Litcius/Paper detail

Linking Upwelling Dynamics and Subsurface Nutrients to Projected Productivity Changes in the California Current System

Michael G. Jacox, Steven J. Bograd, Jérôme Fiechter, Mercedes Pozo Buil, Michael A. Alexander, Dillon J. Amaya, Nathalí Cordero Quirós, Hui Ding, Ryan R. Rykaczewski

2024Geophysical Research Letters17 citationsDOIOpen Access PDF

Abstract

Abstract Given the importance of coastal upwelling systems to ocean productivity, fisheries, and biogeochemical cycles, their response to climate change is of great interest. However, there is no consensus on future productivity changes in these systems, which may be controlled by multiple drivers including wind‐driven and geostrophic transport, stratification, and source water properties. Here we use an ensemble of regional ocean projections and recently developed upwelling indices for the California Current System to disentangle these sometimes‐competing influences. Some changes are consistent among models (e.g., decreased mixed layer depth), while for others there is a lack of agreement even on the direction of future change (e.g., nitrate concentration in upwelled waters). Despite models' diverging projections of productivity changes, they agree that those changes are predominantly driven by subsurface nitrate concentrations, not by upwelling strength. Our results highlight the need for more attention to processes governing subsurface nutrient changes, not just upwelling strength.

Topics & Concepts

UpwellingCurrent (fluid)ProductivityNutrientEnvironmental scienceOceanographyGeologyPrimary productivityClimatologyEcologyEconomicsBiologyMacroeconomicsOceanographic and Atmospheric ProcessesAtmospheric and Environmental Gas DynamicsMarine and coastal ecosystems