Earth often referred
to as the Earth, Terra, the
World or
Planet Earth) is the third
planet away
from the Sun, and is
the fifth largest planet in the
solar
system. It is also the largest of its
planetary system's
terrestrial planets, making it the largest
solid body in the
solar system, and it is the only place in the
universe
known to humans
to support life. It
is also the densest planet in the solar system. Widely accepted scientific
evidence indicates that the Earth was formed around
4.57 billion years ago[1]
and its
natural satellite, the
Moon, was orbiting
it shortly thereafter, around 4.53 billion years ago.
The
outer surface is divided into several
tectonic plates that gradually migrate across the surface over
geologic time spans. The interior of the planet remains active, with a thick
layer of convecting yet solid
mantle and an iron core that generates a
magnetic field. Its
atmospheric conditions have been significantly altered by the presence of
life forms, which create an ecological balance that modifies the surface
conditions. About 71% of the surface is covered in salt-water
oceans, and the
remainder consists of continents and islands.
There is significant interaction between the Earth and its space environment.
The relatively large moon provides ocean
tides and has
gradually modified the length of the planet's rotation period. A
cometary
bombardment during the early history of the planet is believed to have played a
role in the formation of the oceans. Later,
asteroid
impacts are understood to have caused significant changes to the surface
environment. Long term
periodic changes in the orbit of the planet may also be responsible for the
ice ages that
have covered significant portions of the surface in glacial sheets.
Lexicography
In
American English usage, the name can be capitalized or spelled in lowercase
interchangeably, either when used absolutely or prefixed with "the" (i.e. Earth,
the Earth, earth or the earth). Many deliberately spell the name of the planet
with a capital, both as "Earth" or "the Earth". This is to distinguish it as a
proper noun, distinct from the senses of the term as a count noun or verb (e.g.
referring to soil, the ground,
earthing in the electrical sense, etc.).
Oxford Spelling recognizes the lowercase form as the most common, with the
capitalized form as a variant of it. Another convention that is very common is
to spell the name with a capital when occurring absolutely (e.g.
Earth's atmosphere) and lowercase when preceded by "the" (e.g. the
atmosphere of the earth). The term almost exclusively exists in lowercase when
appearing in common phrases, even without "the" preceding it (e.g. it does not
cost the earth; what on earth are you doing?).[2]
Terms that refer to the Earth can use the
Latin root terr-, as in
terraform
and
terrestrial. An alternative Latin root is tellur-, which is used in
words such as
tellurian and
tellurium.
Such terms derive from Latin terra and tellus, which refer
variously to the world, the element earth, the earth goddess and so forth[3].
Scientific terms such as
geography,
geocentric
and
geothermal use the
Greek prefix geo- (γαιο-, gaio-), from gē (again
meaning "earth").[4]
Astronauts
and sailors refer to the Earth as "Terra Firma".
The English word "earth" has
cognates in
many modern and ancient languages. Examples in modern tongues include aarde
in Afrikaans
and
Dutch, and Erde in
German. The root has cognates in extinct languages such as ertha in
Old Saxon
and ert (meaning "ground") in
Middle
Irish, derived from the
Old
English eorðe. All of these words derive from the
Proto-Indo-European base *er-.
Several
Semitic languages have words for "earth" similar to those in
Indo-European languages.
Arabic has
ard;
Akkadian, irtsitu;
Aramaic, araa;
Phoenician, erets (which appears in the
Mesha
Stele); and
Hebrew, ארץ (arets, or erets when not preceded by a definite
article, or when followed by a
noun modifier). The etymological connection between the words in
Indo-European and Semitic languages are uncertain, though, and may simply be
coincidence.
The standard name for
people from
Earth is
Earthling, although
Terran,
Gaian, and
Earther are alternate names that have been used in
Science fiction.
