Earth, also known as
the Earth or
Terra, is the third planet outward from the
Sun. It is the largest of the
solar systems terrestrial planets, and the only planetary body that modern science confirms as harboring life. The planet formed around 4.57 billion (4.57×109) years ago and shortly thereafter acquired its single natural satellite, the Moon. Its dominant sentient species is the human ('Homo sapiens sapiens'').
Its symbol consists of a circled cross, representing a
meridian and the
equator; a variant puts the cross atop the circle (
Unicode: ⊕ or ♁).
Physical characteristics
Shape
The Earth is approximately a slightly
oblate spheroid, with an average diameter of approximately 12,742 km. The maximum deviations from this are the highest point on Earth (the summit of
Mount Everest, which is only 8,850 m) and the lowest (the bottom of the
Mariana Trench, at 10,911 m below sea level). Thus the Earth is an oblate spheroid within a
tolerance of one part in about 584, or 0.17 %. The mass of the Earth is approximately 6,000 yottagrams (6 x 10
24 kg).
Structure
The interior of Earth, like that of the other terrestrial planets, is chemically divided into an outer
siliceous solid
crust, a highly viscous
mantle, a liquid outer core that is much less viscous than the mantle, and a solid inner core. The liquid outer core gives rise to a weak
magnetic field due to the convection of its electrically conductive material.
New material constantly finds its way to the surface through volcanoes and cracks in the ocean floors (see
seafloor spreading). Much of Earth's crust is less than 100 million (1×10
8) years old; the very oldest parts of the crust are as much as 4.4 billion (4.4×10
9) years old
http://spaceflightnow.com/news/n0101/14earthwater/.
Taken as a whole, the Earth's composition by mass
http://earthref.org/cgi-bin/er.cgi?s=erda.cgi?n=547 is:
-
Interior
Interior heat
The interior of Earth reaches temperatures of 5270
kelvins. The planet's internal heat was originally generated during its accretion (see
gravitational binding energy), and since then additional heat has continued to be generated by the decay of radioactive elements such as
uranium,
thorium, and
potassium. The heat flow from the interior to the surface is only 1/20,000 as great as the energy received from the Sun.
Structure
Earth's composition (by depth below surface):
- 0 to 60 km - Lithosphere (locally varies 5-200 km)
- *0 to 35 km - Crust (locally varies 5-70 km)
- 35 to 2890 km - Mantle
- *100 to 700 km - Asthenosphere
- 2890 to 5100 km - Outer Core
- 5100 to 6378 km - Inner Core
The core
The average density of Earth is 5515
kg/
m3, making it the densest planet in the Solar system. Since the average density of surface material is only around 3000 kg/m
3, we must conclude that denser materials exist within the core of the Earth. In its earliest stages, about 4.5 billion (4.5×10
9) years ago, melting would have caused denser substances to sink towards the center in a process called
planetary differentiation, while less dense materials would have migrated to the crust. As a result, the core is largely composed of iron (80%), along with nickel and silicon; while other dense elements, such as lead and uranium, are either too rare to be significant or tend to bind to lighter elements and thus remain in the crust (see:
felsic materials).
The core is divided into two parts, a solid inner core with a
radius of ~1250 km and a liquid outer core extending beyond it to a radius of ~3500 km. The inner core is generally believed to be solid and composed primarily of iron and some nickel. Some have argued that the inner core may be in the form of a single iron
crystal. The outer core surrounds the inner core and is believed to be composed of liquid iron mixed with liquid nickel and trace amounts of lighter elements. It is generally believed that convection in the outer core, combined with stirring caused by the Earth's rotation (see: Coriolis forces), gives rise to the
Earth's magnetic field through a process described by the
dynamo theory. The solid inner core is too hot to hold a permanent magnetic field (see: Curie temperature) but probably acts to stabilise the magnetic field generated by the liquid outer core.
Recent evidence has suggested that the inner core of Earth may rotate slightly faster than the rest of the planet, by ~2° per
year (''Comins DEU-p.82'').
Earth cutaway from core to exosphere. Partially to scale.
