Beyond compiling the current state of knowledge, the authors contribute new analyses from the MARHYS hydrothermal vent database and model the solubility of iron minerals to illustrate how environmental parameters and plume chemistry affect iron transport. These findings emphasize how hydrothermal plumes act as long-distance supply systems for bioavailable iron—a process with far-reaching consequences for ocean productivity and the global carbon cycle.

The publication, published in the journal communications earth & environment, is the result of a collaboration among twelve scientists from major German marine research institutions, including GEOMAR, AWI, and the ICBM in Oldenburg. The study was led by Solveig I. Bühring from MARUM—Center for Marine Environmental Sciences at the University of Bremen—together with her MARUM colleagues Alexander Diehl and Charlotte Kleint, as well as Andrea Koschinsky from Constructor University Bremen, who is also affiliated with the Cluster of Excellence “The Ocean Floor—Earth’s Uncharted Interface” based at MARUM. “Our results show how closely physical, chemical, and biological processes at the seafloor are intertwined—exactly what lies at the heart of the Cluster of Excellence. Studies like this help us understand how the ocean floor functions as an active link within the Earth system,” explained Dr. Charlotte Kleint.

By combining geochemical, microbiological, and modeling perspectives, the team provides an integrated view of how hydrothermal systems are connected to global nutrient cycles—and how substances are dispersed along the invisible pathways of hydrothermal plumes, stimulating ocean productivity even in distant regions.