50,[73][74][75].…”

Section: Wave Dampingmentioning

confidence: 99%

Dilational Rheology of Fluid/Fluid Interfaces: Foundations and Tools

Guzmán

Maestro

Carbone

et al. 2022

Fluids

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Fluid/fluid interfaces are ubiquitous in science and technology, and hence, the understanding of their properties presents a paramount importance for developing a broad range of soft interface dominated materials, but also for the elucidation of different problems with biological and medical relevance. However, the highly dynamic character of fluid/fluid interfaces makes shedding light on fundamental features guiding the performance of the interfaces very complicated. Therefore, the study of fluid/fluid interfaces cannot be limited to an equilibrium perspective, as there exists an undeniable necessity to face the study of the deformation and flow of these systems under the application of mechanical stresses, i.e., their interfacial rheology. This is a multidisciplinary challenge that has been evolving fast in recent years, and there is currently available a broad range of experimental and theoretical methodologies providing accurate information of the response of fluid/fluid interfaces under the application of mechanical stresses, mainly dilational and shear. This review focused on providing an updated perspective on the study of the response of fluid/fluid interfaces to dilational stresses; to open up new avenues that enable the exploitation of interfacial dilational rheology and to shed light on different problems in the interest of science and technology.

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A laboratory study of longitudinal waves in surfactant films in a water wave tank

Cited by 6 publications

References 24 publications

Surfactant-Enhanced Spreading of Sessile Water Drops on Polypropylene Surfaces

Surfactant-Enhanced Spreading of Sessile Water Drops on Polypropylene Surfaces

The Suppression of Ocean Waves by Biogenic Slicks

Dilational Rheology of Fluid/Fluid Interfaces: Foundations and Tools

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