Mantle
Earth's mantle extends to a depth of 2890 km. The
pressure, at the bottom of the mantle, is ~140 G
Pa (1.4 M
atm). It is largely composed of substances rich in iron and magnesium. The melting point of a substance depends on the pressure it is under. As there is intense and increasing pressure as one travels deeper into the mantle, the lower part of this region is thought solid while the upper mantle is
plastic (semi-molten). The
viscosity of the upper mantle ranges between 10
21 and 10
24 Pa·s, depending on depth
http://www2.uni-jena.de/chemie/geowiss/geodyn/poster2.html. Thus, the upper mantle can only flow very slowly.
Why is the inner core thought solid, the outer core thought liquid, and the mantle solid/plastic? The melting points of iron-rich substances are higher than pure iron. The core is composed almost entirely of pure iron, while iron rich substances are more common outside the core. So, surface iron-substances are solid, upper mantle iron-substances are semi-molten (as it is hot and they are under relatively little pressure), lower mantle iron-substances are solid (as they are under tremendous pressure), outer core pure iron is liquid as it has a very low melting point (despite enormous pressure), and the inner core is solid due to the overwhelming pressure found at the center of the planet.
Crust
The crust ranges from 5 to 70 km in depth. The thin parts are
oceanic crust composed of dense (
mafic) iron magnesium
silicate rocks and underlie the ocean basins. The thicker crust is
continental crust which is less dense and composed of (
felsic)
sodium potassium
aluminium silicate rocks. The crust-mantle boundary occurs as two physically different events. Firstly, there is a discontinuity in the
seismic velocity which is known as the
Mohorovičić discontinuity or Moho. The cause of the Moho is thought to be a change in rock composition from rocks containing
plagioclase feldspar (above) to rocks that contain no feldspars (below). The second event is a
chemical discontinuity between
ultramafic cumulates and tectonized
harzburgites which has been observed from deep parts of the oceanic crust that have been
obducted into the continental crust and preseved as
ophiolite sequences.
Biosphere
Earth is the only place where life is known to exist. The planet's lifeforms are sometimes said to form a "
biosphere". This biosphere is generally believed to have begun
evolving about 3.5 billion (3.5×10
9) years ago. The biosphere is divided into a number of
biomes, inhabited by broadly similar
flora and
fauna. On land, biomes are separated primarily by
latitude. Terrestrial biomes lying within the
Arctic and
Antarctic Circles are relatively barren of
plant and
animal life, while most of the more populous biomes lie near the
Equator.
Atmosphere
Earth has a relatively thick atmosphere composed of 78%
nitrogen, 21%
oxygen, and 1%
argon, plus traces of other gases including
carbon dioxide and
water vapor. The atmosphere acts as a buffer between Earth and the Sun. The Earth's atmospheric composition is unstable and is maintained by the biosphere. Namely, the large amount of free diatomic oxygen is maintained through solar energy by the Earth's
plants, and without the plants supplying it, the oxygen in the atmosphere will over geological timescales combine with material from the surface of the Earth. Free oxygen in the atmosphere is a signature of life.
The layers,
troposphere,
stratosphere,
mesosphere,
thermosphere, and the
exosphere, vary around the globe and in response to seasonal changes.
The total mass of the atmosphere is about 5.1 × 10
18 kg, ca. 0.9
ppm of the Earth's total mass.
Hydrosphere
A [[plate carrée projection of a composite satellite image of Earth]]
Earth is the only planet in our
solar system whose surface has liquid
water. Water covers 71% of Earth's surface (97% of it being sea water and 3% fresh water
http://earthobservatory.nasa.gov/Library/Water/) and divides it into five oceans and seven
continents. Earth's solar orbit, vulcanism,
gravity,
greenhouse effect,
magnetic field and oxygen-rich atmosphere seem to combine to make Earth a water planet.
Earth is actually beyond the outer edge of the orbits which would be warm enough to form liquid water. Without some form of a
greenhouse effect, Earth's water would freeze.
Paleontological evidence indicates that at one point after blue-green bacteria (
Cyanobacteria) had colonized the oceans, the greenhouse effect failed, and Earth's oceans may have completely frozen over for 10 to 100 million years in what is called a
snowball Earth event.
On other planets, such as
Venus, gaseous water is destroyed (cracked) by solar
ultraviolet radiation, and the
hydrogen is
ionized and blown away by the
solar wind. This effect is slow, but inexorable. This is one hypothesis explaining why Venus has no water. Without hydrogen, the oxygen interacts with the surface and is bound up in solid
minerals.
