Air/Sea Transfer of Highly Soluble Gases Over Coastal Waters

The deposition of soluble trace gases to the sea surface is not well studied due to a lack of flux measurements over the ocean. Here we report simultaneous air/sea eddy covariance flux measurements of water vapor, sulfur dioxide (SO2), and momentum from a coastal North Atlantic pier. Gas transfer ve...

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Bibliographic Details
Main Authors: Porter, J. G., de Bruyn, Warren J., Miller, S. D., Saltzman, E. S.
Format: Text
Language:unknown
Published: Chapman University Digital Commons 2020
Subjects:
air/sea gas exchange
sulfur cycle
gas deposition
air/sea exchange
sulfur dioxide
Atmospheric Sciences
Environmental Chemistry
Oceanography
Other Oceanography and Atmospheric Sciences and Meteorology
North Atlantic
Online Access:https://digitalcommons.chapman.edu/sees_articles/257
https://digitalcommons.chapman.edu/cgi/viewcontent.cgi?article=1257&context=sees_articles
Description
Summary:The deposition of soluble trace gases to the sea surface is not well studied due to a lack of flux measurements over the ocean. Here we report simultaneous air/sea eddy covariance flux measurements of water vapor, sulfur dioxide (SO2), and momentum from a coastal North Atlantic pier. Gas transfer velocities were on average about 20% lower for SO2 than for H2O. This difference is attributed to the difference in molecular diffusivity between the two molecules (D SO 2/D H 2O = 0.5), in reasonable agreement with bulk parameterizations in air/sea gas models. This study demonstrates that it is possible to observe the effect of molecular diffusivity on airā€side resistance to gas transfer. The slope of observed relationship between gas transfer velocity and friction velocity is slightly smaller than predicted by gas transfer models, possibly due to wind/wave interactions that are unaccounted for in current models.

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