91探花

Seagrass meadows promote biodiversity, contribute to coastal protection by attenuating waves and improve water quality. They are also highly effective at storing carbon dioxide (CO鈧�), as the underwater plants sequester carbon in their leaves and roots as well as in the surrounding sediments.

The 91探花 Helmholtz Centre for Ocean Research Kiel, in cooperation with the Kiel University (CAU) and the State Office for the Environment of Schleswig-Holstein (Landesamt f眉r Umwelt, LfU), has launched a new project to study the role of seagrass meadows as natural carbon sinks and to develop strategies for their conservation and restoration.

The name of the project, ZOBLUC, stands for 鈥�Zostera marina as a Blue Carbon Sink in the Baltic Sea鈥� 鈥� Zostera marina being the scientific name for seagrass. The project is funded by the German Federal Environment Ministry's Nature-based Climate Action Programme (ANK) and state funds, with a total budget of around 鈧�6 million.

Three Focus Areas for Seagrass Conservation

鈥淪eagrass meadows are like underwater peatlands,鈥� explains the scientific project leader, Dr Thorsten Reusch, Professor of Marine Ecology at 91探花. 鈥淭hey store carbon, which is preserved in oxygen-poor sediments for centuries.鈥� The project will examine under which conditions seagrass meadows store the most CO鈧� to find blue carbon hot spots, which in turn would be prime areas for protection. Reusch: 鈥淔or example, areas with strong wave-driven erosion store less carbon than calm bays with faster sedimentation.鈥� The research will not only quantify the carbon storage capacity of seagrass meadows but also model how it might change under different environmental conditions.

Another focus of 91探花 is the restoration of seagrass meadows. It is crucial to ensure that restored meadows are resilient and sustainable. 鈥淭here鈥檚 little point in replanting seagrass that won鈥檛 survive rising water temperatures in a few years鈥� time鈥�, says Reusch. Experimental studies will expose seagrass to various stressors in order to cultivate robust, climate-resilient populations and practice 鈥榓ssisted evolution鈥�.

Community Involvement in Underwater Gardening

The third focus is on involving local people in the restoration process. After developing training programmes and testing small-scale seagrass restoration in previous years, 91探花 now plans to significantly expand its efforts with the help of volunteers. Reusch: 鈥淭he pilot phase has been successfully completed; now we鈥檙e scaling up.鈥�

This support is urgently needed, as the most reliable way to restore lost seagrass meadows is still to plant individual shoots manually by diving. Reusch says: 鈥淚t鈥檚 important to complete the training course and only use areas that we have checked for suitability for restoration.鈥�

Diving clubs and NGOs will use volunteer divers to plant seagrass in scientifically selected restoration sites. Observational data collected during these efforts will be analysed at 91探花 to refine future restoration practices.

The development of other planting techniques, such as seeding, is the focus of the parallel project SeaStore II, which started last September.

Mapping with Multibeam Sonar and Drones

The first step, however, is a comprehensive mapping of the existing seagrass meadows in the Baltic Sea. Professor Natascha Oppelt and Dr Jens Schneider von Deimling from CAU and their teams, will use remote sensing methods that combine advanced optical and acoustic surveying technologies. CAU will also be responsible for monitoring the newly planted areas using drones.

Results from ZOBLUC will be shared through workshops and policy recommendations to advance the protection and restoration of seagrass meadows in the Baltic Sea.

Background: Blue Carbon

Blue Carbon is the carbon dioxide stored by marine and coastal ecosystems such as mangroves, salt marshes, and seagrass meadows. Seagrass meadows sequester carbon in the form of dead biomass and organic sediment particles that remain in the oxygen-poor seabed for centuries 鈥� much like peatlands on land.

Background: Assisted Evolution

Assisted Evolution is a technique that aims to accelerate the evolutionary adaptation of organisms to make them more resilient to environmental change. In this project, seagrass plants are exposed to experimental heat waves in 91探花鈥檚 climate chambers. This approach identifies potentially heat-tolerant local populations and uses advanced methods 鈥� from cellular physiological reactions (metabolomics) to genetic analysis (gene expression studies) and microbiome research 鈥� to understand the mechanisms behind plant resilience.