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7463


Date: April 01, 2024 at 09:32:30
From: akira, [DNS_Address]
Subject: NASA to launch 3 rockets on Eclipse under Project codename APEP

URL: https://science.nasa.gov/solar-system/skywatching/nasa-to-launch-sounding-rockets-into-moons-shadow-during-solar-eclipse/


NASA to Launch Sounding Rockets into Moon’s Shadow During Solar Eclipse

Desiree Apodaca
MAR 25, 2024

ARTICLE
NASA will launch three sounding rockets during the total solar eclipse on
April 8, 2024, to study how Earth’s upper atmosphere is affected when
sunlight momentarily dims over a portion of the planet.

The Atmospheric Perturbations around Eclipse Path (APEP) sounding rockets
will launch from NASA’s Wallops Flight Facility in Virginia to study the
disturbances in the ionosphere created when the Moon eclipses the Sun. The
sounding rockets had been previously launched and successfully recovered
from White Sands Test Facility in New Mexico, during the October 2023
annular solar eclipse. They have been refurbished with new instrumentation
and will be relaunched in April 2024. The mission is led by Aroh Barjatya, a
professor of engineering physics at Embry-Riddle Aeronautical University in
Florida, where he directs the Space and Atmospheric Instrumentation Lab.

This photo shows the three APEP sounding rockets and the support team
after successful assembly. The team lead, Aroh Barjatya, is at the top center,
standing next to the guardrails on the second floor.
NASA/Berit Bland
The sounding rockets will launch at three different times: 45 minutes before,
during, and 45 minutes after the peak local eclipse. These intervals are
important to collect data on how the Sun’s sudden disappearance affects the
ionosphere, creating disturbances that have the potential to interfere with
our communications.

This conceptual animation is an example of what observers might expect to
see during a total solar eclipse, like the one happening over the United States
on April 8, 2024.
NASA's Scientific Visualization Studio.
The ionosphere is a region of Earth’s atmosphere that is between 55 to 310
miles (90 to 500 kilometers) above the ground. “It’s an electrified region that
reflects and refracts radio signals, and also impacts satellite communications
as the signals pass through,” said Barjatya. “Understanding the ionosphere
and developing models to help us predict disturbances is crucial to making
sure our increasingly communication-dependent world operates smoothly.”
The ionosphere forms the boundary between Earth's lower atmosphere –
where we live and breathe – and the vacuum of space. It is made up of a sea
of particles that become ionized, or electrically charged, from the Sun’s
energy, or solar radiation. When night falls, the ionosphere thins out as
previously ionized particles relax and recombine back into neutral particles.
However, Earth’s terrestrial weather and space weather can impact these
particles, making it a dynamic region and difficult to know what the
ionosphere will be like at a given time. 

An animation depicts changes in the ionosphere over a 24-hour period. The
red and yellow swaths represent high-density ionized particles during the
day. The purple dots represent neutral, relaxed particles at night.
NASA/Krystofer Kim
It’s often difficult to study short-term changes in the ionosphere during an
eclipse with satellites because they may not be at the right place or time to
cross the eclipse path. Since the exact date and times of the total solar
eclipse are known, NASA can launch targeted sounding rockets to study the
effects of the eclipse at the right time and at all altitudes of the ionosphere.
As the eclipse shadow races through the atmosphere, it creates a rapid,
localized sunset that triggers large-scale atmospheric waves and small-scale
disturbances, or perturbations. These perturbations affect different radio
communication frequencies. Gathering the data on these perturbations will
help scientists validate and improve current models that help predict
potential disturbances to our communications, especially high frequency
communication. 

The animation depicts the waves created by ionized particles during the
2017 total solar eclipse.
MIT Haystack Observatory/Shun-rong Zhang. Zhang, S.-R., Erickson, P. J.,
Goncharenko, L. P., Coster, A. J., Rideout, W. & Vierinen, J. (2017).
Ionospheric Bow Waves and Perturbations Induced by the 21 August 2017
Solar Eclipse. Geophysical Research Letters, 44(24), 12,067-12,073.
https://doi.org/10.1002/2017GL076054.
The APEP rockets are expected to reach a maximum altitude of 260 miles
(420 kilometers). Each rocket will measure charged and neutral particle
density and surrounding electric and magnetic fields. “Each rocket will eject
four secondary instruments the size of a two-liter soda bottle that also
measure the same data points, so it's similar to results from fifteen rockets,
while only launching three,” explained Barjatya. Three secondary instruments
on each rocket were built by Embry-Riddle, and the fourth one was built at
Dartmouth College in New Hampshire.
In addition to the rockets, several teams across the U.S. will also be taking
measurements of the ionosphere by various means. A team of students from
Embry-Riddle will deploy a series of high-altitude balloons. Co-investigators
from the Massachusetts Institute of Technology’s Haystack Observatory in
Massachusetts, and the Air Force Research Laboratory in New Mexico, will
operate a variety of ground-based radars taking measurements. Using this
data, a team of scientists from Embry-Riddle and Johns Hopkins University
Applied Physics Laboratory are refining existing models. Together, these
various investigations will help provide the puzzle pieces needed to see the
bigger picture of ionospheric dynamics.

A sounding rocket is able to carry science instruments between 30 and 300
miles above Earth's surface. These altitudes are typically too high for science
balloons and too low for satellites to access safely, making sounding rockets
the only platforms that can carry out direct measurements in these regions.
NASA's Goddard Space Flight Center
When the APEP sounding rockets launched during the 2023 annular solar
eclipse, scientists saw a sharp reduction in the density of charged particles
as the annular eclipse shadow passed over the atmosphere. “We saw the
perturbations capable of affecting radio communications in the second and
third rockets, but not during the first rocket that was before peak local
eclipse” said Barjatya. “We are super excited to relaunch them during the
total eclipse, to see if the perturbations start at the same altitude and if their
magnitude and scale remain the same.”
The next total solar eclipse over the contiguous U.S. is not until 2044, so
these experiments are a rare opportunity for scientists to collect crucial data.
The APEP launches will be live streamed via NASA’s Wallops’ official YouTube
page and featured in NASA’s official broadcast of the total solar eclipse. The
public can also watch the launches in person from 1-4 p.m. at the NASA
Wallops Flight Facility Visitor Center.
By Desiree Apodaca
NASA’s Goddard Space Flight Center, Greenbelt, Md.


Responses:
[7464]


7464


Date: April 04, 2024 at 03:23:18
From: Eve, [DNS_Address]
Subject: Re: NASA to launch 3 rockets on Eclipse under Project codename APEP




Interesting.


Responses:
None


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