In the Earth's atmosphere, a tenuous layer of
ozone within the stratosphere absorbs most of this energetic ultraviolet radiation high in the atmosphere, reducing the cracking effect. The ozone, too, can only be produced in an atmosphere with a large amount of free diatomic oxygen, and so also is dependent on the biosphere (
plants). The
magnetosphere also shields the
ionosphere from direct scouring by the solar wind.
Finally,
vulcanism continuously emits water
vapor from the interior. Earth's
plate tectonics recycle
carbon and water as
limestone rocks are
subducted into the mantle and volcanically released as gaseous carbon dioxide and
steam. It is estimated that the minerals in the mantle may contain as much as 10 times the water as in all of the current oceans, though most of this trapped water will never be released.
The total mass of the hydrosphere is about 1.4 × 10
21 kg, ca. 0.023 % of the Earth's total mass.
Earth in the Solar System
It takes Earth 23 hours, 56 minutes and 4.091 seconds (
1 sidereal day) to rotate around the axis connecting the
north pole and the
south pole. Thus from Earth the main apparent motion of celestial bodies in the sky (except
meteors which are within the atmosphere and low orbiting satellites) is the movement to the west at a rate of 15 °/h = 15'/min, i.e. a Sun or Moon diameter every two minutes.
Earth orbits the Sun every 365.2564 mean solar days (
1 sidereal year). Thus from Earth this gives an apparent movement of the Sun with respect to the stars at a rate of ca. 1 °/day, i.e. a Sun or Moon diameter every 12 hours eastward.
The orbital speed of the Earth averages about 30 km/s, which is enough to cover one Earth diameter (~12,700 km) in 7 minutes, and one distance to the Moon (384,000 km) in 4 hours.
Earth has one
natural satellite, the
Moon, which orbits around Earth every
27 1/3 days. Thus from Earth this gives an apparent movement of the Moon with respect to the Sun and the stars at a rate of roughly 12 °/day, i.e. a Moon diameter every hour eastward.
Viewed from Earth's north pole, the motion of Earth, its moon and their axial rotations are all counterclockwise.
The orbital and axial planes are not precisely aligned: Earth's
axis is tilted some 23.5 degrees against the Earth-Sun plane (which causes the
seasons), and the Earth-Moon plane is tilted about 5 degrees against the Earth-Sun plane (otherwise there would be an eclipse every month).
The
Hill sphere (sphere of influence) of the Earth is about 1.5 Gm (930 thousand miles) in radius, within which one natural satellite (the
Moon) comfortably orbits.
In an inertial reference frame, the Earth's axis undergoes a slow
precessional motion with a period of some 25,800 years, as well as a
nutation with a main period of 18.6 years. These motions are caused by the differential attraction of Sun and Moon on the equatorial bulge due to the Earth's oblateness. In a reference frame attached to the solid body of the Earth, its rotation is also slightly irregular due to
polar motion. The polar motion is quasi-periodic, containing an annual component and a component with a 14 month period called the
Chandler wobble. Also the rotational velocity varies, a phenomenon known as
length of day variation.
The Moon
Luna, or simply
the Moon, is a relatively large terrestrial planet-like satellite, about one quarter of Earth's diameter. The
natural satellites orbiting other planets are called "moons", after Earth's Moon.
The gravitational attraction between the Earth and Moon cause the tides on Earth. The same effect on the Moon has led to its
tidal locking: its rotation period is the same as the time it takes to orbit the Earth. As a result it always presents the same face to the planet.
As the Moon orbits Earth, different parts of its face are illuminated by the Sun, leading to the
lunar phases: the dark part of the face is separated from the light part by the
solar terminator.
The Moon may enable life by moderating the weather. Paleontological evidence and computer simulations show that Earth's
axial tilt is stabilised by tidal interactions with the Moon. Without this stabilization against the
torques applied by the Sun and planets to the Earth's equatorial bulge, some theorists believe that the rotational axis might be chaotically unstable, as it appears to be with Mars. If Earth's axis of rotation were to approach the
plane of the ecliptic, extremely severe
weather could result as this would make seaonal differences extreme. One pole would be pointed directly toward the Sun during
summer and directly away during
winter.
Planetary scientists who have studied the effect claim that this might kill all large animal and higher plant life. This remains a controversial subject, however, and further studies of Mars —which shares Earth's
rotation period and
axial tilt, but not its large moon or liquid core— may provide additional information.
