SubsidieMeestersUntangling Ediacaran Paleomagnetism to Contextualize Immense Global Change
The EPIC project aims to investigate the origins of aberrant paleomagnetic data from the Ediacaran-early Cambrian period to reconstruct its paleogeography and enhance understanding of global changes.
Projectdetails
Introduction
The Ediacaran-early Cambrian (~635-520 Ma) was an interval of immense global change with fundamental state shifts occurring in the bio-cryo- and atmosphere. Such changes included the abrupt appearance and rapid diversification of modern metazoan life (the Ediacaran fauna and Cambrian ‘explosion’), the end of protracted, global-scale glaciations (Snowball Earth), the rise of atmospheric oxygen to present-day levels, and the perturbation of carbon isotopic records to extremes otherwise unknown to Earth history.
Importance of the Changes
Given the immensity and abruptness of those changes, they are clearly essential to an understanding of the development of life, the history of climatic change, and the evolution of the oxygen and carbon cycles. Accordingly, great effort has been dedicated to acquiring detailed temporal records to investigate those changes through time, but we still lack a robust paleogeographic framework to study them in space.
Challenges in Paleomagnetic Data
This is because paleomagnetic data—which are used to determine the ancient positions of continents—exhibit aberrant behavior at this time, the meaning of which is unknown. Four alternative hypotheses have been formulated to explain them:
- Rapid rotations of the entire solid Earth (true polar wander)
- An unstable magnetic field
- Pervasive data corruption
- Ultra-fast plate motion
Each of these hypotheses has far-reaching implications: Hypotheses 1, 2 & 4 reflect dramatic non-uniformitarian processes that would defy our understanding of geodynamics, whereas hypothesis 3 poses grave challenges to the interpretation of paleomagnetic data in Precambrian time.
Vision of the EPIC Project
My vision with EPIC is to investigate and identify the origin(s) of the aberrant paleomagnetic data of this age, and to use that knowledge to directly reconstruct Ediacaran-early Cambrian paleogeography for the first time. EPIC will thus transform one of geophysics’ most outstanding enigmas into one of our greatest assets in understanding this critical time in Earth’s development.
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 1.963.575 |
| Totale projectbegroting | € 1.963.575 |
Tijdlijn
| Startdatum | 1-10-2022 |
| Einddatum | 30-9-2027 |
| Subsidiejaar | 2022 |
Partners & Locaties
Projectpartners
- UNIVERSITETET I OSLOpenvoerder
Land(en)
Vergelijkbare projecten binnen European Research Council
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|---|---|---|---|---|
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Unravelling the first Babbles of the Earth Inner Core History
UBEICH aims to refine the timeline of Earth's inner core formation using innovative paleomagnetic techniques to enhance understanding of planetary habitability and core evolution.
Deconvolving the early record of eukaryotic evolution
This project aims to uncover the ecological and evolutionary dynamics of the Neoproterozoic Era through advanced geochemical methods, revealing insights into the rise of complex life and carbon cycle changes.
Geomagnetic field excursions: revealing the extreme states of Earth's outer core
The EXCURSION project aims to model and analyze geomagnetic excursions over the Brunhes Chron using data assimilation and machine learning to enhance understanding of Earth's core dynamics and their impacts.
Core dynamics on millennial timescales
PALEOCORE aims to develop an integrated core-field core-flow model to understand Earth's core dynamics over millennial timescales and forecast future magnetic field changes.
Magmatic Triggering of Cenozoic Climate Changes
MATRICs aims to reconstruct magmatic CO2 emissions from the Neo-Tethyan arc to understand their impact on early Cenozoic climate through innovative geological and modeling techniques.