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Vertical Advection — Diffusion Rates in the Oceanic Thermocline Determined from 14C Distributions*

Published online by Cambridge University Press:  18 July 2016

P D Quay
Affiliation:
Department of Geological Sciences, University of Washington, Seattle, Washington 98195
Minze Stuiver
Affiliation:
Departments of Geological Sciences and Zoology, Quaternary Research Center, University of Washington, Seattle, Washington 98195
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Abstract

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The characteristics of a one-dimensional vertical advection-diffusion ocean mixing model were examined using temperature, salinity, and bomb 14C measurements made during the GEOSECS program. Vertical advection (W) and eddy diffusion (K) rates for the main oceanic thermocline and CO2 gas exchange rates (E) were determined from the depth distributions of salinity and bomb produced 14C measured in the upper 1000m of the Atlantic and Pacific Oceans. In the Atlantic, the results suggest that vertical diffusion rates are lower in the equatorial region (K = 0.6cm2sec—1) than in the temperate region (K = 1.6cm2sec—1). Upwelling rates were calculated for stations located between about 30° N and 30°S and average 10m yr—1, corresponding to an upward transport of about 10 Sverdrups. Model calculations of the gas exchange rate of CO2 indicate a 2 to 3-fold decrease between temperate latitudes and the equatorial latitudes of the Atlantic. For many of the Pacific GEOSECS stations, the Δ14C depth distribution is distinctly different than in the Atlantic, and cannot be used to calculate unique values of K and W that explain both the salinity and 14C depth distributions.

Type
Oceanography
Copyright
Copyright © The American Journal of Science

Footnotes

*

The support of the National Science Foundation (GX-28166 and IDO71-04200) and Department of Energy (DE79EV10216) is gratefully acknowledged.

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