On Sound Scattering and Acoustic Properties of the Upper Layer of the Sea with Bubble Clouds

Bulanov, V. A.; Bugaeva, L. K.; Storozhenko, A. V.

doi:10.3390/jmse10070872

Cited by 5 publications

(4 citation statements)

References 22 publications

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“…Previously conducted studies of the distribution of bubbles in typical real liquids (including seawater) allowed this article to use the model function of bubble size distribution (28) to calculate the effective compressibility β e (11) and, on this basis, to obtain estimates for the absorption coefficient α and the speed of sound c e , Equations ( 21) and ( 22), which were valid for sufficiently high concentrations of bubbles. The article did not have the opportunity to discuss the limits of applicability of the approximations made, but the authors, when conducting the analysis, understood the need to take into account the effects of multiple scattering and the overlap of sound scattering cross-sections at high concentrations of bubbles; therefore, all the calculations were carried out in areas where these effects should not be significant.…”

Section: Discussion Of the Resultsmentioning

confidence: 99%

“…It is also important that the exponent n ∼ 3.3 and the critical dimensions R m and R P are natural parameters that follow from the Garrett-Lee-Farmer theory (GLF) [27]. The measurements of g(R) on a large factual material under similar conditions of moderate sea conditions give values n in the interval n ≈ 3.3 ÷ 3.8 [9][10][11][12][13]18,[26][27][28][29], which is close enough to the estimate n ∼ 3.3 obtained for the inertial interval between the sizes R m and R P , which follow from the theory of GLF [27].…”

Section: Effective Parameters Of a Micro-inhomogeneous Liquidmentioning

confidence: 99%

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Cavitation Strength, Acoustic Nonlinearity, and Gas Bubble Distribution in Water

Bulanov,

Sosedko,

Bulanov

et al. 2023

Fluids

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The acoustic properties of real liquids are largely related to the phase inclusions contained in them, of which gas bubbles are the most common. The aim of the work was to find the relationship between the nonlinear acoustic parameter and the cavitation strength of the liquid with the distribution of bubbles in the liquid, which has so far been poorly studied. The theoretical studies of the parameter of acoustic nonlinearity and the cavitation strength of a liquid with bubbles were carried out within the framework of the homogeneous approximation of a micro-homogeneous liquid; the relationship of these parameters with the bubble distribution function was established, and the typical values of these parameters for different concentrations of bubbles were calculated. Experimental measurements of the parameter of acoustic nonlinearity and the cavitation strength in the upper layer of seawater were carried out; these measurements were consistent with the theoretical estimates. A connection was established between the thresholds of acoustic and optical cavitation—the optical breakdown of a liquid by laser radiation. The results obtained can find practical application in the measurement of the cavitation strength of seawater at great depths in the sea, and the use of an optoacoustic method associated with the use of optical cavitation is proposed.

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Section: Discussion Of the Resultsmentioning

confidence: 99%

Section: Effective Parameters Of a Micro-inhomogeneous Liquidmentioning

confidence: 99%

Cavitation Strength, Acoustic Nonlinearity, and Gas Bubble Distribution in Water

Bulanov,

Sosedko,

Bulanov

et al. 2023

Fluids

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“…[50,51] The diameter of bubbles generated by breaking waves is even smaller, typically less than 600 µm, [35] and the average volume concentration is around 10 −5 or less. [34,36] The sizes of these seawater bubbles are much smaller than required by existing bubble energy harvesters, and the bubbles themselves are dispersed across a vast underwater environment in extremely low concentrations. Therefore, the capture as well as converging of microbubbles dispersed in water is a necessary prerequisite for bubble energy harvesting, which is of great significance for ocean in situ energy exploitation and underwater scientific exploration.…”

Section: Introductionmentioning

confidence: 99%

“…At the surface of the ocean, wave breaking enables large amounts of air to pass into the water. [34][35][36] In the photic zone of the upper and middle layers of the ocean, submersed plants such as algae produce 50% of the oxygen on earth through photosynthesis. [37] At the bottom of the ocean, up to 48 Tg of methane is released annually into seawater from subsea sediments.…”

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confidence: 99%

Super‐Aerophilic Biomimetic Cactus for Underwater Dispersed Microbubble Capture, Self‐Transport, Coalescence, and Energy Harvesting

Wen

et al. 2023

Small

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Human ocean activities are inseparable from the supply of energy. The energy contained in the gas‐phase components dispersed in seawater is a potential universal energy source for eupelagic or deep‐sea equipment. However, the low energy density of bubbles dispersed in water introduces severe challenges to the potential energy harvesting of gas‐phase components. Here, a super‐aerophilic biomimetic cactus is developed for underwater dispersive microbubble capture and energy harvesting. The bubbles captured by the super‐aerophilic biomimetic cactus spines, driven by the surface tension and liquid pressure, undergo automatic transport, coalescence, accumulation, and concentrated release. The formerly unavailable low‐density dispersive surface free energy of the bubbles is converted into high‐density concentrated gas buoyancy potential energy, thereby providing an energy source for underwater in situ electricity generation. Experiments show a continuous process of microbubble capture by the biomimetic cactus and demonstrate a 22.76‐times increase in output power and a 3.56‐times enhancement in electrical energy production compared with a conventional bubble energy harvesting device. The output energy density is 3.64 times that of the existing bubble energy generator. This work provides a novel approach for dispersive gas‐phase potential energy harvesting in seawater, opening up promising prospects for wide‐area in situ energy supply in underwater environments.

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The Problem of Complete Damping of a Diffraction Sound Field for a Cylindrical Shell

Kosarev

2024

J. Mach. Manuf. Reliab.

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On Sound Scattering and Acoustic Properties of the Upper Layer of the Sea with Bubble Clouds

Cited by 5 publications

References 22 publications

Cavitation Strength, Acoustic Nonlinearity, and Gas Bubble Distribution in Water

Cavitation Strength, Acoustic Nonlinearity, and Gas Bubble Distribution in Water

Super‐Aerophilic Biomimetic Cactus for Underwater Dispersed Microbubble Capture, Self‐Transport, Coalescence, and Energy Harvesting

The Problem of Complete Damping of a Diffraction Sound Field for a Cylindrical Shell

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