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Mosaic of the planets of the solar system, excluding Pluto, and including Earth's Moon. Note: planets are not portrayed in the
same scale.
A generic solar system (or planetary system) consists of at least one star and various orbiting objects (such as asteroids, comets, moons, and planets). The term originated to describe the
planetary system around Sol, the Latin name for our
sun. The planet Earth is located within our solar
system, which is usually called simply the Solar system; others are called planetary systems to avoid
confusion. This article uses this terminology.
Solar system objects
The wide variety of objects that exist in the solar system fall into several categories. In recent years many of these
categories have been found to be less clear-cut than once thought. This encyclopedia employs the following divisions:
- The Sun is a spectral class G2
star that contains 99.86% of the system's mass.
- The planets of the solar system are those nine bodies traditionally labelled as
such: Mercury, Venus, Earth, Mars, Jupiter, Saturn, Uranus, Neptune and Pluto.
- Sizeable objects that orbit these planets are moons. For a
complete listing, see that article.
- Dust and other small particles that orbit these planets form planetary rings.
- Space debris of artificial origin that can be found in orbit around
Earth.
- Planetesimals, from which the planets were originally formed, are
sub-planetary bodies that accreted during the first years of the solar system and that no longer exist. The name is also
sometimes used to refer to asteroids and comets in general, or to asteroids below 10km in diameter.
- Asteroids are objects smaller than planets that lie roughly within the orbit of
Jupiter and are composed in significant part of nonvolatile minerals. They are subdivided into asteroid groups and asteroid families based on their specific orbital characteristics.
- Asteroid moons are asteroids that orbit larger asteroids. They are
not as clearly distinguished as planetary moons, sometimes being almost as large as their partners.
- Trojan asteroids are located in either of Jupiter's L4 or L5 points, though the term is also sometimes used
for asteroids in any other planetary Lagrange point as well.
- Meteoroids are asteroids that range in size from roughly boulder sized to
particles as small as dust.
- Comets are composed largely of volatile ices and have highly eccentric orbits,
generally having a periapsis within the orbit of the inner planets and an
apoapsis beyond Pluto. Short-period comets exist with apoapses closer than this,
however, and old comets that have had most of their volatiles driven out by solar warming are often categorized as asteroids.
Some comets with hyperbolic orbits may also originate outside the solar
system.
- Centaurs are icy comet-like bodies that have
less-eccentric orbits so that they remain in the region between Jupiter and Neptune.
- Trans-Neptunian objects, which are icy bodies whose
mean orbital radius lies beyond Neptune's. These are further subdivided:
- Kuiper belt objects have orbits lying between 30 and 50 AU. This is
thought to be the origin for short-period comets. Pluto is sometimes classified as a Kuiper belt object in addition to being a
planet, and a class of Kuiper belt objects with Pluto-like orbits are called Plutinos. The remaining Kuiper belt objects are classified as Cubewanos in the main belt and scattered disk
objects in the outer fringes.
- Oort cloud objects, currently hypothetical, have orbits lying between
50,000 and 100,000 AU. This region is thought to be the origin of long-period comets.
- The newly discovered object Sedna, with a highly
elliptical orbit extending from about 76 to 850 AU, does not obviously fit in either category, although its discoverers argue
that it should be considered a part of the Oort cloud.
- Small quantities of dust are present throughout the solar system and are responsible for the phenomenon of zodiacal light. Some of the dust is likely interstellar dust from outside the solar system.
This illustration shows the approximate sizes of the planets relative to one another and the Sun.
Origin and evolution of planetary systems
Planetary systems are generally believed to form as part of the same process which results in star formation; although, some argue that systems are formed by some kind of accidental "stellar near-collison". The more common theory argues that the
objects of a planetary system developed from a solar nebula.
Orbit of the solar system
The solar system is part of the Milky Way galaxy, a spiral galaxy with a diameter of about 100,000 light years containing
approximately 200 billion stars, of which our Sun is fairly typical.
