Summary
Contemporary Earth’s ecosystems are threatened by accelerating extinction rates, but their responses to biodiversity losses are not detectable on short time scales. However, many large-scale biodiversity crises, or ‘mass extinctions’, occurred in the past and played a fundamental role in evolution. For instance, modern-style ecosystems originated from the worst biodiversity crisis in Earth history (PTME) at the Permian-Triassic boundary (~252 million years ago). The PTME killed over 70% of vertebrate species and created opportunities for new groups to diversify. After the extinction, Triassic land vertebrate assemblages were transformed, and new species diversified in ecological roles that were unexploited in Permian ecosystems. This suggests that extinctions may change the evolutionary trajectory of ecosystems and increase ecological complexity. Nevertheless, the ecological impacts of mass extinctions on ecosystems are still poorly understood. For the first time, this project critically investigates how the ecological structure and composition of land ecosystems changed across the PTME and its connection to biodiversity recovery. We will target the fossil record of exceptionally preserved Permian-Triassic ecosystems, alongside new field data from critical, but poorly sampled time intervals. Using a suite of novel approaches modified from modern ecology, we will quantify changes in ecological diversity, richness and stability of land ecosystems and major vertebrate groups. These patterns will be used to understand what factors drive biodiversity and the evolution of ecosystems during and after times of crisis. Through a comprehensive training and knowledge exchange programme, the experienced researcher and hosts will bring together and integrate their expertise in palaeontology, biology, quantitative techniques, and macroevolution to deliver this timely, innovative, and interdisciplinary project that will address fundamental ecological questions.
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| Web resources: | https://cordis.europa.eu/project/id/101022550 |
| Start date: | 01-03-2022 |
| End date: | 28-02-2025 |
| Total budget - Public funding: | 271 732,80 Euro - 271 732,00 Euro |
Cordis data
Original description
Contemporary Earth’s ecosystems are threatened by accelerating extinction rates, but their responses to biodiversity losses are not detectable on short time scales. However, many large-scale biodiversity crises, or ‘mass extinctions’, occurred in the past and played a fundamental role in evolution. For instance, modern-style ecosystems originated from the worst biodiversity crisis in Earth history (PTME) at the Permian-Triassic boundary (~252 million years ago). The PTME killed over 70% of vertebrate species and created opportunities for new groups to diversify. After the extinction, Triassic land vertebrate assemblages were transformed, and new species diversified in ecological roles that were unexploited in Permian ecosystems. This suggests that extinctions may change the evolutionary trajectory of ecosystems and increase ecological complexity. Nevertheless, the ecological impacts of mass extinctions on ecosystems are still poorly understood. For the first time, this project critically investigates how the ecological structure and composition of land ecosystems changed across the PTME and its connection to biodiversity recovery. We will target the fossil record of exceptionally preserved Permian-Triassic ecosystems, alongside new field data from critical, but poorly sampled time intervals. Using a suite of novel approaches modified from modern ecology, we will quantify changes in ecological diversity, richness and stability of land ecosystems and major vertebrate groups. These patterns will be used to understand what factors drive biodiversity and the evolution of ecosystems during and after times of crisis. Through a comprehensive training and knowledge exchange programme, the experienced researcher and hosts will bring together and integrate their expertise in palaeontology, biology, quantitative techniques, and macroevolution to deliver this timely, innovative, and interdisciplinary project that will address fundamental ecological questions.Status
SIGNEDCall topic
MSCA-IF-2020Update Date
28-04-2024
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