Words for Earth in other languages include: Terre (French),
पृथ्वी pr̥thvī (Sanskrit),
Maa (Finnish
and
Estonian), Pământ (Romanian),
Föld (Hungarian),
Ziemia (Polish),
Zemlja (Russian
and
Serbian), Zemya Земя (Bulgarian),
Tierra (Spanish),
Terra (Italian),
地球 (Mandarin,
Cantonese,
Japanese), Jigu (Korean),
Bumi (Malay),
Jorden (Danish,
Norwegian,
Swedish), כדור הארץ (Hebrew),
Bhoomi (Telugu),
Gi, Choma (Greek),
Dunia (Swahili),
Âlem, Dünya الْمَسْكُونَة (Arabic),
Dinê (Kurdish),
Ergir երկիր (Armenian),
Jehun, Zamin (Persian),
and Acun, Yeryüzü, Yerküre (Turkish).[5]
|
Orbital
characteristics |
|
Epoch J2000 |
| Aphelion
distance: |
152,097,701
km
(1.016 710 333 5
AU) |
| Perihelion distance: |
147,098,074 km
(0.983 289 891 2 AU) |
|
Semi-major axis: |
149,597,887.5 km
(1.000 000 112 4 AU) |
|
Semi-minor axis: |
149,576,999.826 km
(0.999 860 486 9 AU) |
| Orbital
circumference: |
924,375,700 km
( 6.179 069 900 7 AU) |
|
Eccentricity: |
0.016 710 219 |
| Avg.
orbital speed: |
29.783
km/s
(107,218
km/h) |
| Max.
orbital speed: |
30.287 km/s
(109,033
km/h) |
| Min.
orbital speed: |
29.291 km/s
(105,448
km/h) |
| Inclination: |
0
(7.25° to Sun's
equator) |
|
Longitude of ascending node: |
348.739 36° |
|
Argument of perihelion: |
114.207 83° |
|
Satellites: |
1 (the Moon) |
|
Physical characteristics |
| Ellipticity: |
0.003 352 9 |
| Mean radius: |
6,372.797 km |
| Equatorial
radius: |
6,378.137 km |
|
Polar radius: |
6,356.752 km |
| Aspect Ratio: |
0.996 647 1 |
| Equatorial circumference: |
40,075.02 km |
| Meridional circumference: |
40,007.86 km |
| Mean circumference: |
40,041.47 km |
|
Surface area: |
510,065,600
km² |
| Land area: |
148,939,100 km² (29.2 %) |
| Water area: |
361,126,400 km² (70.8 %) |
| Volume: |
1.083 207 3×1012
km³ |
| Mass: |
5.9742×1024
kg |
| Mean density: |
5,515.3
kg/m³ |
| Equatorial
surface gravity: |
9.780 1
m/s²
(0.997 32
g) |
|
Escape velocity: |
11.186 km/s (≅39,600 km/h) |
| Sidereal rotation period: |
0.997 258 d
(23.934 h) |
| Rotation velocity at equator: |
465.11 m/s |
| Axial
tilt: |
23.439 281° |
|
Right ascension of North pole: |
undefined° |
| Declination: |
+90° |
| Albedo: |
0.367 |
Surface
temp.:
Kelvin
Celsius |
| min |
mean |
max |
| 185 K |
287 K |
331 K |
| -88.3 °C |
14 °C |
57.7 °C |
|
| Adjectives: |
Terrestrial, Terran, Telluric, Tellurian, Earthly |
|
Atmosphere |
| Surface
pressure: |
101.3 kPa (MSL) |
| Composition: |
78.08%
Nitrogen
20.94% Oxygen
0.93% Argon
0.038%
Carbon dioxide
Trace
water vapor (varies with
climate) |
History
Based on the available evidence, current scientists have been able to
reconstruct detailed information about the planet's past. Earth formed 4.567
billion years ago out of the
solar
nebula, along with the Sun and the other planets. Initially
molten, the
outer layer of the planet cooled when water began accumulating in the atmosphere
when the planet was about half its current radius, resulting in the solid crust.
