| Phys.Org | - |
This picture
of Earth and the ionosphere, taken with a handheld camera by an
astronaut on the International Space Station, shows a bright red wall of
plasma near the equator.
UC Berkeley selected to build NASA's next space weather satellite
April 17, 2013 by Robert Sanders
UC Berkeley selected to build NASA’s next space weather satellite
Enlarge
This picture of Earth and the ionosphere, taken with a handheld camera
by an astronaut on the International Space Station, shows a bright red
wall of plasma near the equator. The ICON satellite will image this
glowing plasma in order to connect Earth storms to ionospheric storms
and better predict space weather. Though the glowing plasma looks like
the aurora, it's much higher in altitude.Credit: NASA.
(Phys.org) —NASA has awarded the University of California, Berkeley, up
to $200 million to build a satellite to determine how Earth's weather
affects weather at the edge of space, in hopes of improving forecasts of
extreme "space weather" that can disrupt global positioning satellites
(GPS) and radio communications.
Ads by Google
Buffett's Top 5 Stocks - These 5 stocks make up 75% of his firm’s
portfolio. Free picks. - www.StreetAuthority.com
The satellite mission, called the Ionospheric Connection Explorer
(ICON), will be designed, built and operated by scientists at UC
Berkeley's Space Sciences Laboratory. Scheduled for launch in 2017, ICON
will orbit 550 kilometers (345 miles) above Earth in the ionosphere:
the edge of space where the sun ionizes the air to create constantly
shifting streams and sheets of charged particles. These charged
particles can interfere with GPS signals and radio signals that travel
through and bounce off the ionosphere.
ICON will collect data needed to establish the connection between storms
that occur near Earth's surface and space-weather storms, allowing
scientists to better predict space weather. These results could help
airliners, for example, which today cannot rely solely on GPS satellites
to fly and land because signals from these satellites can be distorted
by charged-particle storms in the ionosphere.
"Ten years ago, we had no idea that the ionosphere was affected and
structured by storms in the lower atmosphere," said the project's
principal investigator, Thomas Immel, a senior fellow at the Space
Sciences Laboratory. "We proposed ICON in response to this new
realization."
NASA announced the award last week, along with another mission called
the Global-scale Observations of the Limb and Disk (GOLD), which will
image Earth's thermosphere and ionosphere from a commercial
geosynchronous satellite.
"One of the frontier areas of heliophysics is the study of the interface
between outer space and the upper reaches of Earth's atmosphere," said
John Grunsfeld, NASA associate administrator for science at NASA
Headquarters in Washington, D.C. "These selected projects use innovative
solutions to advance our knowledge of this relatively unexplored
region. The two missions together will result in significantly more
advances in our understanding of Earth's atmosphere and ionosphere than
either would alone."
Ads by Google
10 Stocks to Hold Forever - Buy them, forget about them, and never sell
them. - www.StreetAuthority.com
Until recently, Immel said, the ionosphere was thought to be affected
primarily by the solar wind, which consists of charged particles emitted
from the sun. When the sun is active and firing bursts of charged
particles toward Earth, the ionosphere erupts in chaotic storms. But a
slew of satellites orbiting Earth to study the sun, solar wind and
Earth's magnetic field have now shown that Earth's space environment,
specifically activity in the ionosphere, can't be explained solely by
particles streaming from the sun.
UC Berkeley selected to build NASA’s next space weather satellite
The ICON satellite will orbit Earth at a 27 degree angle to the equator,
pointing its MIGHTI imager and far and extreme ultraviolet sensors at
ionospheric storms as on-board instruments measure the flow of
charged-particles (guided by the arched magnetic field shown with blue
lines) at the position of the satellite.
"We know that the solar wind plays a big role in the ionosphere, but
most of the time the sun is relatively quiet, and our space environment
still varies quite a bit," he said. "We think that variability is coming
from weather on our own planet, which can be very powerful."
This can happen, Immel said, when surface storms compress and heat the
atmosphere, driving huge waves upward into space and causing charged
particles to move across magnetic fields in unpredictable ways. This can
also lead to extreme fluctuations of temperature in the ionosphere.
UC Berkeley selected to build NASA’s next space weather satellite
The ICON spacecraft, with blue solar panels and limb-pointing
instruments to measure winds in the thermosphere (MIGHTI), far and
extreme ultraviolet emissions (FUV and EUV) from the ionosphere and the
in situ ion velocity meter (IVM).
"There are huge waves at an altitude above 100 kilometers (63 miles),
with amplitudes as large as 50 degrees Kelvin, where the average
temperature is about 300 degrees Kelvin (77 degrees Fahrenheit) – a
20-30 percent variation," he said. "That may sound small, but imagine a
wave rolling through your neighborhood with a temperature swing of 100
degrees Kelvin, or 180 degrees Fahrenheit – from freezing to boiling!
