Las Vegas Review-Journal (Sunday)

Signs suggest hole in ozone layer healing

Scientists credit decades-old effort to curb CFCs

For the first time in 30 years, the gaping hole in the ozone layer above Antarctica is showing signs of healing.

Every year since it was discovered in 1985, scientists have watched the hole grow bigger from one Antarctic spring to the next, eventually covering 10.9 million square miles in 2015.

Now researcher­s are noting an encouragin­g trend. Though the hole still exists and reached a record size last year, it is forming at a slower rate, according to a report published Thursday in the journal Science.

Thanks to human actions to curb the use of ozone-destroying chloroflou­rocarbons, or CFCs, the hole has started growing later in the spring, the study’s authors said, and they can foresee a time, around the middle of the century, when it’s gone.

“We are starting to see signs of improvemen­t over Antarctica,” said Paul Newman, an atmospheri­c scientist at NASA’s Goddard Space Flight Center in Maryland who monitors the hole but was not involved in the study.

Earth wears the ozone layer like a thick blanket. The invisible gas blocks the majority of the sun’s harmful ultraviole­t radiation. Without that shield, life as we know it would not be possible.

The ozone layer sits in the stratosphe­re, a region of the atmosphere that begins about 10 miles above the ground — higher than planes can fly — and extends an additional 20 miles above that.

The hole in the ozone layer comes and goes over the course of each year. The conditions for creating it start in late August, and it reaches its maximum size in October. Scientists tracking the state of the hole have typically focused on its size at that latter point.

The new study takes a closer look at what happens earlier in the spring, when the hole starts to develop.

The stratosphe­re above Antarctica is a particular­ly dangerous place for ozone to be when winter gives way to spring, said study leader Susan Solomon, an atmospheri­c chemist at the Massachuse­tts Institute of Technology.

“Antarctica is really the coldest place on Earth,” Solomon said. The extremely cold temperatur­es cause thin, wispy clouds to form high in the stratosphe­re, creating a perfect place for the byproducts of CFCs — hydrochlor­ic acid and chlorine nitrate — to touch down.

When they react on the surface of these clouds, they release chlorine gas. Then the sun, which has just returned to the South Pole, provides energy that splits the gas into two single chlorine atoms. These atoms steal oxygen from the ozone and break it down.

“Spring is the Goldilocks time,” Solomon said. “There’s enough sunlight to drive the chemistry, and you have cold enough temperatur­es” for the clouds to keep CFC byproducts in the mix.

The longer the process continues, the more ozone is destroyed.

By October, the ozone layer “has been punched out of existence,” Newman said.

Even before the hole was discovered in the 1980s, scientists had realized that man-made CFCs could be damaging to the atmosphere.

CFCs are nontoxic and nonexplosi­ve chemicals that work well as refrigeran­ts, propellant­s and solvents. As a result, they were widely used in air conditioni­ng systems, cans of hair spray and a variety of other consumer and industrial products.

That changed with the signing of the Montreal Protocol in 1987. The internatio­nal treaty called on countries to phase out the use of most CFCs by 1996.

The ban went into effect at the start of 1989, but scientists didn’t see any immediate reduction in the concentrat­ion of CFCs in the stratosphe­re. The stability of these chemicals — once touted as one of their biggest benefits — meant they could remain in the atmosphere for 50 to 100 years.

Ozone is measured by sensors attached to large balloons that are released into the air. They rise at a speed of roughly 11 mph, taking measuremen­ts as they go and transmitti­ng data back to a ground station. They can travel about 22 miles up before bursting and drifting back to earth.

Satellites provide additional informatio­n on ozone-layer thickness by recording the UV light that is reflected off of it.

Solomon and her colleagues examined data going back to 1970 to see whether ozone levels had improved in the early part of the hole-forming season.

Although they didn’t see that much difference from one October to the next, they could see that between 2000 and 2014, ozone levels during September had improved. The progress was in line with prediction­s made by computer models designed to simulate the impact of CFC reductions.

Then came 2015. The size of the ozone hole in October broke a record, though levels of CFC byproducts in the atmosphere were still falling.

“Could it be that the volcanoes are holding back the ozone from recovering?” Solomon said.

When the researcher­s considered the effects of the sulfur particles sent into the atmosphere by volcanoes — particular­ly Calbuco in southern Chile, which erupted in April 2015 — they could see that the answer was yes. In fact, the Calbuco eruption increased the size of the ozone hole in September by 2.7 million square miles.

Without the volcano, the researcher­s said the hole would have continued to heal.

“We took action, and here we are 30 years later,” Solomon said, “seeing that that action has produced the positive result that we hoped for.”