Warming temperatures increasingly alter structure of atmosphere
New research quantifies extent of rising tropopause

Date:
November 8, 2021
Source:
National Center for Atmospheric Research/University Corporation
for Atmospheric Research
Summary:
Climate change is having an increasing impact on the structure
of Earth's atmosphere, a new international study shows. The
research draws on decades of observations to quantify that warming
temperatures are playing a greater role in pushing up the top of
the lowest level of the atmosphere by about 50-60 meters per decade.



FULL STORY ========================================================================== Climate change is having an increasing impact on the structure of Earth's atmosphere, a new international study shows.


==========================================================================
The research, published in Science Advances, draws on decades of weather balloon observations and specialized satellite measurements to quantify
the extent to which the top of the lowest level of the atmosphere is
rising. That region, the tropopause, is pushing up the boundary with
the stratosphere by about 50-60 meters (about 165-195 feet) per decade.

The rising is caused by warming temperatures near Earth's surface that
are causing the lower atmosphere to expand.

"This is an unambiguous sign of changing atmospheric structure," said
Bill Randel, a scientist at the National Center for Atmospheric Research
(NCAR) and co-author of the new study. "These results provide independent confirmation, in addition to all the other evidence of climate change,
that greenhouse gases are altering our atmosphere." The international
research team was led by scientists at Nanjing University in China. The
study was supported in part by the National Science Foundation, which
is NCAR's sponsor.

Impacts from greenhouse gases, ozone-destroying chemicals The height
of the tropopause, an atmospheric region that divides the dense and
turbulent troposphere from the overlying and more stable stratosphere,
ranges from about 5 miles above Earth's surface at the poles to 10 miles
at the equator, depending on the season. The location of the tropopause is
of interest to commercial pilots who often fly in the lower stratosphere
to avoid turbulence, and it plays a role in severe thunderstorms, whose overshooting tops sometimes drive the tropopause higher and draw down
air from the stratosphere.



==========================================================================
The steadily increasing height of the tropopause in recent decades does
not significantly affect society or ecosystems, but it illustrates the wide-ranging impacts of greenhouse gas emissions.

Previous scientific studies have shown that the tropopause is rising. This
was not only because of climate change, but also because of cooling
in the stratosphere associated with ozone depletion. The 1987 Montreal
Protocol and subsequent international agreements to restrict emissions
of ozone-destroying chemicals, however, have successfully reversed the
loss of ozone and stabilized temperatures in the lower stratosphere.

Randel and his co-authors pulled together newly available data to analyze
how much the tropopause is continuing to rise now that stratospheric temperatures are no longer having a significant impact.

They turned primarily to two sources of information. One was a recently
updated archive of observations from radiosondes, which have been lofted
high into the atmosphere for decades on weather balloons to measure
atmospheric properties.

Because the radiosonde data is most detailed over land areas of the
Northern Hemisphere between 20 and 80 degrees in latitude, the new study focused on the rising height of the tropopause in that region.

The scientists also analyzed observations from specialized satellite instruments dating back to 2002 that probe the atmosphere by measuring
the degree to which Global Positioning System (GPS) radio signals bend
and slow as they pass through the atmosphere. This innovative technique,
known as GPS radio occultation, was pioneered in part by an array of
satellites known as COSMIC (now COSMIC-2), whose data is processed and disseminated by the University Corporation for Atmospheric Research,
which manages NCAR.



==========================================================================
The research team then applied statistical techniques to account for the
impact of natural events that temporarily change atmospheric temperatures
and affect the tropopause, such as volcanic eruptions and the periodic
warming of surface waters in the eastern tropical Pacific Ocean known as
El Nin~o. This enabled them to isolate the role of human-induced warming.

Their analysis of radiosonde observations showed that the tropopause has increased in height at a steady pace since 1980: about 58-59 meters per
decade, of which 50-53 meters per decade is attributable to human-induced warming of the lower atmosphere. This trend has continued even as the
influence from stratospheric temperatures has waned, demonstrating that
warming in the troposphere is having an increasingly large impact.

The satellite observations taken since 2000 verified that the height of
the tropopause has increased over the past two decades.

"The study captures two important ways that humans are changing
the atmosphere," Randel said. "The height of the tropopause
is being increasingly affected by emissions of greenhouse
gases even as society has successfully stabilized conditions
in the stratosphere by restricting ozone-destroying chemicals." ========================================================================== Story Source: Materials provided by National_Center_for_Atmospheric_Research/University Corporation_for_Atmospheric_Research. Original written by David
Hosansky. Note: Content may be edited for style and length.


========================================================================== Journal Reference:
1. Lingyun Meng, Jane Liu, David W. Tarasick, William J. Randel,
Andrea K.

Steiner, Hallgeir Wilhelmsen, Lei Wang, Leopold
Haimberger. Continuous rise of the tropopause in the Northern
Hemisphere over 1980-2020. Science Advances, 2021; 7 (45) DOI:
10.1126/sciadv.abi8065 ==========================================================================

Link to news story: https://www.sciencedaily.com/releases/2021/11/211108130900.htm

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