The Moon is just far enough away to have, when seen from Earth, very nearly the same apparent angular size as the Sun (the Sun is 400 times larger, but the Moon is 400 times closer). This allows total
eclipses as well as annular eclipses to occur on Earth. Here is a diagram showing the relative sizes of the Earth and the Moon and the distance between the two (click to enlarge):
Earth and Moon to scale (click to enlarge)
The Moon's origin is unknown, but one popular hypothesis states that it was formed from the collision of a Mars-sized
protoplanet with the early Earth. This hypothesis explains (among other things) the Moon's relative lack of iron and volatile elements. See
Giant impact theory.
Earth also has at least one known co-orbital
asteroid,
3753 Cruithne.
Geography
Medium) (Large 2 MB)]]
Map references:
Time Zones, Coordinates.
Biggest geographic subdivision
Continents,
Oceans
Area:
- total: 510.073 million km2
- land: 148.94 million km2
- water: 361.132 million km2
- note: 70.8 % of the world's surface is covered by water, 29.2 % is exposed land
Land boundaries:
the land boundaries in the world total 251,480 km (not counting shared boundaries twice)
Coastline:
356,000 km
Maritime claims: see
United Nations Convention on the Law of the Sea
- contiguous zone: 24 nautical miles (44.4 km) claimed by most, but can vary
- continental shelf: 200 m depth claimed by most or to depth of exploitation; others claim 200 nautical miles (370.4 km) or to the edge of the continental margin
- exclusive fishing zone: 200 nautical miles (370.4 km) claimed by most, but can vary
- exclusive economic zone: 200 nautical miles (370.4 km) claimed by most, but can vary
- territorial sea: 12 nautical miles (22.2 km) claimed by most, but can vary
- Note: boundary situations with neighboring states prevent many countries from extending their fishing or economic zones to a full 200 nautical miles (370.4 km)
- 43 nations and other areas are completely landlocked (see list of landlocked countries)
Climate
Two large areas of polar
climates separated by two rather narrow
temperate zones from a wide
equatorial band of tropical to
subtropical climates.
Precipitation patterns vary widely, ranging from several metres of water per year to less than a millimetre.
Terrain
Elevation extremes: (measured relative to
sea level)
Natural resources
- Earth's crust contains large deposits of fossil fuels: (coal, petroleum, natural gas, methane clathrate). These deposits are used by humans both for energy production and as feedstock for chemical production.
- Mineral ore bodies have been formed in Earth's crust by the action of erosion and plate tectonics. These ore bodies form concentrated sources for many metals and other useful elements.
- Earth's biosphere produces many useful biological products, including (but far from limited to) food, wood, pharmaceuticals, oxygen, and the recycling of many organic wastes. The land-based ecosystem depends upon topsoil and fresh water, and the oceanic ecosystem depends upon dissolved nutrients washed down from the land.
Some of these resources, such as
mineral fuels, are difficult to replenish on a short time scale, called non-renewable resources. The exploitation of non-renewable resources by human
civilization has become a subject of significant controversy in modern
environmentalism movements.
Land use
- arable land: 10 %
- permanent crops: 1 %
- permanent pastures: 26 %
- forests and woodland: 32 %
- urban areas: 1.5 %
- other: 30 % (1993 est.)
Irrigated land:
2,481,250 km
2 (1993 est.)
Natural and environmental hazards
Large areas are subject to extreme
weather such as (tropical
cyclones), hurricanes, or typhoons that dominate life in those areas. Many places are subject to
earthquakes,
landslides,
tsunamis,
volcanic eruptions,
tornadoes,
sinkholes,
floods,
droughts, and other calamities and
disasters.
Large areas are subject to
overpopulation, industrial disasters such as
pollution of the air and water,
acid rain and toxic substances, loss of vegetation (
overgrazing,
deforestation,
desertification), loss of
wildlife,
species extinction,
soil degradation, soil depletion,
erosion, and introduction of
invasive species.
Long term
climate alteration due to enhancement of the
greenhouse effect by human industrial
carbon dioxide emissions is an increasing concern, the focus of intense study and debate.
Human population
Earth at night, composite of pictures taken between October 1994 and March 1995.
