The micropaleoecology framework: evaluating biotic responses to global change through paleoproxy, microfossil, and ecological data integration
The micropaleoecology framework: evaluating biotic responses to global change through paleoproxy, microfossil, and ecological data integration
The microfossil record contains abundant, diverse, and well-preserved fossils spanning multiple trophic levels from primary producers to apex predators. In addition, microfossils often constitute and are preserved in high abundances alongside continuous high-resolution geochemical proxy records. These characteristics mean that microfossils can provide valuable context for understanding the modern climate and biodiversity crises by allowing for the interrogation of spatiotemporal scales well beyond what is available in neo-ecological research. Here, we formalize a research framework of “micropaleoecology,” which builds on a holistic understanding of global change from the environment to ecosystem level. Location: Global. Time period: Neoproterozoic-Phanerozoic. Taxa studied: Fossilizing organisms/molecules. Our framework seeks to integrate geochemical proxy records with microfossil records and metrics, and draws on mechanistic models and systems-level statistical analyses to integrate disparate records. Using multiple proxies and mechanistic mathematical frameworks extends analysis beyond traditional correlation-based studies of paleoecological associations and builds a greater understanding of past ecosystem dynamics. The goal of micropaleoecology is to investigate how environmental changes impact the component and emergent properties of ecosystems through the integration of multi-trophic level body fossil records (primarily using microfossils, and incorporating additional macrofossil data where possible) with contemporaneous environmental (biogeochemical, geochemical, and sedimentological) records. Micropaleoecology, with its focus on integrating ecological metrics within the context of paleontological records, facilitates a deeper understanding of the response of ecosystems across time and space to better prepare for a future Earth under threat from anthropogenic climate change.
Woodhouse, Adam
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Swain, Anshuman
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Smith, Jansen A.
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Sibert, Elizabeth C.
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Lam, Adriane R.
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Dunne, Jennifer A.
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Auderset, Alexandra
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31 October 2024
Woodhouse, Adam
a0025c27-6460-473e-aa96-34dba6520a73
Swain, Anshuman
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Smith, Jansen A.
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Sibert, Elizabeth C.
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Lam, Adriane R.
ec61a518-9dd1-4047-9958-dba5bb25cb56
Dunne, Jennifer A.
932f0514-8075-4d35-85fd-20dd07532378
Auderset, Alexandra
a6054a25-7c59-49fe-a2cd-62c1d3f3c8b3
Woodhouse, Adam, Swain, Anshuman, Smith, Jansen A., Sibert, Elizabeth C., Lam, Adriane R., Dunne, Jennifer A. and Auderset, Alexandra
(2024)
The micropaleoecology framework: evaluating biotic responses to global change through paleoproxy, microfossil, and ecological data integration.
Ecology and Evolution, 14 (11), [e70470].
(doi:10.1002/ece3.70470).
Abstract
The microfossil record contains abundant, diverse, and well-preserved fossils spanning multiple trophic levels from primary producers to apex predators. In addition, microfossils often constitute and are preserved in high abundances alongside continuous high-resolution geochemical proxy records. These characteristics mean that microfossils can provide valuable context for understanding the modern climate and biodiversity crises by allowing for the interrogation of spatiotemporal scales well beyond what is available in neo-ecological research. Here, we formalize a research framework of “micropaleoecology,” which builds on a holistic understanding of global change from the environment to ecosystem level. Location: Global. Time period: Neoproterozoic-Phanerozoic. Taxa studied: Fossilizing organisms/molecules. Our framework seeks to integrate geochemical proxy records with microfossil records and metrics, and draws on mechanistic models and systems-level statistical analyses to integrate disparate records. Using multiple proxies and mechanistic mathematical frameworks extends analysis beyond traditional correlation-based studies of paleoecological associations and builds a greater understanding of past ecosystem dynamics. The goal of micropaleoecology is to investigate how environmental changes impact the component and emergent properties of ecosystems through the integration of multi-trophic level body fossil records (primarily using microfossils, and incorporating additional macrofossil data where possible) with contemporaneous environmental (biogeochemical, geochemical, and sedimentological) records. Micropaleoecology, with its focus on integrating ecological metrics within the context of paleontological records, facilitates a deeper understanding of the response of ecosystems across time and space to better prepare for a future Earth under threat from anthropogenic climate change.
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Ecology and Evolution - 2024 - Woodhouse - The Micropaleoecology Framework Evaluating Biotic Responses to Global Change
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Accepted/In Press date: 3 October 2024
Published date: 31 October 2024
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Local EPrints ID: 500851
URI: http://eprints.soton.ac.uk/id/eprint/500851
ISSN: 2045-7758
PURE UUID: bf9969f6-45e8-47df-9b7a-dcc642a2cde3
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Date deposited: 14 May 2025 16:32
Last modified: 22 Aug 2025 02:38
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Contributors
Author:
Adam Woodhouse
Author:
Anshuman Swain
Author:
Jansen A. Smith
Author:
Elizabeth C. Sibert
Author:
Adriane R. Lam
Author:
Jennifer A. Dunne
Author:
Alexandra Auderset
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