Until they were discovered in 2000, these lush and intricate ecosystems were largely unknown, and scientists have only begun to learn about their ecological importance and their role in the evolution of life in the deep. Deep-sea corals that thrive on and around seamounts host more than 1,300 different species of animals some are unique to seamounts themselves and some live only on a specific species of coral. At the same time, coral mining and fish trawling, using nets that rake up everything in their paths, have created indelible scars in the spectacularly diverse and abundant seamount ecosystems. Seamounts also attract an abundance of marine life and are productive fishing grounds more than 80 commercial species worldwide. Forged and altered by volcanic and tectonic processes that are intimately linked to the deep earth, they are also being targeted by mining companies that hope to harvest the minerals that often collect around seamounts as a result of hydrothermal activity. Unlike shallow-water corals, which rely on photosynthetic algae and sunlight to grow, deep-sea corals get energy from filtering organic material that falls from the surface.Īlthough they are often hidden beneath the ocean (often making them a navigation hazard, particularly for submarines), seamounts are nevertheless ubiquitous and fundamental geological features studying them gives us insights into the forces that have shaped the face of our planet. These factors combine to make seamounts fertile habitats for diverse communities of marine life, including sponges, crabs, sea anemones, commercially important fish, and deep-sea corals. In addition, seamounts rising into the ocean create obstacles that shape ocean currents and direct deep, nutrient-rich waters up the sloping sides of seamounts to the surface. These provide hard foundations for deep-sea life to settle on and grow. Scientists estimate there are at least 100,000 seamounts higher than 1,000 meters around the world. Seamounts are also created at hot spots, isolated areas within tectonic plates where plumes of magma rise through the crust and erupt at the seafloor, often creating chains of volcanoes and seamounts, such as the Hawaiian Islands. Near subduction zones, plates collide, forcing ocean crust down toward Earth’s hot interior, where this crustal material melts, forming magma that rises buoyantly back to the surface and erupts to create volcanoes and seamounts. At mid-ocean ridges, plates are spreading apart and magma rises to fill the gaps. Seamounts are commonly found near the boundaries of Earth’s tectonic plates and mid-plate near hotspots. In fact, the highest mountain on Earth is actually a seamount-Hawaii’s Mauna Kea, a dormant volcano that is more than 30,000 feet tall measured from its base on the seafloor 18,000 feet beneath the surface. They are generally extinct volcanoes that, while active, created piles of lava that sometimes break the ocean surface. Seamounts are underwater mountains that rise hundreds or thousands of feet from the seafloor. Other Expeditions Highlighting WHOI Research.Expedition to Stellwagen Bank National Marine Sanctuary.How do polynyas help feed emperor penguins?.Why is pressure different in the ocean?.What’s the difference between climate and weather?.How does ocean warming affect fisheries?.
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