This looping video shows an umbrella cloud generated by the underwater eruption of the Hunga Tonga-Hunga Ha’apai volcano on Jan. 15, 2022. The GOES-17 satellite captured the series of images that also show crescent-shaped shock waves and lightning strikes. Credits: NASA Earth Observatory image by Joshua Stevens using GOES imagery courtesy of NOAA and NESDIS
The huge amount of water vapor hurled into the atmosphere, as detected by
NASA’s Microwave Limb Sounder, could end up temporarily warming Earth’s
surface.
When the Hunga Tonga-Hunga Ha’apai volcano erupted on Jan. 15, it sent a tsunami racing around the world and set off a
sonic boom that circled the globe twice. The underwater eruption in the South
Pacific Ocean also blasted an enormous plume of water vapor into Earth’s
stratosphere – enough to fill more than 58,000 Olympic-size swimming pools. The
sheer amount of water vapor could be enough to temporarily affect Earth’s
global average temperature.
“We’ve never seen anything like it,” said Luis Millán, an atmospheric
scientist at NASA’s Jet Propulsion Laboratory in Southern California. He led a
new study examining the amount of water vapor that the Tonga volcano injected
into the stratosphere, the layer of the atmosphere between about 8 and 33 miles
(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 (1 teragram equals a
trillion grams) of water vapor into Earth’s stratosphere – equal to 10% of the
water already present in that atmospheric layer. That’s nearly four times the
amount of water vapor that scientists estimate the 1991 Mount Pinatubo
eruption in the Philippines lofted into the stratosphere.
This satellite image shows an intact Hunga Tonga-Hunga Ha’apai in April
2015, years before an explosive underwater volcanic eruption obliterated most
of the Polynesian island in January 2022. Credits: NASA Earth Observatory
image by Jesse Allen, using Landsat data from the U.S. Geological Survey
Millán analyzed data from the Microwave Limb Sounder (MLS) instrument on NASA’s Aura satellite, 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 in the plume to
make sure they were trustworthy,” said Millán.
A Lasting Impression
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 – sent appreciable amounts of water vapor to such high
altitudes. But those were mere blips compared to the Tonga event, and the water
vapor from both previous eruptions dissipated quickly. The excess water vapor
injected by the Tonga volcano, on the other hand, could remain in the
stratosphere for several years.
This extra water vapor could influence atmospheric chemistry, boosting
certain chemical reactions that could temporarily worsen depletion of the ozone
layer. It could also influence surface temperatures. Massive volcanic eruptions
like Krakatoa and Mount Pinatubo typically cool Earth’s surface by ejecting
gases, dust, and ash that reflect sunlight back into space. In contrast, the
Tonga volcano didn’t inject large amounts of aerosols into the stratosphere,
and the huge amounts of water vapor from the eruption may have a small,
temporary warming effect, since water vapor traps heat. The effect would
dissipate when the extra water vapor cycles out of the stratosphere and would
not be enough to noticeably exacerbate climate change effects.
An image from Jan. 16, 2022, shows the ash plume from the Hunga Tonga-Hunga Ha’apai volcanic eruption that occurred the day before. An astronaut took a photograph of the plume from the International Space Station. Credits: NASA
The sheer amount of water injected into the stratosphere was likely only
possible because the underwater volcano’s caldera – a basin-shaped depression
usually formed after magma erupts or drains from a shallow chamber beneath the
volcano – was at just the right depth in the ocean: about 490 feet (150 meters)
down. Any shallower, and there wouldn’t have been enough seawater superheated
by the erupting magma to account for the stratospheric water vapor values
Millán and his colleagues saw. Any deeper, and the immense pressures in the ocean’s
depths could have muted the eruption.
The MLS instrument was well situated to detect this water vapor plume
because it observes natural microwave signals emitted from Earth’s atmosphere.
Measuring these signals enables MLS to “see” through obstacles like ash clouds
that can blind other instruments measuring water vapor in the stratosphere.
“MLS was the only instrument with dense enough coverage to capture the water
vapor plume as it happened, and the only one that wasn’t affected by the ash
that the volcano released,” said Millán.
The MLS instrument was designed and built by JPL, which is managed for NASA
by Caltech in Pasadena. NASA’s Goddard Space Flight Center manages the Aura
mission.
Source: Tonga
Eruption Blasted Unprecedented Amount of Water Into Stratosphere | NASA
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