Abstract
Air-sea turbulent fluxes determine the exchange of momentum, heat, freshwater, and gas between the atmosphere and ocean. These exchange processes are critical to a broad range of research questions spanning length scales from meters to thousands of kilometers and time scales from hours to decades. Examples are discussed (section 2). The estimation of surface turbulent fluxes from satellite is challenging and fraught with considerable errors (section 3); however, recent developments in retrievals (section 3) will greatly reduce these errors. Goals for the future observing system are summarized in section 4. Surface fluxes are defined as the rate per unit area at which something (e.g., momentum, energy, moisture, or CO Z ) is transferred across the air/sea interface. Wind- and buoyancy-driven surface fluxes are called surface turbulent fluxes because the mixing and transport are due to turbulence. Examples of nonturbulent processes are radiative fluxes (e.g., solar radiation) and precipitation (Schmitt et al., 2010). Turbulent fluxes are strongly dependent on wind speed; therefore, observations of wind speed are critical for the calculation of all turbulent surface fluxes. Wind stress, the vertical transport of horizontal momentum, also depends on wind direction. Stress is very important for many ocean processes, including upper ocean currents (Dohan and Maximenko, 2010) and deep ocean currents (Lee et al., 2010). On short time scales, this horizontal transport is usually small compared to surface fluxes. For long-term processes, transport can be very important but again is usually small compared to surface fluxes.
Highlights
Wind- and buoyancy-driven surface fluxes are called surface turbulent fluxes because the mixing and transport are due to eddy motions rather than mean flow
Turbulent fluxes are strongly dependent on wind speed; observations of wind speed are critical for the calculation of all turbulent surface fluxes
A review of the US satellite program (NRC, 2007) gave NOAA a mandate to fly a new generation of wind instrument, the eXtended Ocean Vector Wind Mission (XOVWM), which combines the advantages of scatterometry (Ku-band and C-band), passive polarimetry, and synthetic aperture radar
Summary
Recent improvements in the measurement of vector winds, air temperatures, and atmospheric humidities have all contributed to better estimation of surface fluxes from satellite observations. These advances are discussed in the context of applications, with examples from a tropical cyclone and a very strong mid-latitude storm. Passive instruments measure electromagnetic energy radiated from the water surface at several wavelengths The radiances at these frequencies are typically linearly combined with the goals of accounting for attenuation and emission in the atmosphere, thereby improving the estimate of the surface value (Goodberlet et al, 1989). Variable Stress (Nm-2) Sensible + Latent (W m-2) Vector Wind Wind Speed (m s-2) SST (K) Air Temperature (K) Humidity (g kg-1)
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