4.6 Article

Kelp carbon sink potential decreases with warming due to accelerating decomposition

Journal

PLOS BIOLOGY
Volume 20, Issue 8, Pages -

Publisher

PUBLIC LIBRARY SCIENCE
DOI: 10.1371/journal.pbio.3001702

Keywords

-

Funding

  1. Norwegian Blue Forest Network
  2. Australian Research Council [DE1901006192]
  3. National Science and Engineering Research Council of Canada [516938-2018]
  4. NSERC Undergraduate Student Research Awards [UXSO100]
  5. Woods Hole Sea Grant
  6. BOEM Award [M12AS0001]
  7. UKRI Future Leaders Fellowship [MR/S032827/1]
  8. Norwegian Research Council [267536]
  9. NERC Newton Fund [NE/S011692/1]
  10. Canadian NSERC Discovery Grant [RGPIN-2017-05581]
  11. Brittany Regional Council
  12. French Government through the National Research Agency [ANR-10-BTBR-04]

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The cycling of organic carbon in the ocean is influenced by environmental factors, but the controls on carbon flux in the coastal zone are still not well understood. A field experiment was conducted across different latitudes to measure the decomposition rates of kelp detritus in relation to local environmental factors. The results showed that decomposition rates were influenced by ocean temperature and initial carbon content, with higher rates of biomass loss at lower latitudes with warmer temperatures. The findings suggest that decomposition of kelp species could accelerate with ocean warming, leading to changes in carbon cycling patterns.
Cycling of organic carbon in the ocean has the potential to mitigate or exacerbate global climate change, but major questions remain about the environmental controls on organic carbon flux in the coastal zone. Here, we used a field experiment distributed across 28 degrees of latitude, and the entire range of 2 dominant kelp species in the northern hemisphere, to measure decomposition rates of kelp detritus on the seafloor in relation to local environmental factors. Detritus decomposition in both species were strongly related to ocean temperature and initial carbon content, with higher rates of biomass loss at lower latitudes with warmer temperatures. Our experiment showed slow overall decomposition and turnover of kelp detritus and modeling of coastal residence times at our study sites revealed that a significant portion of this production can remain intact long enough to reach deep marine sinks. The results suggest that decomposition of these kelp species could accelerate with ocean warming and that low-latitude kelp forests could experience the greatest increase in remineralization with a 9% to 42% reduced potential for transport to long-term ocean sinks under short-term (RCP4.5) and long-term (RCP8.5) warming scenarios. However, slow decomposition at high latitudes, where kelp abundance is predicted to expand, indicates potential for increasing kelp-carbon sinks in cooler (northern) regions. Our findings reveal an important latitudinal gradient in coastal ecosystem function that provides an improved capacity to predict the implications of ocean warming on carbon cycling. Broad-scale patterns in organic carbon decomposition revealed here can be used to identify hotspots of carbon sequestration potential and resolve relationships between carbon cycling processes and ocean climate at a global scale.

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