The water to the sky of the volcano of Tonga would warm the Earth

The water to the sky of the volcano of Tonga would warm the Earth

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The huge amount of water vapor spewed into the atmosphere by Tonga’s explosive eruption in January could be enough to temporarily warm the Earth’s surface.

When the Hunga Tonga-Hunga Ha’apai volcano erupted on January 15, it sent a tsunami that raced across the globe and caused a sonic boom that circled the globe twice. The underwater eruption in the South Pacific Ocean also spewed a huge plume of water vapor into Earth’s stratosphere, enough to fill more than 58,000 Olympic swimming pools.

“We’ve never seen anything like it,” Luis Millán, an atmospheric scientist at NASA’s Jet Propulsion Laboratory in Southern California, said in a statement. He led a new study examining the amount of water vapor the Tonga volcano injected into the stratosphere, the layer of the atmosphere between about 12 and 53 kilometers above Earth’s surface.

In the study, published in Geophysical Research Letters, Millán and his colleagues estimate that the Tonga eruption sent around 146 teragrams of water vapor into Earth’s stratosphere, equivalent to 10% of the water already present in that layer of the atmosphere. . That’s nearly four times the amount of water vapor that scientists estimate the 1991 Mount Pinatubo eruption in the Philippines spewed into the stratosphere.

Off-chart water vapor readings

Millán analyzed data from NASA’s Aura satellite’s Microwave Limb Sounder (MLS) instrument, which measures atmospheric gases, including water vapor and ozone. After the Tonga volcano erupted, the MLS team started seeing water vapor readings that were off the charts. “We had to carefully inspect all the measurements on the plume to make sure they were reliable,” Millán said.

Volcanic eruptions rarely inject much water into the stratosphere. In the 18 years that NASA has been taking measurements, only two other eruptions, the 2008 Kasatochi event in Alaska and the 2015 Calbuco eruption in Chile, have sent appreciable amounts of water vapor to such high altitudes. But those were mere flashes compared to the Tonga event, and water vapor from the previous two eruptions quickly dissipated. Excess water vapor injected by the Tonga volcano, on the other hand, could remain in the stratosphere for several years.

This additional water vapor could influence atmospheric chemistry, driving certain chemical reactions that could temporarily worsen ozone layer depletion. It could also influence surface temperatures.

Satellite image of the Hunga Tonga volcano island before and after January 15 / Image: Copernicus

water vapor traps heat

Massive volcanic eruptions like Krakatoa and Mount Pinatubo typically cool the Earth’s surface by expelling gases, dust, and ash that reflect sunlight back into space. In contrast, the Tonga volcano did not inject large amounts of aerosols into the stratosphere, and the huge amounts of water vapor from the eruption may have little temporary warming effect, since the water vapor traps heat. The effect would dissipate as the additional water vapor leaves the stratosphere and would not be enough to markedly exacerbate the effects of climate change.

The large amount of water injected into the stratosphere was probably only possible because the submarine volcano’s caldera, a basin-like depression that usually forms after magma erupts or drains from a shallow chamber beneath the volcano, it was at the correct depth in the ocean: about 150 meters down.

Shallower, and there wouldn’t be enough seawater superheated by the erupting magma to account for the stratospheric water vapor values ​​that Millán and his colleagues saw. Deeper, and the immense pressures in the deep ocean could have silenced the eruption.

The MLS instrument was well placed to detect this plume of water vapor because it sees natural microwave signals emitted from Earth’s atmosphere. Measuring these signals allows MLS to “see” through obstacles like ash clouds that can blind other instruments that measure water vapor in the stratosphere.

“MLS was the only instrument with coverage dense enough to capture the water vapor plume at the time it happened, and the only one that was not affected by the ash released by the volcano,” Millán said.

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