In the darkness of the deep ocean, where sunlight can’t reach, scientists have stumbled upon a strange phenomenon — the production of oxygen where none should exist. An international team says the unexpected discovery of what they’re calling “dark oxygen” challenges our understanding of deep-sea ecosystems and could have far-reaching implications for ocean chemistry and climate science.
The team, led by Andrew K. Sweetman from The Scottish Association for Marine Science, conducted experiments nearly four kilometers (roughly 2.5 miles) beneath the surface of the Pacific Ocean. Their study area, known as the Clarion-Clipperton Zone (CCZ), is a vast expanse of seafloor covered in potato-sized lumps called polymetallic nodules. These nodules, rich in valuable metals like manganese, nickel, and copper, have attracted interest from mining companies eager to exploit their potential.
It’s not the promise of mineral wealth that has scientists excited, however, it’s what’s happening around these nodules that’s truly groundbreaking.
Typically, in the deep sea, oxygen is consumed as organisms breathe and decompose organic matter. Scientists can measure this oxygen consumption to understand the health and activity of deep-sea ecosystems. However, when Sweetman and his team placed experimental chambers on the seafloor to measure oxygen levels, they observed something entirely unexpected: oxygen levels were increasing, not decreasing.
Over the course of two days, oxygen concentrations in some chambers more than tripled. This “dark oxygen production,” as the researchers termed it in the journal Nature Geoscience, occurred without any sunlight – the driving force behind oxygen production through photosynthesis in surface waters and on land.
“For aerobic life to begin on the planet, there had to be oxygen, and our understanding has been that Earth’s oxygen supply began with photosynthetic organisms,” says Sweetman, who leads the Seafloor Ecology and Biogeochemistry research group at SAMS, in a media release. “But we now know that there is oxygen produced in the deep sea, where there is no light. I think we, therefore, need to revisit questions like: Where could aerobic life have begun?”
The discovery raises intriguing questions about the source of this mysterious oxygen. After ruling out experimental errors and known biological processes, the team began to suspect the nodules themselves might be involved.
Further investigation revealed that the nodules possess an electrical potential, acting somewhat like natural batteries. The researchers measured voltage differences of up to 0.95 volts between different points on nodule surfaces – approaching the 1.23 volts theoretically required to split water molecules into hydrogen and oxygen.