The
Sun Profile
- diameter: 1,390,000 km.
- mass: 1.989e30 kg
- temperature: 5800 K (surface) 15,600,000 K (core)
History of The Sun
The
Sun is by far the largest object in the solar system. It contains more than
99.8% of the total mass of the Solar System (Jupiter contains most of the
rest).
It
is often said that the Sun is an "ordinary" star. That's true in the
sense that there are many others similar to it. But there are many more smaller
stars than larger ones; the Sun is in the top 10% by mass. The median size of
stars in our galaxy is probably less than half the mass of the Sun.
How
big is the sunThe Sun is personified in many mythologies: the Greeks called it
Helios and the Romans called it Sol.
The Sun is, at present, about 70% hydrogen and
28% helium by mass everything else ("metals") amounts to less than
2%. This changes slowly over time as the Sun converts hydrogen to helium in its
core.
The
outer layers of the Sun exhibit differential rotation: at the equator the
surface rotates once every 25.4 days; near the poles it's as much as 36 days.
This odd behavior is due to the fact that the Sun is not a solid body like the
Earth. Similar effects are seen in the gas planets. The differential rotation
extends considerably down into the interior of the Sun but the core of the Sun
rotates as a solid body.
Conditions
at the Sun's core (approximately the inner 25% of its radius) are extreme. The
temperature is 15.6 million Kelvin and the pressure is 250 billion atmospheres.
At the center of the core the Sun's density is more than 150 times that of
water.
The
Sun's power (about 386 billion billion mega Watts) is produced by nuclear fusion
reactions. Each second about 700,000,000 tons of hydrogen are converted to
about 695,000,000 tons of helium and 5,000,000 tons (=3.86e33 ergs) of energy
in the form of gamma rays. As it travels out toward the surface, the energy is
continuously absorbed and re-emitted at lower and lower temperatures so that by
the time it reaches the surface, it is primarily visible light. For the last
20% of the way to the surface the energy is carried more by convection than by
radiation.
The
surface of the Sun, called the photosphere, is at a temperature of about 5800
K. Sunspots are "cool" regions, only 3800 K (they look dark only by
comparison with the surrounding regions). Sunspots can be very large, as much
as 50,000 km in diameter. Sunspots are caused by complicated and not very well
understood interactions with the Sun's magnetic field.
A
small region known as the chromosphere lies above the photosphere.
The
highly rarefied region above the chromosphere, called the corona, extends
millions of kilometers into space but is visible only during a total solar
eclipse (left). Temperatures in the corona are over 1,000,000 K.
It
just happens that the Moon and the Sun appear the same size in the sky as
viewed from the Earth. And since the Moon orbits the Earth in approximately the
same plane as the Earth's orbit around the Sun sometimes the Moon comes
directly between the Earth and the Sun. This is called a solar eclipse; if the
alignment is slighly imperfect then the Moon covers only part of the Sun's disk
and the event is called a partial eclipse. When it lines up perfectly the
entire solar disk is blocked and it is called a total eclipse of the Sun.
Partial eclipses are visible over a wide area of the Earth but the region from
which a total eclipse is visible, called the path of totality, is very narrow,
just a few kilometers (though it is usually thousands of kilometers long).
Eclipses of the Sun happen once or twice a year. If you stay home, you're
likely to see a partial eclipse several times per decade. But since the path of
totality is so small it is very unlikely that it will cross you home. So people
often travel half way around the world just to see a total solar eclipse. To
stand in the shadow of the Moon is an awesome experience. For a few precious
minutes it gets dark in the middle of the day. The stars come out. The animals
and birds think it's time to sleep. And you can see the solar corona. It is
well worth a major journey.
The
Sun's magnetic field is very strong (by terrestrial standards) and very
complicated. Its magnetosphere (also known as the heliosphere) extends well
beyond Pluto.
In
addition to heat and light, the Sun also emits a low density stream of charged
particles (mostly electrons and protons) known as the solar wind which
propagates throughout the solar system at about 450 km/sec. The solar wind and
the much higher energy particles ejected by solar flares can have dramatic
effects on the Earth ranging from power line surges to radio interference to
the beautiful aurora borealis.
Recent
data from the spacecraft Ulysses show that during the minimum of the solar
cycle the solar wind emanating from the polar regions flows at nearly double
the rate, 750 kilometers per second, than it does at lower latitudes. The
composition of the solar wind also appears to differ in the polar regions.
During the solar maximum, however, the solar wind moves at an intermediate
speed.
Further
study of the solar wind will be done by Wind, ACE and SOHO spacecraft from the
dynamically stable vantage point directly between the Earth and the Sun about
1.6 million km from Earth.
The
solar wind has large effects on the tails of comets and even has measurable
effects on the trajectories of spacecraft.
Spectacular
loops and prominences are often visible on the Sun's limb (left).
The
Sun's output is not entirely constant. Nor is the amount of sunspot activity.
There was a period of very low sunspot activity in the latter half of the 17th
century called the Maunder Minimum. It coincides with an abnormally cold period
in northern Europe sometimes known as the Little Ice Age. Since the formation
of the solar system the Sun's output has increased by about 40%.
The
Sun is about 4.5 billion years old. Since its birth it has used up about half
of the hydrogen in its core. It will continue to radiate "peacefully"
for another 5 billion years or so (although its luminosity will approximately
double in that time). But eventually it will run out of hydrogen fuel. It will
then be forced into radical changes which, though commonplace by stellar
standards, will result in the total destruction of the Earth (and probably the
creation of a planetary nebula).
Source: http://nineplanets.org/sol.html
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