A joint NASA-U.S. Naval Research Laboratory experiment dedicated to studying the origins of solar energetic particles — the Sun’s most dangerous form of radiation — is ready for launch.
UVSC Pathfinder — short for Ultraviolet
Spectro-Coronagraph Pathfinder — will hitch a ride to space aboard STPSat-6,
the primary spacecraft of the Space Test Program-3 (STP-3) mission for the
Department of Defense. STP-3 is scheduled to lift off on a United Launch
Alliance Atlas V 551 rocket no earlier than Nov. 22, from Cape Canaveral Space
Force Station in Florida.
Solar energetic particles, or SEPs, are a
type of space weather that pose a major challenge to space exploration. A solar
particle storm, or SEP event, occurs when the Sun fires energetic particles
into space at such high speeds that some reach Earth — 93 million miles away —
in less than an hour. Flurries of the powerful particles can wreak havoc with
spacecraft and expose astronauts to dangerous radiation.
UVSC Pathfinder will peer at the lowest
regions of the Sun’s outer atmosphere, or corona, where SEPs are thought to
originate. While the Sun releases eruptions almost daily when it is most
active, there are only about 20 disruptive solar particle storms during any
given 11-year solar cycle. Scientists can’t reliably predict which of these
will produce SEPs, nor their intensity. Understanding and eventually predicting
these solar storms are crucial for enabling future space exploration.
“It’s a pathfinder because we’re demonstrating
new technology and a new way to forecast this type of space weather,” said
Leonard Strachan, an astrophysicist at the U.S. Naval Research Laboratory in
Washington, D.C., and the mission’s principal investigator. “Right now, there’s
no real way of predicting when these particle storms will happen.”
A close up of a solar eruption, including a solar flare, a coronal mass ejection, and a solar energetic particle event. Credits: NASA's Goddard Space Flight Center
Understanding and
predicting SEPs
UVSC Pathfinder is a coronagraph, a kind of instrument that blocks the
Sun’s bright face to reveal the dimmer, surrounding corona. Most coronagraphs
have a single aperture with a series of occulters that block the Sun and reduce
stray light. The novelty of UVSC Pathfinder is that it uses five separate
apertures, each with its own occulter — significantly boosting the signal from
the corona.
In the corona, scientists expect to find the special group of particles
that eventually becomes solar energetic particles. Not just any regular
particle in the Sun’s atmosphere can be energized to an SEP. Rather, scientists
think SEPs come from swarms of seed particles residing in the corona that are
already around 10 times hotter and more energetic than their neighbors. Those
could come from bright bursts of energy, called flares, or regions of intense
magnetic fields in the corona, called current sheets.
It takes some prior energetic solar activity to fire up the seed particles.
Occasionally, the Sun unleashes massive clouds of solar material, called
coronal mass ejections. Those explosions can generate a shock ahead of them,
like the wave that crests at the front of a speeding boat. “If a coronal mass
ejection comes out fast enough” — 600 miles per second at least — “it can
produce a shock, which can sweep up these particles,” Strachan explained. “The
particles get so much energy from the shock, they become SEPs.”
UVSC Pathfinder is a
spectro-coronagraph, which is an instrument that blocks the Sun’s bright face
to reveal the dimmer, surrounding corona. It is shown here being inspected
after thermal vacuum testing at NRL. Credits: Courtesy of Leonard Strachan
Unlike most coronagraphs that take images in visible light, UVSC Pathfinder is unique because it’s combined with a spectrometer that measures ultraviolet light, a kind of light that’s invisible to human eyes. By analyzing the light in the corona, researchers hope to identify when seed particles are present.
Scientists have routinely observed SEPs
from the near-Earth perspective — 93 million miles away from their origin.
Since seed particles are only present in the corona, it has been impossible to
measure them directly. UVSC Pathfinder aims to observe the elusive particles by
remotely sensing their signatures in ultraviolet light. “We know rather little
about them,” said Martin Laming, a U.S. Naval Research Laboratory physicist and
UVSC Pathfinder’s science lead. “This is really a ground-breaking observation.”
The impacts of SEP swarms are serious. When it comes
to spacecraft, they can
fry electronics, corrupt a satellite’s computer programming, damage solar
panels, and even disorient a spacecraft’s star tracker, used for navigation.
The effect is like driving through a blizzard and getting lost: SEPs fill the
star tracker’s view, and losing its ability to orient itself, it spins off
orbit.
To humans, SEPs are dangerous because they
can pass through spacecraft or an astronaut’s skin, where they can damage cells
or DNA. This damage can increase risk for cancer later in life, or in extreme
cases, cause acute radiation sickness in the short-term. (On Earth, our
planet’s protective magnetic field and atmosphere shield humans from this
harm.) A series of
enormous solar flares in
August 1972 — in between the Apollo 16 and 17 missions — serves as a reminder of the threat solar activity
and radiation poses.
The UVSC Pathfinder experiment marks a
major step toward understanding where SEPs come from and how they evolve as
they travel through the solar system. The data will help scientists predict
whether a solar explosion could generate problematic SEPs much the way we
predict severe weather events on Earth. Forecasts would enable spacecraft
operators and astronauts to take steps to mitigate their impacts. “If our
thinking is correct, seed particles will be a really important signature of
radiation storms to watch out for,” Laming said.
Images from NASA's STEREO satellite show a coronal mass ejection followed by a flurry of solar energetic particles. Credits: NASA/STEREO
Joining NASA’s
heliophysics fleet
UVSC Pathfinder is the latest addition to NASA's fleet of heliophysics
observatories. NASA heliophysics missions study a vast, interconnected system
from the Sun to the space surrounding Earth and other planets, and to the
farthest limits of the Sun's constantly flowing stream of solar wind. UVSC
Pathfinder provides key information on SEPs, enabling future space exploration.
The mission’s observations will complement those of two other solar
observatories. The new coronagraph will look as close as 865,000 miles from the
Sun, while NASA’s Parker Solar Probe and the European
Space Agency and NASA’s Solar Orbiter will directly
sample the space up to a distance of 3.8 million miles and 26.7 million miles
from the Sun, respectively. “We hope coordinated observations will be useful in
pinning down the evolution of SEPs as they move out from the Sun,” Strachan
said.
“The NASA science program has a long history of obtaining predictive space
weather tools from the results of pure research missions,” said Daniel Moses,
chief technologist in NASA’s Heliophysics Division. “Collaboration between the
NASA Science Mission Directorate, the Naval Research Laboratory and the
Department of Defense STP program has been particularly fruitful in this area.
UVSC Pathfinder continues this proud tradition of basic research collaboration
with the potential of developing a new, high-impact tool with predictive
capability.”
UVSC Pathfinder is a NASA and U.S. Naval Research Laboratory payload aboard
the Department of Defense’s Space Test Program Satellite-6 (STPSat-6). It flies
alongside NASA’s Laser Communications Relay
Demonstration (LCRD), which is testing an enhanced
communications capability with the potential to increase bandwidth 10 to 100
times more than radio frequency systems — allowing space missions to send more
data home.
UVSC Pathfinder was designed and built at the U.S. Naval Research
Laboratory. It was funded through NASA’s Heliophysics Program and the Office of
Naval Research. It is managed by the Heliophysics Technology and Instrument
Development for Science, or H-TIDeS, program office at NASA Headquarters. STP is
operated by the United States Space Force’s Space Systems Command.
By Lina Tran NASA’s Goddard Space Flight Center, Greenbelt, Md.
Source: Pathfinding
Experiment to Study Origins of Solar Energetic Particles | NASA
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