The effects of breaking waves on dual-tracer gas exchange experiments

Asher, W; Wanninkhof, R

Title: The effects of breaking waves on dual-tracer gas exchange experiments

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Abstract

Quantification of air-sea gas fluxes is important in understanding the global ocean carbon cycle, determining the effect of biologically produced gases on remote marine tropospheric aerosol production, and measuring the atmospheric lifetimes of trace gases. Direct measurement of the flux, F, of a sparingly soluble gas through the air-sea interface is extremely difficult in general, and F is often calculated as F = k{sub L}{delta}C where k{sub L} is the transfer velocity of the gas and AC is its air-sea concentration difference. In the absence of bubbles, k{sub L} is a function of the near-surface aqueous-phase turbulence and the molecular diffusivity of the gas. Although direct measurement of {delta}C is relatively simple, oceanic measurements of k{sub L} are problematical. Because of this, k{sub L} is usually estimated from empirical parameterizations for k{sub L} in terms of wind speed, U. The linear relation between F and k{sub L} at a constant {delta}C implies that the accuracy of the parameterization of k{sub L} in terms of U is critical in calculating F. This is especially true when U is large, since experiments in wind tunnels, lakes, and the ocean suggest that k{sub L} increases quadratically with U (Wanninkhof, 1992). With the exactmore »« less

Authors:

Asher, W ^[1]; Wanninkhof, R ^[2]

Pacific Northwest Lab., Sequim, WA (United States)
National Oceanic and Atomospheric Administration/Atlantic Oceanographic and Meterological Lab., Miami, FL (United States)

Publication Date:: Sat Jul 01 00:00:00 EDT 1995

Research Org.:: Pacific Northwest National Lab. (PNNL), Richland, WA (United States)

Sponsoring Org.:: USDOE, Washington, DC (United States)

OSTI Identifier:: 102364

Report Number(s):: PNL-SA-25775; CONF-950743-6
ON: DE95016797; TRN: 95:006753

DOE Contract Number:: AC06-76RL01830

Resource Type:: Conference

Resource Relation:: Conference: 3. international symposium on air-water gas transfer, Heidelberg (Germany), 24-27 Jul 1995; Other Information: PBD: Jul 1995

Country of Publication:: United States

Language:: English

Subject:: 54 ENVIRONMENTAL SCIENCES; CARBON CYCLE; GLOBAL ASPECTS; WATER WAVES; TRACER TECHNIQUES; SEAS; TURBULENCE; AIR-WATER INTERACTIONS; BUBBLES; PLUMES; WIND

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                    Asher, W, and Wanninkhof, R. The effects of breaking waves on dual-tracer gas exchange experiments.  United States: N. p., 1995. 
        Web.

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                    Asher, W, & Wanninkhof, R. The effects of breaking waves on dual-tracer gas exchange experiments.  United States.

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                    Asher, W, and Wanninkhof, R. 1995.  
        "The effects of breaking waves on dual-tracer gas exchange experiments".  United States.  https://www.osti.gov/servlets/purl/102364.

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@article{osti_102364,

  title        = {The effects of breaking waves on dual-tracer gas exchange experiments},

  author       = {Asher, W and Wanninkhof, R},

  abstractNote = {Quantification of air-sea gas fluxes is important in understanding the global ocean carbon cycle, determining the effect of biologically produced gases on remote marine tropospheric aerosol production, and measuring the atmospheric lifetimes of trace gases. Direct measurement of the flux, F, of a sparingly soluble gas through the air-sea interface is extremely difficult in general, and F is often calculated as F = k{sub L}{delta}C where k{sub L} is the transfer velocity of the gas and AC is its air-sea concentration difference. In the absence of bubbles, k{sub L} is a function of the near-surface aqueous-phase turbulence and the molecular diffusivity of the gas. Although direct measurement of {delta}C is relatively simple, oceanic measurements of k{sub L} are problematical. Because of this, k{sub L} is usually estimated from empirical parameterizations for k{sub L} in terms of wind speed, U. The linear relation between F and k{sub L} at a constant {delta}C implies that the accuracy of the parameterization of k{sub L} in terms of U is critical in calculating F. This is especially true when U is large, since experiments in wind tunnels, lakes, and the ocean suggest that k{sub L} increases quadratically with U (Wanninkhof, 1992). With the exact functional form of the relation between U and k{sub L} not definitively known at present, estimation of k{sub L} at high U could be inaccurate. This problem could be resolved with further oceanic measurements of k{sub L} at high U. However, increases in U are also associated with increases in the frequency of wave breaking. Whitecaps are known to generate bubble plumes, and these bubbles could have a significant effect on the measurement of k{sub L}.},

  doi          = {},

  url          = {https://www.osti.gov/biblio/102364},
  journal      = {},
number       = ,

  volume       = ,

  place        = {United States},

  year         = {Sat Jul 01 00:00:00 EDT 1995},

  month        = {Sat Jul 01 00:00:00 EDT 1995}

}

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