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The Sun is the most prominent feature in our solar system. It is the largest
object and contains approximately 98% of the total solar system mass. One
hundred and nine Earths would be required to fit across the Sun's disk, and its
interior could hold over 1.3 million Earths. The Sun's outer visible layer is
called the photosphere and has a temperature of 6,000°C (11,000°F). This layer
has a mottled appearance due to the turbulent eruptions of energy at the
surface.
Solar energy is created deep within the core of the Sun. It is here that the
temperature (15,000,000° C; 27,000,000° F) and pressure (340 billion times
Earth's air pressure at sea level) is so intense that nuclear reactions take
place. This reaction causes four protons or hydrogen nuclei to fuse together to
form one alpha particle or helium nucleus. The alpha particle is about .7
percent less massive than the four protons. The difference in mass is expelled
as energy and is carried to the surface of the Sun, through a process known as convection,
where it is released as light and heat. Energy generated in the Sun's core takes
a million years to reach its surface. Every second 700 million tons of hydrogen
are converted into helium ashes. In the process 5 million tons of pure
energy is released; therefore, as time goes on the Sun is becoming lighter.
The chromosphere is above the photosphere. Solar energy passes through this
region on its way out from the center of the Sun. Faculae and flares arise in
the chromosphere. Faculae are bright luminous hydrogen clouds which form above
regions where sunspots are about to form. Flares are bright filaments of hot gas
emerging from sunspot regions. Sunspots are dark depressions on the photosphere
with a typical temperature of 4,000°C (7,000°F).
The corona is the outer part of the Sun's atmosphere. It is in this region
that prominences appears. Prominences are immense clouds of glowing gas
that erupt from the upper chromosphere. The outer region of the corona stretches
far into space and consists of particles traveling slowly away from the Sun. The
corona can only be seen during total solar eclipses. (See
Solar Eclipse Image).
The Sun appears to have been active for 4.6 billion years and has enough fuel
to go on for another five billion years or so. At the end of its life, the Sun
will start to fuse helium into heavier elements and begin to swell up,
ultimately growing so large that it will swallow the Earth. After a billion
years as a red giant,
it will suddenly collapse into a white
dwarf -- the final end product of a star like ours. It may take a trillion
years to cool off completely.
| Sun Statistics |
| Mass (kg) |
1.989e+30 |
| Mass (Earth = 1) |
332,830 |
| Equatorial radius (km) |
695,000 |
| Equatorial radius (Earth = 1) |
108.97 |
| Mean density (gm/cm^3) |
1.410 |
| Rotational period (days) |
25-36* |
| Escape velocity (km/sec) |
618.02 |
| Luminosity (ergs/sec) |
3.827e33 |
| Magnitude (Vo) |
-26.8 |
| Mean surface temperature |
6,000°C |
| Age (billion years) |
4.5 |
Principal chemistry
- Hydrogen
- Helium
- Oxygen
- Carbon
- Nitrogen
- Neon
- Iron
- Silicon
- Magnesium
- Sulfur
- All others
|
92.1%
7.8%
0.061%
0.030%
0.0084%
0.0076%
0.0037%
0.0031%
0.0024%
0.0015%
0.0015% |
* The Sun's period of rotation at the surface varies from approximately 25
days at the equator to 36 days at the poles. Deep down, below the convective
zone, everything appears to rotate with a period of 27 days.
Sun Prominence
This image was acquired from NASA's Skylab space station on December 19, 1973.
It shows one of the most spectacular solar flares ever recorded, propelled by
magnetic forces, lifting off from the Sun. It spans more than 588,000 km
(365,000 miles) of the solar surface. In this photograph, the solar poles are
distinguished by a relative absence of supergranulation network, and a much
darker tone than the central portions of the disk. (Courtesy NASA)
Comet SOHO-6
and Solar Polar Plumes
This image of the solar corona was acquired on 23 December 1996 by the LASCO
instrument on the SOHO spacecraft. It shows the inner streamer belt along the
Sun's equator, where the low latitude solar wind originates and is accelerated.