These waves can change the composition of the upper atmosphere and how
the ionosphere grows during the day."
ICON will explore these and other processes that control the dynamics
and chemistry of the upper atmosphere and ionosphere. One question, for
example, is why "North America is, in a way, like tornado alley for
space storms," Immel said, where huge masses of ionized plasma roll over
the country and disrupt GPS and other communications.
"We want to understand where this plasma comes from – Is it generated in
situ? Does it grow in outer space? Or are we pulling plasma up from
lower latitudes like the Caribbean?" he said.
The satellite will operate in a circular orbit tilted 27 degrees from
the equator and simultaneously map winds in the upper atmosphere and
charged particle currents, called plasmas, in the ionosphere, a region
that stretches from an altitude of about 85 to 600 kilometers (50 to 370
miles).
The instrument called MIGHTI (Michelson Interferometer for Global
High-resolution Thermospheric Imaging), which will be built by
scientists at the Naval Research Laboratory, will detect the aurora-like
glow of air molecules and measure their temperature and speed via
Doppler imaging. These winds routinely blow at 200 miles per hour in a
part of the upper atmosphere called the thermosphere.
Two other instruments built at UC Berkeley's Space Sciences Laboratory
will simultaneously image the upper atmosphere in the far and extreme
ultraviolet, while a fourth instrument from the University of Texas,
Dallas, will measure the charged particles and flowing plasma at the
location of the satellite.
"ICON's imaging capability, combined with its in situ measurements on
the same spacecraft, gives a perspective of the coupled system that
would otherwise require two or more orbiting observatories," he said.
UC Berkeley will control the spacecraft from its Mission Operations
Center at the Space Sciences Laboratory, which currently operates the
satellite missions THEMIS, ARTEMIS, RHESSI and NuSTAR, all NASA Explorer
missions, and recently operated the FAST Explorer.
NASA is funding ICON through the Explorer program, the agency's oldest
continuous program, designed to provide frequent, low-cost access to
space for principal investigator-led space science investigations
relevant to the heliophysics and astrophysics programs in NASA's Science
Mission Directorate in Washington.
More information: icon.ssl.berkeley.edu/
Provided by University of California - Berkeley search and more info
website
Read more at: http://phys.org/news/2013-04-uc-berkeley-nasa-space-weather.html#jCp
Read more at: http://phys.org/news/2013-04-uc-berkeley-nasa-space-weather.html#jCp
UC Berkeley selected to build NASA's next space weather satellite
April 17, 2013 by Robert Sanders
UC Berkeley selected to build NASA’s next space weather satellite
Enlarge
This picture of Earth and the ionosphere, taken with a handheld camera
by an astronaut on the International Space Station, shows a bright red
wall of plasma near the equator. The ICON satellite will image this
glowing plasma in order to connect Earth storms to ionospheric storms
and better predict space weather. Though the glowing plasma looks like
the aurora, it's much higher in altitude.Credit: NASA.
(Phys.org) —NASA has awarded the University of California, Berkeley, up
to $200 million to build a satellite to determine how Earth's weather
affects weather at the edge of space, in hopes of improving forecasts of
extreme "space weather" that can disrupt global positioning satellites
(GPS) and radio communications.
Ads by Google
Buffett's Top 5 Stocks - These 5 stocks make up 75% of his firm’s
portfolio. Free picks. - www.StreetAuthority.com
The satellite mission, called the Ionospheric Connection Explorer
(ICON), will be designed, built and operated by scientists at UC
Berkeley's Space Sciences Laboratory. Scheduled for launch in 2017, ICON
will orbit 550 kilometers (345 miles) above Earth in the ionosphere:
the edge of space where the sun ionizes the air to create constantly
shifting streams and sheets of charged particles. These charged
particles can interfere with GPS signals and radio signals that travel
through and bounce off the ionosphere.
ICON will collect data needed to establish the connection between storms
that occur near Earth's surface and space-weather storms, allowing
scientists to better predict space weather. These results could help
airliners, for example, which today cannot rely solely on GPS satellites
to fly and land because signals from these satellites can be distorted
by charged-particle storms in the ionosphere.
"Ten years ago, we had no idea that the ionosphere was affected and
structured by storms in the lower atmosphere," said the project's
principal investigator, Thomas Immel, a senior fellow at the Space
Sciences Laboratory. "We proposed ICON in response to this new
realization."
NASA announced the award last week, along with another mission called
the Global-scale Observations of the Limb and Disk (GOLD), which will
image Earth's thermosphere and ionosphere from a commercial
geosynchronous satellite.
"One of the frontier areas of heliophysics is the study of the interface
between outer space and the upper reaches of Earth's atmosphere," said
John Grunsfeld, NASA associate administrator for science at NASA
Headquarters in Washington, D.C. "These selected projects use innovative
solutions to advance our knowledge of this relatively unexplored
region. The two missions together will result in significantly more
advances in our understanding of Earth's atmosphere and ionosphere than
either would alone."
