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Ocean surface warming could accelerate climate change

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Ocean surface warming could accelerate climate change

Oceans help limit global warming by absorbing carbon dioxide emissions. But intense warming in the future could diminish this capacity, leading to even more severe warming..

By The University of Texas at Austin

The discovery comes from a study led by The University of Texas at Austin in which researchers analyzed a climate simulation configured to a worst-case emissions scenario and found that the oceans’ ability to soak up carbon dioxide (CO2) would peak by 2100, becoming only half as efficient at absorbing the greenhouse gas by 2300.

The decline happens because of the emergence of a surface layer of low-alkalinity water that hinders the ability of the oceans to absorb CO2. Alkalinity is a chemical property that affects how much CO2 can dissolve in seawater.

Although the emissions scenario used in the study is unlikely because of global efforts to limit greenhouse gas emissions, the findings reveal a previously unknown tipping point that if activated would release an important brake on global warming, the authors said.

“We need to think about these worst-case scenarios to understand how our CO2 emissions might affect the oceans not just this century, but next century and the following century,” said Megumi Chikamoto, who led the research as a research fellow at the University of Texas Institute for Geophysics.

The study was published in the journal Geophysical Research Letters.

Today, the oceans soak up about a third of the CO2 emissions generated by humans. Climate simulations had previously shown that the oceans slow their absorption of CO2 over time, but none had considered alkalinity as explanation. To reach their conclusion, the researchers recalculated pieces of a 450-year simulation until they hit on alkalinity as a key cause of the slowing.

According to the findings, the effect begins with extreme climate change, which supercharges rainfall and slows ocean currents. This leaves the surface of the oceans covered in a warm layer of fresh water that won’t mix easily with the cooler, more alkaline waters below it. As this surface layer becomes more saturated with CO2, its alkalinity falls and with it, its ability to absorb CO2.

The end result is a surface layer that acts like a barrier for CO2 absorption. That means less of the greenhouse gas goes into the ocean and more of it is left behind in the atmosphere. This in turn produces faster warming, which sustains and strengthens the low-alkalinity surface layer.

Co-author, Pedro DiNezio, an affiliate researcher at the University of Texas Institute for Geophysics and associate professor at University of Colorado, said that the discovery was a powerful reminder that the world needs to reduce its CO2 emissions to avoid crossing this and other tipping points.

“Whether it’s this or the collapse of the ice sheets, there’s potentially a series of connected crises lurking in our future that we need to avoid at all costs,” he said. The next step, he said, is to figure out whether the alkalinity mechanism is triggered under more moderate emissions scenarios.

Co-author Nikki Lovenduski, a professor at the University of Colorado who contributed to the Intergovernmental Panel on Climate Change 2021 climate report, said that the study’s findings would help scientists make better projections about future climate change.

“This paper demonstrates that the climate change problem may be exacerbated by things that are as yet unknown,” she said. “But the ocean climate feedback mechanism this particular study revealed will open up new avenues of research that will help us better understand the carbon cycle, past climate change and perhaps come up with solutions for future problems.”

Acceleration and slowdown of oceanic CO2 uptake
Acceleration and slowdown of oceanic CO2 uptake. (a) Prescribed increase in atmospheric CO2 concentrations (ppm), (b, c) Globally and regionally integrated sea-air CO2 flux (PgC yr−1), and (d) peak slowdown trend, that is, a slowdown in uptake in sea-air CO2 flux (PgC decade−1) in the North Atlantic (40°–70°N), the tropical Pacific (30°S–30°N), and the Southern Ocean (>30°S). Atmospheric CO2 concentration is prescribed from historical observations, the RCP8.5 emission scenario, and its extension through 2300 (Lindsay et al., 2014; Meinshausen et al., 2011). Negative CO2 flux corresponds to oceanic uptake. Gray and light pink lines in (b) derive from interpolated observations and ocean biogeochemical model hindcast simulations (Friedlingstein et al., 2020). The dash lines in panel c show the timing of the peak slowdown trend, defined by the highest trend of the sea-air CO2 flux for 40 consecutive years since 2000 (Figure S1 in Supporting Information S1). The bar in panel d shows the peak slowdown trend, which is the average of the sea-air CO2 flux trend over the 40 years when the trend peaks (colored shading in panel c). Numbers on the x-axis in (d) are peak slowdown years (dashed colored lines in (c)).

 

Referência:

Megumi O. Chikamoto et al, Long‐Term Slowdown of Ocean Carbon Uptake by Alkalinity Dynamics, Geophysical Research Letters (2023). DOI: 10.1029/2022GL101954

 

 

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in EcoDebate, ISSN 2446-9394

 

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