The moon formed soon afterwards, possibly as the result of the impact with a
Mars-sized object known as
Theia. Outgassing and
volcanic
activity produced the primordial atmosphere; condensing
water
vapor, augmented by ice delivered by
comets,
produced the oceans.[6]
The highly energetic chemistry is believed to have produced a self-replicating
molecule around 4 billion years ago, and half a billion years later, the
last common ancestor of all life lived.[7]
The development of
photosynthesis allowed the sun's energy to be harvested directly; the
resultant oxygen
accumulated in the atmosphere and gave rise to the
ozone
layer. The incorporation of smaller cells within larger ones resulted in the
development of complex cells called
eukaryotes.[8]
Cells within colonies became increasingly specialized, resulting in true
multicellular organisms. Aided by the absorption of harmful
ultraviolet radiation by the ozone layer, life colonized the surface of
Earth.
Over hundreds of millions of years, continents formed and broke up as the
surface of Earth continually reshaped itself. The continents have migrated
across the surface of the Earth, occasionally combining to form a
supercontinent. Roughly 750 million years ago (mya), the earliest known
supercontinent
Rodinia, began to break apart. The continents later recombined to form
Pannotia,
600–540 mya, then finally
Pangaea,
which broke apart 180 mya.[9]
Since the 1960s, it has been hypothesized that severe
glacial
action between
750 and 580 mya, during the
Neoproterozoic, covered much of the planet in a sheet of ice. This
hypothesis has been termed "Snowball
Earth", and is of particular interest because it preceded the
Cambrian explosion, when multicellular lifeforms began to proliferate.[10]
Since the
Cambrian explosion, about 535 mya, there have been five
mass extinctions.[11]
The last occurred 65 mya, when a meteorite collision probably triggered the
extinction of the (non-avian)
dinosaurs
and other large reptiles, but spared small animals such as
mammals, which
then resembled shrews. Over the past 65 million years, mammalian life has
diversified, and several mya, a small African ape gained the ability to stand
upright. This enabled tool use and encouraged communication that provided the
nutrition and stimulation needed for a larger brain. The development of
agriculture, and then civilization, allowed humans to influence the Earth in a
short timespan as no other life form had, affecting both the nature and quantity
of other life forms.
Composition and structure
Shape
The Earth's shape is very close to an
oblate spheroid,
although the precise shape (the
geoid) varies
from this by up to 100 meters (327 ft). The average diameter of the reference
spheroid is approximately 12,742 km (more roughly, 40,000 km/π).
The rotation
of the Earth causes the
equator to
bulge out slightly so that the equatorial diameter is 43 km larger than the
pole to pole diameter. The largest local deviations in the rocky surface of
the Earth are
Mount
Everest (8,850 m above local
sea level)
and the
Mariana Trench (10,924 m below local sea level). Hence compared to a perfect
ellipsoid,
the Earth has a
tolerance of about one part in about 584, or 0.17%. For comparison, this is
less than the 0.22% tolerance allowed in
billiard balls. Because of the bulge, the feature farthest from the center
of the Earth is actually
Mount Chimborazo in
Ecuador.
Chemical composition
The mass of the
Earth is approximately 5.98 ×1024 kg. It is composed mostly of
iron (35.0%),
oxygen (28.0%),
silicon
(17.0%),
magnesium (15.7%),
nickel (1.5%),
calcium
(1.4%) and
aluminium (1.4%)[12].
The commoner rock constituents of the
Earth's crust are nearly all oxides; chlorine, sulfur and fluorine are the
only important exceptions to this and their total amount in any rock is usually
much less than 1%. F. W. Clarke has calculated that a little more than 47% of
the earth's crust consists of oxygen. It occurs principally in combination as
oxides, of which the chief are silica, alumina, iron oxides, lime, magnesia,
potash and soda. The silica functions principally as an acid, forming silicates,
and all the commonest minerals of igneous rocks are of this nature. From a
computation based on 1672 analyses of all kinds of rocks, Clarke arrived at the
following as the average percentage composition: SiO2=59.71%, Al2O3=15.41%,
CaO=4.90%, MgO=4.36%, Na2O=3.55%, FeO=3.52%, K2O=2.80%, Fe2O3=2.63%,
H2O=1.52%, TiO2=0.60%, P2O5=0.22%.
