The ocean floor as we know it is dissolving rapidly as a result of human activity.
Normally, the deep-sea bottom is a chalky white. It’s composed, to a large extent, of the mineral calcite, formed from the skeletons and shells of many planktonic organisms and corals. The seafloor plays a crucial role in controlling the degree of ocean acidification.
The dissolution of calcite neutralizes the acidity of carbon dioxide and in the process prevents seawater from becoming too acidic. But these days—at least in certain hotspots such as the Northern Atlantic and the southern oceans—the ocean’s chalky bed is becoming more of a murky brown. As a result of human activities, the level of carbon dioxide in the water is so high, and the water is so acidic, that the calcite is simply being dissolved.
A research team led by McGill University—and including a University of Michigan physical oceanographer and his former postdoctoral fellow—report their findings this week in Proceedings of the National Academy of Sciences. The researchers said they believe that what they are seeing today is only a foretaste of the way that the ocean floor will most likely be affected in future.
“Because it takes decades or even centuries for CO2 to drop down to the bottom of the ocean, almost all the CO2 created through human activity is still at the surface. But in the future, it will invade the deep ocean, spread above the ocean floor and cause even more calcite particles at the seafloor to dissolve,” said lead author Olivier Sulpis, who is working on his doctorate at McGill’s Department of Earth and Planetary Sciences.
“The rate at which CO2 is currently being emitted into the atmosphere is exceptionally high in Earth’s history, faster than at any period since at least the extinction of the dinosaurs. And at a much faster rate than the natural mechanisms in the ocean can deal with, so it raises worries about the levels of ocean acidification in the future.”
In future work, the researchers plan to look at how this deep ocean-bed dissolution is likely to evolve over the coming centuries, under various potential future CO2 emission scenarios. They believe that it is critical for scientists and policymakers to develop accurate estimates of how marine ecosystems will be affected, over the long term, by acidification caused by humans.
Because it is difficult and expensive to obtain measurements in the deep sea, the researchers created a set of seafloor-like microenvironments in the laboratory, reproducing abyssal bottom currents, seawater temperature and chemistry as well as sediment compositions.
These experiments helped them to understand what controls the dissolution of calcite in marine sediments and allowed them to quantify precisely its dissolution rate as a function of various environmental variables. By comparing pre-industrial and modern seafloor dissolution rates, they were able to extract the anthropogenic fraction of the total dissolution rates.
The speed estimates for ocean-bottom currents came from a high-resolution ocean model developed in the laboratory of U-M physical oceanographer Brian Arbic by former postdoctoral fellow David Trossman, who is now a research associate at the University of Texas.
“When David and I developed these simulations, applications to the dissolution of geological material at the bottom of the oceans were far from our minds. It’s a wonderful surprise that our simulations were useful for Olivier’s study, which just goes to show you that scientific research can sometimes take unexpected detours and pay unexpected dividends,” said Arbic, an associate professor in the U-M Department of Earth and Environmental Sciences.
Trossman added: “Just as climate change isn’t just about polar bears, ocean acidification isn’t just about coral reefs. Our study shows that the effects of human activities have become evident all the way down to the seafloor in many regions, and the resulting increased acidification in these regions may impact our ability to understand Earth’s climate history.”
“This study shows that human activities are dissolving the geological record at the bottom of the ocean,” Arbic said. “This is important because the geological record provides evidence for natural and anthropogenic changes.”
Source: University of Michigan
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