Scientists sent underwater robots into the depths of the Pacific, about 1.5 miles (2.5 kilometers) beneath the surface, and discovered something unexpected: a football field-size expanse of towering hydrothermal vents that cropped up in an area these underwater chimneys haven’t typically been seen.
The hydrothermal vents, shaped like candelabras, stand roughly 35 to 40 feet (10 to 12 meters) tall, or about as tall as three-story buildings, the research team leaders, from Lehigh University, said in a statement (opens in new tab). These striking structures gush black, mineral-filled water that reaches temperatures (opens in new tab) of up to 694 degrees Fahrenheit (368 degrees Celsius), although the water likely starts out at an even higher temperature, closer to 818 F (437 C), the team determined. Such high temperatures hint that a volcanic eruption may occur at the site in the next few years.
The newfound vent field is located about 200 miles (321 km) off the coast of western Mexico, in the East Pacific Rise, a range of underwater volcanoes (opens in new tab) that extends nearly from the Gulf of California to Antarctica.
“We were astounded that not only was the field very active, but it is larger in area and hotter in origin temperature than any other hydrothermal vent field known along this portion of the East Pacific Rise that has been studied for the past 30 years,” Daniel Fornari, a marine geologist at the Woods Hole Oceanographic Institution in Massachusetts and a co-author of the paper, said in the statement.
Related: Wonderland of iridescent worms and hydrothermal vents found off Mexican coast (opens in new tab)
As a midocean ridge, the East Pacific Rise marks a region where tectonic plates (opens in new tab) in Earth’s crust are spreading apart and molten rock is rushing in to fill the gap, according to the Monterey Bay Aquarium Research Institute (opens in new tab). The magma’s movement triggers volcanic eruptions and creates cracks in the crust, allowing water to trickle down into the fractures, get superheated by the hot rock below and then shoot back up through the seafloor, forming hydrothermal vents.
Most hydrothermal vents discovered on the East Pacific Rise have been found along the “axis” of the ridge — the plate boundary where the spreading occurs — where magmatic activity has formed a 54- to 109-yard-wide (50 to 100 meters) trough. By comparison, the newfound vent field was discovered about 820 yards (750 m) east and 4.3 miles (7 km) north of these previously known vents.
“Although 750 m may not seem like a great distance from the axis, known vents are so tightly localized in the [axial summit trough] that this discovery stands out as something very different,” William Seyfried, leader of the Aqueous Geochemistry Lab at the University of Minnesota, and Jeffrey Karson, leader of the Oceanic Lithosphere Tectonics Group at Syracuse University, wrote in a commentary (opens in new tab) about the research.
These so-called off-axis vents likely derive their heat from a different source than the vents found on the axis, said Seyfried and Karson, who were not involved in the new study. The discovery hints that there are more hydrothermal vents in the deep sea than once thought and that these off-axis vents could serve as a “presently underappreciated source of heat and chemicals that might be significant on a global scale,” they wrote.
“There is much still left to be discovered about deep-sea vents along the global mid-ocean ridge, both in terms of where they are located as well as their geological, geochemical and biological characteristics,” lead author Jill McDermott, chemical oceanographer and faculty member in Lehigh University’s Department of Earth and Environmental Sciences, said in the statement. “I hope our study will motivate future research efforts to target mapping off-axis areas along the global mid-ocean ridge crest to better quantify the extent of off-axis versus on-axis hydrothermal venting.”
McDermott and her colleagues published their findings July 21 in the journal Proceedings of the National Academy of Sciences (opens in new tab).
Originally published on Live Science.