Fireworks of the Sun make spectacular display
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Mar 16, 2011, 5:32:47 AM3/16/11
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In this x-ray photo provided by NASA, the sun is shown early in the morning of
Sunday, August 1, 2010. The dark arc near the top right edge of the image is a
filament of plasma blasting off the surface - part of the coronal mass ejection.
The bright region is an unassociated solar flare. When particles from the
eruption reach Earth on the evening of August 3-4, they may trigger a brilliant
auroral display known as the Northern Lights. (Photo: AP/NASA)
On August 1st, almost the entire Earth-facing side of the sun erupted in a
tumult of activity. There was a C3-class solar flare, a solar tsunami, multiple
filaments of magnetism lifting off the stellar surface, large-scale shaking of
the solar corona, radio bursts, a coronal mass ejection and more. This extreme
ultraviolet snapshot from the Solar Dynamics Observatory shows the sun's
northern hemisphere in mid-eruption. Different colors in the image represent
different gas temperatures ranging from ~1 to 2 million degrees K. (Text and
Photo: NASA/SDO)
On August 1st around 0855 UT, Earth orbiting satellites detected a C3-class
solar flare. The origin of the blast was Earth-facing sunspot 1092. C-class
solar flares are small and usually have few noticeable consequences here on
Earth besides aurorae. This one has spawned a coronal mass ejection heading in
Earth's direction. This new image from the Solar Dynamics Observatory's
Atmospheric Imaging Assembly (AIA) shows in great detail a solar prominence
taken from a March 30, 2010 eruption. The twisting motion of the material is the
most noticeable feature. Launched on February 11, 2010, SDO is the most advanced
spacecraft ever designed to study the sun. (Text and Photo: NASA/SDO)
Coronal mass ejections (or CMEs) are large clouds of charged particles that are
ejected from the Sun over the course of several hours and can carry up to ten
billion tons (1016 grams) of plasma. They expand away from the Sun at speeds as
high as a million miles an hour. A CME can make the 93-million-mile journey to
Earth in just three to four days. At the time of this snapshot taken on Friday,
March 12, the eruptive prominence was over 700,000 km (420,000 miles across),
over 50 times the Earth's diameter. That's like measuring the length of 50
Earth's standing side-by-side! Even more, the plasma was moving at a rate of
over 75,000 km per hour (50,000 mph).(Text and Photo: NASA/SDO)
When a coronal mass ejection reaches Earth, it interacts with our planet's
magnetic field, potentially creating a geomagnetic storm. Solar particles stream
down the field lines toward Earth's poles and collide with atoms of nitrogen and
oxygen in the atmosphere, resulting in spectacular auroral displays. The STEREO
(Ahead) spacecraft caught this spectacular eruptive prominence in extreme UV
light as it blasted away from the Sun (Apr. 12-13, 2010). This was certainly
among the largest prominence eruptions seen by either NASA's STEREO or SOHO
missions. (Text and Photo: NASA/SDO)
Scientists said residents of northern regions - from Maine to Michigan and
anywhere farther north around the globe - may see unusual northern lights.
Usually only regions closer to the Arctic can see the aurora of rippling reds
and greens, but solar storms pull them south. A SDO/AIA Zoom-out photo sequence
of Launching Filament (band 304). In the following photographs the view of the
filament launch loops several times before pulling out to show the full solar
disk. (Photo: NASA/SDO)
The Sun's "surface" - the photosphere - is a 500-kilometer-thick
(300-mile-thick) region, from which most of the Sun's radiation escapes outward
and is detected as the sunlight we observe here on Earth about eight minutes
after it leaves the Sun.(Text and Photo: NASA/SDO)
Sunspots in the photosphere are areas with strong magnetic fields that are
cooler, and thus darker, than the surrounding region. (Text and Photo Credit:
NASA/SDO)
The number of sunspots goes up and down every 11 years as part of the Sun's
magnetic activity cycle. Also connected to this cycle are bright solar flares
and huge coronal mass ejections that blast off the Sun. (Text and Photo:
NASA/SDO)
According to NASA, this type of eruption is one of the first signs that the sun
is waking up and heading toward another solar maximum, which is expected in
2013. The last solar maximum was in 2001.
Some of the images from the SDO spacecraft show never-before-seen detail of
material streaming outward and away from sunspots. Others show extreme close-ups
of activity on the sun's surface. The spacecraft also has made the first
high-resolution measurements of solar flares in a broad range of extreme
ultraviolet wavelengths.
