Diversity decoupled from ecosystem function and resilience during mass extinction recovery
Diversity decoupled from ecosystem function and resilience during mass extinction recovery
The Chicxulub bolide impact 66 million years ago drove the near-instantaneous collapse of ocean ecosystems. The devastating loss of diversity at the base of ocean food webs probably triggered cascading extinctions across all trophic levels1,2,3 and caused severe disruption of the biogeochemical functions of the ocean, and especially disrupted the cycling of carbon between the surface and deep sea4,5. The absence of sufficiently detailed biotic data that span the post-extinction interval has limited our understanding of how ecosystem resilience and biochemical function was restored; estimates6,7,8 of ecosystem ‘recovery’ vary from less than 100 years to 10 million years. Here, using a 13-million-year-long nannoplankton time series, we show that post-extinction communities exhibited 1.8 million years of exceptional volatility before a more stable equilibrium-state community emerged that displayed hallmarks of resilience. The transition to this new equilibrium-state community with a broader spectrum of cell sizes coincides with indicators of carbon-cycle restoration and a fully functioning biological pump9. These findings suggest a fundamental link between ecosystem recovery and biogeochemical cycling over timescales that are longer than those suggested by proxies of export production7,8, but far shorter than the return of taxonomic richness6. The fact that species richness remained low as both community stability and biological pump efficiency re-emerged suggests that ecological functions rather than the number of species are more important to community resilience and biochemical functions.
242-245
Alvarez, Sarah
aa56905c-9eb3-43c9-847d-943dae98e710
Gibbs, Samantha
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Bown, Paul
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Kim, Hojung
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Sheward, Rosie
881179be-1c42-4837-a7e8-daeeb6fdae63
Ridgwell, Andy
769cea5c-e033-456a-8b53-51dfa307dc35
10 October 2019
Alvarez, Sarah
aa56905c-9eb3-43c9-847d-943dae98e710
Gibbs, Samantha
82dfbcbc-3a8a-40da-8a80-fe7ad83f3110
Bown, Paul
c207fdf4-33dc-449b-b0b1-653903900f66
Kim, Hojung
0b5b4119-c440-489d-b589-2ff96a7aa25c
Sheward, Rosie
881179be-1c42-4837-a7e8-daeeb6fdae63
Ridgwell, Andy
769cea5c-e033-456a-8b53-51dfa307dc35
Alvarez, Sarah, Gibbs, Samantha, Bown, Paul, Kim, Hojung, Sheward, Rosie and Ridgwell, Andy
(2019)
Diversity decoupled from ecosystem function and resilience during mass extinction recovery.
Nature, 574 (7777), .
(doi:10.1038/s41586-019-1590-8).
Abstract
The Chicxulub bolide impact 66 million years ago drove the near-instantaneous collapse of ocean ecosystems. The devastating loss of diversity at the base of ocean food webs probably triggered cascading extinctions across all trophic levels1,2,3 and caused severe disruption of the biogeochemical functions of the ocean, and especially disrupted the cycling of carbon between the surface and deep sea4,5. The absence of sufficiently detailed biotic data that span the post-extinction interval has limited our understanding of how ecosystem resilience and biochemical function was restored; estimates6,7,8 of ecosystem ‘recovery’ vary from less than 100 years to 10 million years. Here, using a 13-million-year-long nannoplankton time series, we show that post-extinction communities exhibited 1.8 million years of exceptional volatility before a more stable equilibrium-state community emerged that displayed hallmarks of resilience. The transition to this new equilibrium-state community with a broader spectrum of cell sizes coincides with indicators of carbon-cycle restoration and a fully functioning biological pump9. These findings suggest a fundamental link between ecosystem recovery and biogeochemical cycling over timescales that are longer than those suggested by proxies of export production7,8, but far shorter than the return of taxonomic richness6. The fact that species richness remained low as both community stability and biological pump efficiency re-emerged suggests that ecological functions rather than the number of species are more important to community resilience and biochemical functions.
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reboot_accepted
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More information
Accepted/In Press date: 27 August 2019
e-pub ahead of print date: 25 September 2019
Published date: 10 October 2019
Identifiers
Local EPrints ID: 434760
URI: http://eprints.soton.ac.uk/id/eprint/434760
ISSN: 0028-0836
PURE UUID: 2c6e2f85-5872-45db-abaa-ee03c4ee4c18
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Date deposited: 08 Oct 2019 16:30
Last modified: 16 Mar 2024 08:13
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Contributors
Author:
Sarah Alvarez
Author:
Samantha Gibbs
Author:
Paul Bown
Author:
Hojung Kim
Author:
Rosie Sheward
Author:
Andy Ridgwell
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