Project description
Understanding deep-sea calcium carbonate dissolution mechanisms
Reducing CO2 emissions is essential in addressing the climate change crisis. Marine sediments, which cover two thirds of the Earth’s surface, contain calcium carbonate (CaCO3) that dissolves due to ocean acidification driven by increasing CO2 levels. This process plays a role in neutralising CO2, but the mechanisms and rates at which it occurs remain poorly understood. The ERC-funded Deep-C project aims to investigate deep-sea CaCO3 dissolution using high-pressure reactors that simulate the conditions of the deep ocean. Using sensors and imaging techniques, it will provide data on the biogeochemical processes involved. Overall, the project will refine global biogeochemical models and enhance our comprehension of the ocean’s role in carbon sequestration, thereby supporting efforts to mitigate climate change.
Objective
As humanity grapples with the escalating crisis of climate change, understanding and mitigating the sources of carbon dioxide (CO2) emissions is imperative. A lesser-known yet significant aspect of this crisis lies in the vast expanses of marine sediments which encompass two-thirds of the Earths surface. A key component of these sediments is calcium carbonate (CaCO3), a family of minerals that makes up the shells and skeletons of marine organisms. CO2 emissions lead to ocean acidification, triggering CaCO3 dissolution, which in turn neutralizes CO2, acting as a crucial CO2 sink over millennial timescales. However, the mechanisms and rate of this dissolution remain unknown due to the challenges posed by the deep oceans high pressures and the elusive bacterial communities mediating the dissolution process. Proposed here is an ambitious five-year research initiative aimed at understanding deep-sea CaCO3 dissolution, thereby paving the way towards a more thorough understanding and potential mitigation of climate change impacts. By focusing on the abyssal and hadal realms, this groundbreaking research seeks to unveil the nature and rate of CaCO3 dissolution through high pressure reactors. These reactors, which mimic the pressure and temperature of deep-sea environments, present a robust alternative to in-field studies. With the integration of cutting-edge sensors and the use of advanced CaCO3 imaging techniques, we anticipate generating precise and continuous data on the unfolding biogeochemical processes. By housing bacterial cultures within the reactors, alongside natural CaCO3 grains, this project will delve into the mechanisms driving dissolution. The insights will be instrumental in refining a global biogeochemical model, thereby promoting a deeper comprehension of the oceans role in carbon sequestration and propelling forward the global efforts towards effective climate change mitigation.
Fields of science (EuroSciVoc)
CORDIS classifies projects with EuroSciVoc, a multilingual taxonomy of fields of science, through a semi-automatic process based on NLP techniques. See: https://op.europa.eu/en/web/eu-vocabularies/euroscivoc.
CORDIS classifies projects with EuroSciVoc, a multilingual taxonomy of fields of science, through a semi-automatic process based on NLP techniques. See: https://op.europa.eu/en/web/eu-vocabularies/euroscivoc.
- natural scienceschemical sciencesinorganic chemistryinorganic compounds
- natural scienceschemical sciencesinorganic chemistryalkaline earth metals
You need to log in or register to use this function
Keywords
Programme(s)
- HORIZON.1.1 - European Research Council (ERC) Main Programme
Topic(s)
Funding Scheme
HORIZON-ERC - HORIZON ERC GrantsHost institution
75794 Paris
France