Over the polar regions, one sees the polar plumes all the way out to the edge of
the field of view. The field of view of this coronagraph encompasses 8.4 million
kilometers (5.25 million miles) of the inner heliosphere. The frame was selected
to show Comet SOHO-6, one of seven sungrazers discovered so far by LASCO, as its
head enters the equatorial solar wind region. It eventually plunged into the
Sun. (Courtesy ESA/NASA)
Sources of
the Solar Wind?
"Plumes" of outward flowing, hot gas in the Sun's atmosphere may be
one source of the solar "wind" of charged particles. These images,
taken March 7, 1996, by the Solar and Heliospheric Observatory (SOHO), show
(top) magnetic fields on the sun's surface near the south solar pole; (middle)
an ultraviolet image of the 1 million degree plumes from the same region; and
(bottom) an ultraviolet image of the "quiet" solar atmosphere closer
to the surface. (Courtesy ESA/NASA)
The Unquiet
Sun
This sequence of images of the the Sun in ultraviolet light was taken by the
Solar and Heliospheric Observatory (SOHO) spacecraft on February 11, 1996 from
its unique vantage point at the "L1" gravity neutral point 1 million
miles sunward from the Earth. An "eruptive prominence" or blob of
60,000°C gas, over 80,000 miles long, was ejected at a speed of at least 15,000
miles per hour. The gaseous blob is shown to the left in each image. These
eruptions occur when a significant amount of cool dense plasma or ionized gas
escapes from the normally closed, confining, low-level magnetic fields of the
Sun's atmosphere to streak out into the interplanetary medium, or heliosphere.
Eruptions of this sort can produce major disruptions in the near Earth
environment, affecting communications, navigation systems and even power grids. (Courtesy
ESA/NASA)
A New Look
at the Sun
This image of 1,500,000°C gas in the Sun's thin, outer atmosphere (corona) was
taken March 13, 1996 by the Extreme Ultraviolet Imaging Telescope onboard the
Solar and Heliospheric Observatory (SOHO) spacecraft. Every feature in the image
traces magnetic field structures. Because of the high quality instrument, more
of the subtle and detail magnetic features can be seen than ever before. (Courtesy
ESA/NASA)
X-Ray Image
This is an X-ray image of the Sun obtained on February 21, 1994. The brighter
regions are sources of increased X-ray emissions. (Courtesy Calvin J.
Hamilton, and Yohkoh)
Solar Disk in
H-Alpha
This is an image of the Sun as seen in H-Alpha.
H-Alpha is a narrow wavelength of red light that is emitted and absorbed by the
element hydrogen. (Courtesy National Solar Observatory/Sacramento Peak)
Solar Flare
in H-Alpha
This is an image of a solar flare as seen in H-Alpha.
(Courtesy National Solar Observatory/Sacramento Peak)
Solar Magnetic
Fields
This image was acquired February 26, 1993. The dark regions are locations of
positive magnetic polarity and the light regions are negative magnetic polarity.
(Courtesy GSFC NASA)
Sun Spots
This image shows the region around a sunspot.
Notice the mottled appearance. This granulation is the result of turbulent
eruptions of energy at the surface. (Courtesy National Solar
Observatory/Sacramento Peak)
1991 Solar
Eclipse
This image shows the total solar eclipse of July 11, 1991 as seen from Baja
California. It is a digital mosaic derived from five individual photographs,
each exposed correctly for a different radius in the solar corona. (Courtesy Steve
Albers, Dennis DiCicco, and Gary Emerson)
1994 Solar
Eclipse
This picture of the 1994 solar eclipse was taken November 3, 1994, as observed
by the High Altitude Observatory White Light Coronal camera from Chile. (Courtesy
HAO, NCAR)
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