Estimates place the solar system at between 25,000 and 28,000 light years from the galactic center. Its speed is about 220
kilometers per second, and it completes one revolution every 226 million years.
The solar system appears to have a very unusual orbit. It is both extremely close to being circular, and at nearly the exact
distance at which the orbital speed matches the speed of the compression waves that form the spiral arms. The solar system
appears to have remained between spiral arms for most of the existence of life on Earth. The radiation from supernovae in spiral arms could theoretically sterilize planetary surfaces, preventing
the formation of large animal life on land. By remaining out of the spiral arms, Earth may be unusually free to form large animal
life on its surface.
Discovery and exploration of the solar system
Because of the geocentric perspective from which humans viewed the solar system, its nature and structure were long
misperceived. The apparent motions of solar system objects as viewed from a moving Earth were believed to be their actual motions
about a stationary Earth. In addition, many solar system objects and phenomena are not directly sensible by humans without
technical aids. Thus both conceptual and technological advances were required in order for the solar system to be correctly
understood.
The first and most fundamental of these advances was the Copernican Revolution, which adopted a heliocentric model for the
motions of the planets. Indeed, the term "solar system" itself derives from this perspective. But the most
important consequences of this new perception came not from the central position of the Sun, but from the orbital position of the
Earth, which suggested that the Earth was itself a planet, and the planets other Earths. This was the first indication of the
true nature of the planets. Also, the lack of perceptible stellar parallax despite
the Earth's orbital motion indicated the extreme remoteness of the fixed stars, which prompted the speculation that they could be
objects similar to the Sun, perhaps with planets of their own.
The solar system and other planetary systems
Until recently, the solar system was the only known example of a planetary system, although it was widely believed that other
comparable systems did exist. A number of such systems have now been detected, although the information available about them is
very limited. The technique employed involves the detection through the Doppler effect of periodic variations in the motion of parent stars which is attributed to the presence of
planets. This allows the mass and orbital characteristics of the unseen planets to be determined. Unfortunately the sensitivity
of these techniques currently does not permit the detection of planets of mass and orbit comparable to the Earth.
Attributes of Major Planets
All attributes below are measured relative to the Earth:
| Planet |
Equatorial
diameter |
Mass |
Orbital
Radius |
Year |
Day |
| Mercury |
0.382 |
0.06 |
0.38 |
0.241 |
58.6 |
| Venus |
0.949 |
0.82 |
0.72 |
0.615 |
-243 |
| Earth |
1.00 |
1.00 |
1.00 |
1.00 |
1.00 |
| Mars |
0.53 |
0.11 |
1.52 |
1.88 |
1.03 |
| Jupiter |
11.2 |
318 |
5.20 |
11.86 |
0.414 |
| Saturn |
9.41 |
95 |
9.54 |
29.46 |
0.426 |
| Uranus |
3.98 |
14.6 |
19.22 |
84.01 |
0.718 |
| Neptune |
3.81 |
17.2 |
30.06 |
164.79 |
0.671 |
| Pluto* |
0.24 |
0.0017 |
39.5 |
248.5 |
6.5 |
*Soon after its discovery in 1930, Pluto was classified a planet by the International Astronomical Union. However,
based on additional discoveries since that time, some astronomers have suggested reconsideration of that decision.
Other facts
The total surface area of the solar system's objects that have solid
surfaces and diameter > 1km is ~ 1.7 × 109 km2.
([1] )
It has been suggested that the Sun may be part of a binary star system,
with a distant companion named Nemesis. Nemesis was proposed to
explain some regularities of the great extinctions of life on Earth. The theory says that Nemesis creates periodical
perturbations in the asteroids and comets of the solar system causing a shower of large bodies and some of them hit Earth causing
destruction of life. After this theory was stated, a search was undertaken for such a dim, distant companion; it found no visible
star within one light-year of the Sun.
Extension
Outer boundaries, in that order, are the termination shock,
the heliosheath, and the heliopause.
See also
External links
- Celestia free 3D realtime space-simulation (OpenGL)
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