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For thousands of kilometers along the western coasts of the Americas, low-oxygen waters known as oxygen minimum zones stretch out into the Pacific. In part due to climate change, this oxygen-starved region is likely to get wider and deeper, expanding by millions of cubic kilometers by the end of the century, models in a new study predict. Larger oxygen minimum zones threaten marine ecosystems and species, along with the industries that depend on them.
Oxygen minimum zones are located 200 to 2000 meters (656 to 6560 feet) beneath the surface, in the “shadow regions” of the tropical ocean, and are driven by factors such as water temperature, nutrient supply and ocean circulation patterns. Predicting how they will respond to climate change has proven difficult and the Pacific oxygen minimum zone, which is the largest in the world, is no exception. Part of the difficulty in predicting changes arises from disagreements on how to define “low” oxygen levels, which the new study explores.
The study was published in the journal AGU Advances, which publishes high-impact, open-access research and commentary across the Earth and space sciences. It used the latest suite of climate models, CMIP6, to improve upon previous predictions for how oxygen minimum zones would change. Those predictions often reported conflicting fates of the Pacific’s oxygen minimum zone.
Oxygen minimum zones comprise an outer layer and an inner core of ultra oxygen-depleted water. If high greenhouse gas emissions continue, the study predicted the tropical Pacific oxygen minimum zone will grow 6 to 8 million cubic kilometers (1.4 to 1.9 million cubic miles) by 2100, expanding about 4%. That volume equates to about 0.6% of the volume of the world’s oceans, or about 3 times the volume of the Greenland ice sheet.
As the Pacific zone grows, its outer layer will stretch over greater areas and depths, but its inner core could shrink, the study found.
The growth of the oxygen minimum zone outer layer is due to weakened ocean circulation, which slows oxygen replenishment, according to the models. Over much of its area, the oxygen minimum zone will likely expand toward the surface by 5 to 50 meters (16 to 160 feet).
There’s a small upside to this: The core in oxygen minimum zones produce nitrous oxide, an important greenhouse gas, so a shrinking core in the tropical Pacific oxygen minimum zone may limit how much gas is released into the atmosphere.
“I think not having that core region balloon out is probably good news,” said Julius Busecke, lead study author and a physical oceanographer at Columbia University. Having a smaller core also poses a smaller threat to fish and other organisms that need oxygen to survive.
Beyond the core, the expansion of the Pacific oxygen minimum zone’s outer layer will compress the habitat for commercially important marine species, such as anchovies, tuna and crabs. “As the levels of oxygen go down, these species won’t be able to feed, swim and reproduce unless they relocate to ocean regions with enough oxygen for them to breathe properly,” said Laure Resplandy, a co-author of the study and biogeochemical oceanographer at Princeton University.
Expanding oxygen minimum zones may lead to more overfishing because low-oxygen zones will likely expand upward toward the ocean’s surface, compacting oxygen-rich regions where fish can live, said Busecke. This could negatively affect the economically important fishery industry of the region.
Expert Reaction
These comments have been collated by the Science Media Centre to provide a variety of expert perspectives on this issue. Feel free to use these quotes in your stories. Views expressed are the personal opinions of the experts named. They do not represent the views of the SMC or any other organisation unless specifically stated.
Dr Denise Fernandez, Physical Oceanographer, NIWA
Around half the oxygen available to sustain primary production on Earth comes from the ocean. This means that we rely on this ocean oxygen to keep us all breathing, and for ecosystems and related socio-economic activities to continue to work. While humans are not at risk of running out of oxygen to breathe, the plants and animals that live in the oceans are.
This modelling study predicts that areas in the Pacific Ocean with low oxygen concentrations will expand in size as a consequence of human-induced climate change. The study also shows that at the same time the minimum oxygen region will contract. This is because the ocean will become more stratified from intensified surface warming – something that will also change how ocean biology works.
These coming changes are difficult to predict with certainty and studies like this are important. What they demonstrate is that a major priority is to improve the real data we can collect from the changing ocean. I’m involved with a global initiative that is deploying ocean robots designed to measure these biophysical changes as they occur. If the models match these changing conditions, it gives us some confidence that their projections are sensible. Regardless, it is clear the ocean is changing and that the impacts will be global.
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