Ads by Google
10 Stocks to Hold Forever - Buy them, forget about them, and never sell
them. - www.StreetAuthority.com
Until recently, Immel said, the ionosphere was thought to be affected
primarily by the solar wind, which consists of charged particles emitted
from the sun. When the sun is active and firing bursts of charged
particles toward Earth, the ionosphere erupts in chaotic storms. But a
slew of satellites orbiting Earth to study the sun, solar wind and
Earth's magnetic field have now shown that Earth's space environment,
specifically activity in the ionosphere, can't be explained solely by
particles streaming from the sun.
UC Berkeley selected to build NASA’s next space weather satellite
The ICON satellite will orbit Earth at a 27 degree angle to the equator,
pointing its MIGHTI imager and far and extreme ultraviolet sensors at
ionospheric storms as on-board instruments measure the flow of
charged-particles (guided by the arched magnetic field shown with blue
lines) at the position of the satellite.
"We know that the solar wind plays a big role in the ionosphere, but
most of the time the sun is relatively quiet, and our space environment
still varies quite a bit," he said. "We think that variability is coming
from weather on our own planet, which can be very powerful."
This can happen, Immel said, when surface storms compress and heat the
atmosphere, driving huge waves upward into space and causing charged
particles to move across magnetic fields in unpredictable ways. This can
also lead to extreme fluctuations of temperature in the ionosphere.
UC Berkeley selected to build NASA’s next space weather satellite
The ICON spacecraft, with blue solar panels and limb-pointing
instruments to measure winds in the thermosphere (MIGHTI), far and
extreme ultraviolet emissions (FUV and EUV) from the ionosphere and the
in situ ion velocity meter (IVM).
"There are huge waves at an altitude above 100 kilometers (63 miles),
with amplitudes as large as 50 degrees Kelvin, where the average
temperature is about 300 degrees Kelvin (77 degrees Fahrenheit) – a
20-30 percent variation," he said. "That may sound small, but imagine a
wave rolling through your neighborhood with a temperature swing of 100
degrees Kelvin, or 180 degrees Fahrenheit – from freezing to boiling!
These waves can change the composition of the upper atmosphere and how
the ionosphere grows during the day."
ICON will explore these and other processes that control the dynamics
and chemistry of the upper atmosphere and ionosphere. One question, for
example, is why "North America is, in a way, like tornado alley for
space storms," Immel said, where huge masses of ionized plasma roll over
the country and disrupt GPS and other communications.
"We want to understand where this plasma comes from – Is it generated in
situ? Does it grow in outer space? Or are we pulling plasma up from
lower latitudes like the Caribbean?" he said.
The satellite will operate in a circular orbit tilted 27 degrees from
the equator and simultaneously map winds in the upper atmosphere and
charged particle currents, called plasmas, in the ionosphere, a region
that stretches from an altitude of about 85 to 600 kilometers (50 to 370
miles).
The instrument called MIGHTI (Michelson Interferometer for Global
High-resolution Thermospheric Imaging), which will be built by
scientists at the Naval Research Laboratory, will detect the aurora-like
glow of air molecules and measure their temperature and speed via
Doppler imaging. These winds routinely blow at 200 miles per hour in a
part of the upper atmosphere called the thermosphere.
Two other instruments built at UC Berkeley's Space Sciences Laboratory
will simultaneously image the upper atmosphere in the far and extreme
ultraviolet, while a fourth instrument from the University of Texas,
Dallas, will measure the charged particles and flowing plasma at the
location of the satellite.
"ICON's imaging capability, combined with its in situ measurements on
the same spacecraft, gives a perspective of the coupled system that
would otherwise require two or more orbiting observatories," he said.
UC Berkeley will control the spacecraft from its Mission Operations
Center at the Space Sciences Laboratory, which currently operates the
satellite missions THEMIS, ARTEMIS, RHESSI and NuSTAR, all NASA Explorer
missions, and recently operated the FAST Explorer.
NASA is funding ICON through the Explorer program, the agency's oldest
continuous program, designed to provide frequent, low-cost access to
space for principal investigator-led space science investigations
relevant to the heliophysics and astrophysics programs in NASA's Science
Mission Directorate in Washington.
More information: icon.ssl.berkeley.edu/
Provided by University of California - Berkeley search and more info
website
Read more at: http://phys.org/news/2013-04-uc-berkeley-nasa-space-weather.html#jCp
I cannot quote this article here so if you are interested in it you will have to click on "UC Berkeley selected------" above. Read more at: http://phys.org/news/2013-04-uc-berkeley-nasa-space-weather.html#jCp
No comments:
Post a Comment