Abstract
The Barents Sea is experiencing long-term climate-driven changes, e.g. modification in oceanographic conditions and extensive sea ice loss, which can lead to large, yet unquantified disruptions to ecosystem functioning. This key region hosts a large fraction of Arctic primary productivity. However, processes governing benthic and pelagic coupling are not mechanistically understood, limiting our ability to predict the impacts of future perturbations. We combine field observations with a reaction-transport model approach to quantify organic matter (OM) processing and disentangle its drivers. Sedimentary OM reactivity patterns show no gradients relative to sea ice extent, being mostly driven by seafloor spatial heterogeneity. Burial of high reactivity, marine-derived OM is evident at sites influenced by Atlantic Water (AW), whereas low reactivity material is linked to terrestrial inputs on the central shelf. Degradation rates are mainly driven by aerobic respiration (40–75%), being greater at sites where highly reactive material is buried. Similarly, ammonium and phosphate fluxes are greater at those sites. The present-day AW-dominated shelf might represent the future scenario for the entire Barents Sea. Our results represent a baseline systematic understanding of seafloor geochemistry, allowing us to anticipate changes that could be imposed on the pan-Arctic in the future if climate-driven perturbations persist.This article is part of the theme issue ‘The changing Arctic Ocean: consequences for biological communities, biogeochemical processes and ecosystem functioning’.
Highlights
Continental shelves play a significant role in organic matter (OM) and nutrient recycling [1,2], and high productivity arctic shelves are important hotspots for benthic processing [3]
We explore OM reactivity patterns and their links with the Barents Sea oceanographic conditions
We discuss OM degradation rates and sediment-water interface (SWI) nutrient fluxes and explore how these processes are influenced by reactivity patterns
Summary
Continental shelves play a significant role in organic matter (OM) and nutrient recycling [1,2], and high productivity arctic shelves are important hotspots for benthic processing [3]. Sea ice dynamics, marked by strong seasonal and interannual variability, play an important role in shaping OM productivity patterns [9,10,11,12,13,14]. Such factors lead to an overall elevated PP in the AW-dominated southern shelf (120 g C m−2 yr−1), which is two-fold higher than PP of the northern shelf [7,8]. In recent years (e.g. 2018), ice-free conditions have been established over the entire Barents Sea shelf during summer months (Norwegian Meteorological Institute, https://cryo.met.no/archive/ice-service/icecharts/quicklooks/2018/). This is critical, as predictions anticipate ice-free summers every year for the Barents Sea by 2050 if present trends continue [12]
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