Wade R. McGillis scite author profile

Abstract. Using recent laboratory and field results we explore the possibility of a cubic relationship between gas exchange and instantaneous (or short-term) wind speed, and its impact on global air-sea fluxes. The theoretical foundation for such a dependency is based on retardation of gas transfer at low to intermediate winds by surfactants, which are ubiquitous in the world's oceans, and bubble-enhanced transfer at higher winds. The proposed cubic relationship shows a weaker dependence of gas transfer at low wind speed and a significantly stronger dependence at high wind speed than previous relationships. A long-term relationship derived from such a dependence, combined with the monthly CO2 climatology of Takahashi

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Advances in Quantifying Air-Sea Gas Exchange and Environmental Forcing

Wanninkhof

Asher

et al. 2009

Annu. Rev. Mar. Sci.

625

636

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The past decade has seen a substantial amount of research on air-sea gas exchange and its environmental controls. These studies have significantly advanced the understanding of processes that control gas transfer, led to higher quality field measurements, and improved estimates of the flux of climate-relevant gases between the ocean and atmosphere. This review discusses the fundamental principles of air-sea gas transfer and recent developments in gas transfer theory, parameterizations, and measurement techniques in the context of the exchange of carbon dioxide. However, much of this discussion is applicable to any sparingly soluble, non-reactive gas. We show how the use of global variables of environmental forcing that have recently become available and gas exchange relationships that incorporate the main forcing factors will lead to improved estimates of global and regional air-sea gas fluxes based on better fundamental physical, chemical, and biological foundations.

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Environmental turbulent mixing controls on air‐water gas exchange in marine and aquatic systems

Zappa

McGillis

Raymond

et al. 2007

Geophysical Research Letters

297

343

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[1] Air-water gas transfer influences CO 2 and other climatically important trace gas fluxes on regional and global scales, yet the magnitude of the transfer is not well known. Widely used models of gas exchange rates are based on empirical relationships linked to wind speed, even though physical processes other than wind are known to play important roles. Here the first field investigations are described supporting a new mechanistic model based on surface water turbulence that predicts gas exchange for a range of aquatic and marine processes. Findings indicate that the gas transfer rate varies linearly with the turbulent dissipation rate to the 1 = 4 power in a range of systems with different types of forcing -in the coastal ocean, in a macro-tidal river estuary, in a large tidal freshwater river, and in a model (i.e., artificial) ocean. These results have important implications for understanding carbon cycling.

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Wade R. McGillis

A cubic relationship between air‐sea CO₂ exchange and wind speed

Advances in Quantifying Air-Sea Gas Exchange and Environmental Forcing

Environmental turbulent mixing controls on air‐water gas exchange in marine and aquatic systems

Contact Info

Product

Resources

About

Wade R. McGillis

A cubic relationship between air‐sea CO2 exchange and wind speed

Advances in Quantifying Air-Sea Gas Exchange and Environmental Forcing

Environmental turbulent mixing controls on air‐water gas exchange in marine and aquatic systems

Contact Info

Product

Resources

About

A cubic relationship between air‐sea CO₂ exchange and wind speed