On
February 25, 2005 the United Nations Population Division issued revised estimates and projected that the world's population will reach 7 billion by 2013 and swell to 9.1 billion in 2050. Most of the growth is expected to take place in developing nations.
Nearly all
humans currently reside on Earth: 6,411,000,000 inhabitants (
January 5 2005 est.)
Two humans are presently in orbit around Earth on board the
International Space Station. The station crew is replaced with new personnel every six months. During the exchange there are more, and sometimes others are also traveling briefly above the atmosphere.
In total, about 400
people have been outside Earth (in space) as of 2004. Most of them have reported a heightened understanding of its value and importance, reverence for human life and amazement at its beauty, not usually achieved by those living on the surface.
See also
space colonization.
The northernmost settlement in the world is
Alert,
Ellesmere Island,
Canada. The southernmost is the
Amundsen-Scott South Pole Station, in
Antarctica, almost exactly at the
South Pole.
Age structure:
- 0 to 14 years: 1,819,000,000 (29.9 %)
- *male: 932,800,000 (15.4 %)
- *female: 886,000,000 (14.6 %)
- 15 to 64 years: 3,841,000,000 (63.2 %)
- *male: 1,942,000,000 (32.0 %)
- *female: 1,898,000,000 (31.2 %)
- 65 years and over: 419,100,000 (6.9 %)
- *male: 184,100,000 (3.0 %)
- *female: 235,000,000 (3.9 %) (2000 est.)
Population growth rate:
1.14% (2004 est.); 73 mln/year (200,000/day); 1 in 32,000 per day
Birth rate:
22 births/1,000 population (2000 est.); 140 mln/year; 1 in 17,000 per day
Death rate:
9 deaths/1,000 population (2000 est.); 60 mln/year; 1 in 41,000 per day
Sex ratio:
- at birth: 1.05 male(s)/female
- under 15 years: 1.05 male(s)/female
- 15 to 64 years: 1.02 male(s)/female
- 65 years and over: 0.78 male(s)/female
- total population: 1.01 male(s)/female (2000 est.)
Infant mortality rate:
54 deaths/1,000 live births (2000 est.)
Life expectancy at birth:
- total population: 64 years
- male: 62 years
- female: 65 years (2000 est.)
Total fertility rate:
2.8 children born/woman (2000 est.)
Government
Earth does not have a
sovereign government with planetwide authority. Independent sovereign
nations claim all of the land surface except
Antarctica. There is a worldwide general
international organization, the
United Nations. The United Nations is primarily an international discussion forum with only limited ability to pass and enforce
laws.
Administrative divisions:
267 nations, dependent areas, other, and miscellaneous entries
Descriptions of Earth
Earth has often been personified as a
deity, in particular a
goddess. See
Gaia and
Mother Earth. The chinese earth goddess Hu-Tu, is similar to gaia, the deification of the earth. The patroness of fertility, element is earth.
In
Norse mythology, the earth goddess
Jord was the mother of
Thor and the daughter of
Annar.
Earth has also been described as a massive spaceship, with a
life support system that requires maintenance. See
Spaceship Earth.
Since Earth is rather large, it is not immediately obvious to the naked eye viewing from the surface that it is an oblate spheroid, bulging slightly at the equator and slightly flattened at the poles. In the past there were varying levels of belief in a
flat Earth because of this. Prior to the introduction of space flight, this belief was countered with deductions based on observations of the secondary effects of the earth's shape and parallels drawn with the shape of other planets.
A photo taken of Earth by
Voyager 1 inspired
Carl Sagan to describe the planet as a "
Pale Blue Dot".
In
science fiction, Earth is frequently the
capital or a major administrative center of a hypothetical galactic
government (especially when that galactic government is postulated to be
human-dominated), often a representative
federal republic, though
empires and
dictatorships are definitely not unseen. Notable examples include
Star Trek and
Babylon 5. However, in other science fiction, people in the future no longer know what planet they originally came from (for example,
Battlestar Galactica and
The Foundation Series).
The Hitchhiker's Guide to the Galaxy, a book series by
Douglas Adams, describes Earth as "Harmless" but the statement is revised in the book and later described as "
Mostly Harmless". In the same series, Earth is said to be a supercomputer built by highly advanced pan-dimensional beings (
Mice) to find out what the question that The Ultimate Answer to Life, the Universe, and Everything answers actually is.
See also
References
External links
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