The Antarctic ozone hole reached its maximum area for the year on October 7, 2021, and ranks as the 13th largest since 1979. Scientists from NASA and NOAA reported that 2021’s ozone hole developed similarly to 2020’s: A colder than usual Southern Hemisphere winter led to a deep and larger-than-average ozone hole that will likely persist into November or December. Credit: NASA Earth Observatory
Ozone in the atmosphere found to have weakened one of Earth’s main cooling mechanisms.
According to new research, ozone may be weakening one of the planet’s most important cooling mechanisms, making it a more significant greenhouse gas than previously thought.
Changes in ozone levels in the upper and lower atmosphere were found to be responsible for nearly a third of the warming seen in ocean waters bordering Antarctica in the second half of the twentieth century, according to a new study.
The Southern Ocean’s deep and rapid warming has an impact on its role as one of the primary regions for absorbing excess heat as the planet warms.
The majority of this warming was the result of ozone increases in the lower atmosphere. Ozone – one of the main components of smog – is already hazardous as a pollutant, but the research shows it may also play a significant role in driving climate change in the coming years.
Dr. Michaela Hegglin, an Associate Professor in atmospheric chemistry and one of the study’s authors, said: “Ozone close to Earth’s surface is harmful to people and the environment, but this study reveals it also has a big impact on the ocean’s ability to absorb excess heat from the atmosphere.
“These findings are an eye-opener and hammer home the importance of regulating air pollution to prevent increased ozone levels and global temperatures rising further still.”
Published in Nature Climate Change, the new research by an international team of scientists was led by the University of California, Riverside.
The team used models to simulate changes in ozone levels in the upper and lower atmosphere between 1955 and 2000, to isolate them from other influences and increase the currently poor understanding of their impact on the Southern Ocean heat uptake.
These simulations showed that a decrease in ozone in the upper atmosphere and increase in the lower atmosphere both contributed to warming seen in the upper 2km of the ocean waters in the high latitudes by overall greenhouse gas increases.
They revealed that the increased ozone in the lower atmosphere caused 60% of the overall ozone-induced warming seen in the Southern Ocean over the period studied – far more than previously thought. This was surprising because tropospheric ozone increases are mainly thought of as a climate forcing in the Northern hemisphere since that is where the main pollution occurs.
Ozone hit the headlines in the 1980s when a hole was discovered in the ozone layer high in the atmosphere over the South Pole, due to damage caused by chlorofluorocarbons (CFCs), a gas used in industry and consumer products.
The ozone layer is vital as it filters dangerous ultraviolet radiation from reaching Earth’s surface. This discovery led to the Montreal Protocol, an international agreement to halt the production of CFCs.
Dr. Hegglin said: “We have known for a while that ozone depletion high in the atmosphere has affected surface climate in the Southern Hemisphere. Our research has shown that ozone increases in the lower atmosphere due to air pollution, which occurs primarily in the Northern Hemisphere and ‘leaks’ into the Southern Hemisphere, is a serious problem as well.
“There is hope to find solutions, and the success of the Montreal Protocol at cutting CFC use shows that international action is possible to prevent damage to the planet.”
Ozone is created in the upper atmosphere by interaction between oxygen molecules and UV radiation from the sun. In the lower atmosphere, it forms due to chemical reactions between pollutants like vehicle exhaust fumes and other emissions.
Changes in ozone concentrations in the atmosphere affect westerly winds in the Southern Hemisphere as well as causing contrasting levels of salt and temperature close to the surface in the Southern Ocean. Both affect ocean currents in distinct ways, thereby affecting ocean heat uptake.
Reference: “Stratospheric ozone depletion and tropospheric ozone increases drive Southern Ocean interior warming” by Wei Liu, Michaela I. Hegglin, Ramiro Checa-Garcia, Shouwei Li, Nathan P. Gillett, Kewei Lyu, Xuebin Zhang and Neil C. Swart, 31 March 2022, Nature Climate Change.
DOI: 10.1038/s41558-022-01320-w
Funding: Centre for Southern Hemisphere Oceans Research, Qingdao National Laboratory for Marine Science and Technology, Commonwealth Scientific and Industrial Research Organisation, Alfred P. Sloan Foundation, US National Science Foundation