These total 99.22%. All the other constituents occur only in very small
quantities.[13]
Internal structure
The interior of the Earth, like that of the other
terrestrial planets, is
chemically
divided into layers. The Earth has an outer
silicate solid
crust, a highly viscous
mantle, a liquid
outer core
that is much less viscous than the mantle, and a solid
inner core.
The geologic component layers of the Earth[14]
are at the following depths below the surface:
| Depth |
Layer |
| Kilometers |
Miles |
| 0–60 |
0–37 |
Lithosphere (locally varies between 5 and 200 km) |
| 0–35 |
0–22 |
...
Crust (locally varies between 5 and 70 km) |
| 35–60 |
22–37 |
... Uppermost part of mantle |
| 35–2890 |
22–1790 |
Mantle |
| 100–700 |
62–435 |
...
Asthenosphere |
| 2890–5100 |
1790–3160 |
Outer core |
| 5100–6378 |
3160–3954 |
Inner
core |
Tectonic plates
According to plate tectonics theory currently accepted by the vast
majority of scientists working in this area, the outermost part of the Earth's
interior is made up of two layers: the
lithosphere comprising the
crust, and the solidified uppermost part of the
mantle. Below the lithosphere lies the
asthenosphere, which comprises the inner, viscous part of the mantle. The
mantle behaves like a superheated and extremely viscous liquid.
The lithosphere essentially floats on the asthenosphere and is broken
up into what are called
tectonic plates. These plates move in relation to one another at one of
three types of plate boundaries:
convergent,
divergent, and
transform.
Earthquakes,
volcanic activity,
mountain-building,
and
oceanic trench formation occur along plate boundaries.
The main plates are
- African Plate, covering
Africa -
Continental plate
-
Antarctic Plate, covering
Antarctica
- Continental plate
-
Australian Plate, covering
Australia
(fused with
Indian
Plate between 50 and 55 million years ago) - Continental plate
-
Eurasian Plate covering
Asia and
Europe -
Continental plate
-
North American Plate covering
North
America and north-east
Siberia -
Continental plate
-
South American Plate covering
South
America - Continental plate
- Pacific Plate, covering the
Pacific Ocean - Oceanic plate
Notable minor plates include the
Indian
Plate, the
Arabian Plate, the
Caribbean Plate, the
Nazca
Plate and the
Scotia
Plate.
Surface
The Earth's
terrain varies greatly from place to place. About 70% of the surface is
covered by water, with much of the
continental shelf below sea level. If all of the land on Earth were spread
evenly, water would rise to an altitude of more than 2500 metres (approximately
8000 ft.). The remaining 30% not covered by water consists of
mountains,
deserts, plains,
plateaus,
etc.
Currently the total arable land is 13.31% of the land surface, with only 4.71%
supporting permanent crops.[15]
Close to 40% of the Earth's land surface is presently used for cropland and
pasture, or an estimated 3.3 × 109
acres of cropland
and 8.4 × 109 acres of pastureland.[16]
Extreme points
Elevation extremes: (measured relative to
sea level)
- Lowest point on land:
Dead Sea −417 m
- Lowest point overall: Challenger Deep of the
Mariana Trench in the
Pacific Ocean
−10,924 m
[17]
- Highest point:
Mount
Everest 8,844 m
(2005 est.)
Pedosphere
The pedosphere is the outermost layer of the Earth that is composed of
soil and subject to
soil
formation processes. It exists at the interface of the
lithosphere,
atmosphere,
hydrosphere and
biosphere.
Hydrosphere
The abundance of water on Earth is a unique feature that distinguishes the "Blue
Planet" from others in the solar system. Approximately 70.8 percent of the
Earth is covered by water and only 29.2 percent is terra firma.
The Earth's hydrosphere consists chiefly of the
oceans, but
technically includes all water surfaces in the world, including inland seas,
lakes, rivers, and underground waters. The average depth of the oceans is 3,794
m (12,447 ft), more than five times the average height of the continents. The
mass of the oceans is approximately 1.35 × 10^18 tonnes, or about 1/4400 of the
total mass of the Earth.
