A dual-beam dual-camera method for a battery-powered underwater miniature PIV (UWMPIV) system

Wang, Binbin; Qian, Lei; Bootsma, Harvey A.; Wang, Peifang

doi:10.1007/s00348-012-1265-9

Cited by 12 publications

(11 citation statements)

References 34 publications

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“…To quantify the filtration impact of giant larvaceans in situ, we developed DeepPIV, an instrument that allows for the measurement of fine-scale fluid motions that is similar in concept to previous technologies deployed in rivers and shallow ocean depths ( 31 , 38 – 40 ). Unlike earlier versions of this technology, DeepPIV can be deployed from ROVs that are capable of diving to depths where giant larvaceans and other midwater organisms are found ( 22 , 23 ).…”

Section: Methodsmentioning

confidence: 99%

New technology reveals the role of giant larvaceans in oceanic carbon cycling

et al. 2017

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Section: Methodsmentioning

confidence: 99%

New technology reveals the role of giant larvaceans in oceanic carbon cycling

et al. 2017

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“…[] and Wang et al . []. The design and construction of the present FPIV system and preliminary experimental results have been reported in Wang et al .…”

Section: Experimental Setup and Measurement Approachmentioning

confidence: 99%

Field observations of turbulent dissipation rate profiles immediately below the air‐water interface

Wang

Qian

2016

JGR Oceans

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Near surface profiles of turbulence immediately below the air-water interface were measured with a free-floating Particle Image Velocimetry (PIV) system on Lake Michigan. The surface-following configuration allowed the system to measure the statistics of the aqueous-side turbulence in the topmost layer immediately below the water surface (z % 0 $ 15 cm, z points downward with 0 at the interface). Profiles of turbulent dissipation rate (e) were investigated under a variety of wind and wave conditions. Various methods were applied to estimate the dissipation rate. Results suggest that these methods yield consistent dissipation rate profiles with reasonable scattering. In general, the dissipation rate decreases from the water surface following a power law relation in the top layer, e $ z 20:7 , i.e., the slope of the decrease was lower than that predicted by the wall turbulence theory, and the dissipation was considerably higher in the top layer for cases with higher wave ages. The measured dissipation rate profiles collapse when they were normalized with the wave speed, wave height, water-side friction velocity, and the wave age. This scaling suggests that the enhanced turbulence may be attributed to the additional source of turbulent kinetic energy (TKE) at the ''skin layer'' (likely due to micro-breaking), and its downward transport in the water column. Key Points:Profiles of turbulent dissipation rates were measured immediately below the air-water interface Near surface dissipation rate profiles can be described by a power law relation Near surface dissipation rates scale with wave speed, wave height, wave age, and friction velocityCorrespondence to: Q. Liao, liao@uwm.edu Citation:Wang, B., and Q. Liao (2016), Field observations of turbulent dissipation rate profiles immediately below the air-water interface,

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“…A fundamental component of the UWMPIV system design is the laser ''beam sweep'' (Kawahashi andHosoi 1989, 1991;Gray et al 1991), which provides adequate particle illumination while avoiding particle image ''motion blur'' (Liao et al 2009;Wang et al 2012). Longer sweeping time can increase the brightness of particle images but at the cost of a longer time lag (Dt) between two consecutive particle exposures.…”

Section: Piv Data Processingmentioning

confidence: 99%

A Free-Floating PIV System: Measurements of Small-Scale Turbulence under the Wind Wave Surface

Wang

Qian

Xiao

et al. 2013

Journal of Atmospheric and Oceanic Technology

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An in situ free-floating underwater miniature particle image velocimetry (UWMPIV) system is developed and applied to measure the structure of turbulence in the aqueous side of the wind wave surface boundary layer. The UWMPIV system provides a direct way to measure the aqueous side turbulence dissipation rate and vortex structures immediately below the air-water interface, which are important parameters that determine the gas exchange rate across the air-water interface subjected to a low-tomoderate wind shear. The impact of platform motion on the measurement of small-scale turbulence is discussed and found to be insignificant. A series of field experiments under a near ''zero-fetch'' wind wave condition and one open water experiment under a low wind condition were conducted on Lake Michigan to demonstrate the capabilities of the free-floating particle image velocimetry (PIV) system. The dissipation rate estimated with a ''direct method'' and with a ''spectra fitting'' method are compared. Vertical profiles of the turbulence dissipation rate suggest a power-law dependency with depth below the water surface. Surface shear velocities estimated through the aqueous side Reynolds stress distribution agreed well with wind stresses estimated by the classic drag law for zero-fetch wind wave conditions, where the primary source of turbulence was wind shear. For the open water experiment under a very low wind condition, a high dissipation rate was observed near the water surface, suggesting a high turbulence production rate by surface waves, and the profile of dissipation rate showed a slower decay rate with depth in the presence of waves.

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A dual-beam dual-camera method for a battery-powered underwater miniature PIV (UWMPIV) system

Cited by 12 publications

References 34 publications

New technology reveals the role of giant larvaceans in oceanic carbon cycling

New technology reveals the role of giant larvaceans in oceanic carbon cycling

Field observations of turbulent dissipation rate profiles immediately below the air‐water interface

A Free-Floating PIV System: Measurements of Small-Scale Turbulence under the Wind Wave Surface

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