Stills from the AIA instrument on SDO. They show the March prominence eruption
captured just after the AIA sensors were activated. All images are from the
ultraviolet part of the spectrum. (Photo: NASA/Goddard Space Flight Center
Scientific Visualization Studio)
To know more
On August 1st around 0855 UT, Earth orbiting satellites detected a C3-class
solar flare. The origin of the blast was Earth-facing sunspot 1092. C-class
solar flares are small and usually have few noticeable consequences here on
Earth besides aurorae. This one has spawned a coronal mass ejection heading in
Earth's direction. This new image from the Solar Dynamics Observatory's
Atmospheric Imaging Assembly (AIA) shows in great detail a solar prominence
taken from a March 30, 2010 eruption. The twisting motion of the material is the
most noticeable feature. Launched on February 11, 2010, SDO is the most advanced
spacecraft ever designed to study the sun. (Text and Photo: NASA/SDO)
Coronal mass ejections (or CMEs) are large clouds of charged particles that are
ejected from the Sun over the course of several hours and can carry up to ten
billion tons (1016 grams) of plasma. They expand away from the Sun at speeds as
high as a million miles an hour. A CME can make the 93-million-mile journey to
Earth in just three to four days. At the time of this snapshot taken on Friday,
March 12, the eruptive prominence was over 700,000 km (420,000 miles across),
over 50 times the Earth's diameter. That's like measuring the length of 50
Earth's standing side-by-side! Even more, the plasma was moving at a rate of
over 75,000 km per hour (50,000 mph).(Text and Photo: NASA/SDO)
When a coronal mass ejection reaches Earth, it interacts with our planet's
magnetic field, potentially creating a geomagnetic storm. Solar particles stream
down the field lines toward Earth's poles and collide with atoms of nitrogen and
oxygen in the atmosphere, resulting in spectacular auroral displays. The STEREO
(Ahead) spacecraft caught this spectacular eruptive prominence in extreme UV
light as it blasted away from the Sun (Apr. 12-13, 2010). This was certainly
among the largest prominence eruptions seen by either NASA's STEREO or SOHO
missions. (Text and Photo: NASA/SDO)
Scientists said residents of northern regions - from Maine to Michigan and
anywhere farther north around the globe - may see unusual northern lights.
Usually only regions closer to the Arctic can see the aurora of rippling reds
and greens, but solar storms pull them south. A SDO/AIA Zoom-out photo sequence
of Launching Filament (band 304). In the following photographs the view of the
filament launch loops several times before pulling out to show the full solar
disk. (Photo: NASA/SDO)
The Sun's "surface" - the photosphere - is a 500-kilometer-thick
(300-mile-thick) region, from which most of the Sun's radiation escapes outward
and is detected as the sunlight we observe here on Earth about eight minutes
after it leaves the Sun.(Text and Photo: NASA/SDO)
Sunspots in the photosphere are areas with strong magnetic fields that are
cooler, and thus darker, than the surrounding region. (Text and Photo Credit:
NASA/SDO)
The number of sunspots goes up and down every 11 years as part of the Sun's
magnetic activity cycle. Also connected to this cycle are bright solar flares
and huge coronal mass ejections that blast off the Sun. (Text and Photo:
NASA/SDO)
According to NASA, this type of eruption is one of the first signs that the sun
is waking up and heading toward another solar maximum, which is expected in
2013. The last solar maximum was in 2001.
Some of the images from the SDO spacecraft show never-before-seen detail of
material streaming outward and away from sunspots. Others show extreme close-ups
of activity on the sun's surface. The spacecraft also has made the first
high-resolution measurements of solar flares in a broad range of extreme
ultraviolet wavelengths.
Stills from the AIA instrument on SDO. They show the March prominence eruption
captured just after the AIA sensors were activated. All images are from the
ultraviolet part of the spectrum. (Photo: NASA/Goddard Space Flight Center
Scientific Visualization Studio)
To know more
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