Seawater Respiration, Carbon Flux, Nutrient Retention Efficiency and Heterotrophic Energy Production in the Peruvian Upwelling

Theodore T Packard1, Natalia Osma2, Igor Fernández-Urruzola2, Louis A Codispoti3, John P Christensen3 and May Gómez4, (1)University of Las Palmas de Gran Canaria, Las Palmas, Spain, (2)Marine Ecophisiology Group: EOMAR, Iu-ECOAQUA. University of Las Palmas de Gran Canaria, Las Palmas de Gran Canaria, Spain, (3)University of Maryland, UMCES, Cambridge, MD, United States, (4)University of Las Palmas de Gran Canaria, EOMAR, Marine Ecophysiology Group, ECOAQUA Institute, Las Palmas, Spain
Abstract:
Oceanic depth profiles of seawater respiration (R) and vertical carbon flux are described by similar power functions and because they are conceptually and mathematically related, they can be calculated from one another. The maximum curvature of the respiration depth profile controls carbon flux. When the curvature is sharp, the carbon flux (FC) from the epipelagic ocean is low and the nutrient retention efficiency (NRE) is high allowing these waters to maintain high productivity. When the curvature is weak, NRE is low, seawater becomes nutrient impoverished, and productivity is reduced. This means that the attenuation of respiration in ocean water columns is critical in understanding and predicting vertical FC, the capacity of epipelagic ecosystems to retain their nutrients, and primary productivity. The new metric, NRE, is the ratio of nutrient regeneration in a seawater layer to the nutrients introduced into it. In other words, NRE = R/FC. A depth profile of FC is the integral of water column R. This relationship facilitates calculating ocean sections of FC. In a FC section across the Peru upwelling system we found a carbon flux maximum extending down to 400 m, 50 km off the Peru coast. Along this same section, by coupling respiratory electron transport system activity to heterotrophic oxidative phosphorylation, we calculated an ocean section of heterotrophic energy production (HEP). In the euphotic zone, HEP ranged from 250 to 500 J d-1 m-3. Below 200m, HEP dropped to less than 5 J d-1 m-3.