Modeling vertical carbon flux from zooplankton respiration

The transport of carbon from ocean surface waters to the deep sea is a critical factor in calculations of planetary carbon cycling and climate change. This vertical carbon flux is currently thought to support the respiration of all the organisms in the water column below the surface, the respiration of the organisms in the benthos, as well as the carbon lost to deep burial. Accordingly, for conditions where the benthic respiration and the carbon burial are small relative to the respiration in the water column, and where horizontal fluxes are known or negligible, the carbon flux can be calculated by integrating the vertical profile of the water-column plankton respiration rate. Here, this has been done for the zooplankton component of the vertical carbon flux from measurements of zooplankton ETS activity south of the Canary Island Archipelago. From zooplankton ETS activity depth profiles, zooplankton respiration depth profiles were calculated and using the equations for the profiles as models, the epipelagic (3.05 mu mol CO2 m(-3) h(-1)), mesopelagic (112.82 nmol CO2 m(-3) h(-1)), and bathypelagic (27.89 nmol CO2 m(-3) h(-1)) zooplankton respiration for these waters were calculated. Then, by integration of the depth-normalized respiration profiles, zooplankton-associated carbon flux profiles below 150 m were calculated. These had an uncertainty of +/- 40%. At the station level (local regional variation) the variability was +/- 114% (n = 16). At 150 m and 500 m the average passive carbon flux associated with the zooplankton was 36 (+/- 114%) and 20 (+/- 113%) mu mol C m(-2) h(-1). The carbon transfer efficiency (T-eff) from the 150 to the 500 m levels averaged 51 +/- 21% and a new metric, the nutrient retention efficiency (NRE), averaged 49 +/- 21%. This metric is an index of the efficiency with which nutrients are maintained in the epipelagic zone and is directly related to the respiration in the water column. The carbon flux equation describing the pooled data (n = 16) was 131.14Z(-0.292). Using this as a model for zooplankton-associated carbon flux south of the Canary Islands one can calculate that carbon flux from epipelagic waters at 200 m is 27.91 mu mol C m(-2) h(-1), and the carbon flux from mesopelagic waters at 1000 m, is 17.45 mu mol C m(-2) h(-1). (C) 2013 Elsevier Ltd. All rights reserved.