Atmosphere
The Earth's atmosphere has no definite boundary, slowly becoming thinner and
fading into outer space. Three-quarters of the atmosphere's mass is contained
within the first 11 km of the planet's surface. This lowest layer is called the
troposphere. Further up, the atmosphere is usually divided into the
stratosphere,
mesosphere,
and
thermosphere. Beyond these, the
exosphere
thins out into the
magnetosphere (where the Earth's magnetic fields interact with the
solar wind).
An important part of the atmosphere for
life
on Earth is the
ozone
layer.
The
atmospheric pressure on the surface of the Earth averages 101.325 kPa,
with a
scale height of about 6 km. It is 78%
nitrogen
and 21% oxygen,
with trace amounts of other gaseous molecules such as water vapor. The
atmosphere protects the Earth's life forms by absorbing
ultraviolet
solar radiation, moderating temperature, transporting water vapor, and
providing useful gases. The atmosphere is one of the principal components in
determining
weather and
climate.
Because
hydrogen gas is light and based on Earth's mean temperature, achieves
escape velocity, unfixed hydrogen leaves the Earth. For this reason, the
Earth's environment is
oxidizing,
with consequences for the
chemical
nature of life
which developed on the planet.
Climate
The most prominent features of the Earth's climate are its two large polar
regions, two narrow
temperate
zones, and a wide
equatorial
tropical region.
Precipitation patterns vary widely, ranging from several metres of water per
year to less than a millimetre.
Ocean currents are important factors in determining climate, particularly the
spectacular
thermohaline circulation which distributes heat energy from the equatorial
oceans to the polar regions.
Biosphere
The planet's lifeforms are sometimes said to form a "biosphere".
This biosphere is generally believed to have begun
evolving
about 3.5 billion (3.5×109) years ago. Earth is the only place in the
universe officially recognized by the communities of Earth where life is
absolutely known to exist, and some scientists believe that
biospheres might be rare.
The biosphere is divided into a number of
biomes, inhabited
by broadly similar
flora and
fauna. On land primarily
latitude
and height above the sea level separates biomes. Terrestrial biomes lying within
the
Arctic,
Antarctic Circle or in high altitudes are relatively barren of
plant and
animal life,
while most of the more populous biomes lie near the
Equator.
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 bodies form concentrated sources for many
metals and other
useful
elements.
- Earth's
biosphere produces many useful biological products for humans, 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 near
the surface by human
civilization has become a subject of significant controversy in modern
environmentalism movements.
Land use
Humans use
the Earth's
land to support themselves through the production of
food,
energy, and
building material. They also live on the land by building
shelters. Human
use of land is approximately:
- Arable land: 13.13%[15]
- Permanent crops: 4.71%[15]
- Permanent pastures: 26%
- Forests and woodland: 32%
- Urban areas: 1.5%
- Other: 30% (1993 est.)
Irrigated land: 2,481,250 km² (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,
blizzards, floods,
droughts, and
other calamities and
disasters.
Many localize areas are subject to human-made
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 from enhancement of the
greenhouse effect caused by the earth itself and human industrial
carbon dioxide emissions is an increasing concern, the focus of intense
study and debate.
Human geography
Earth has approximately 6,600,000,000 human inhabitants.[18][19]
Projections indicate that the
world's human population will reach seven billion in 2013 and 9.1 billion in
2050 (2005
UN
estimates). Most of the growth is expected to take place in
developing nations. Human
population density varies widely around the world.
It is estimated that only one eighth of the surface of the Earth is suitable
for humans to
live on — three-quarters is covered by
oceans, and half
of the land area is
desert, high
mountains
or other unsuitable terrain.
The northernmost permanent settlement in the world is
Alert, on
Ellesmere Island in
Nunavut,
Canada. The
southernmost is the
Amundsen-Scott South Pole Station, in
Antarctica,
almost exactly at the
South Pole.
There are 267 administrative divisions, including nations, dependent areas,
other, and miscellaneous entries. Earth does not have a
sovereign government
with planet-wide authority. Independent sovereign
nations claim
all of the land surface except for some segments of
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.
In total, about 400 people have been outside the Earth's atmosphere as of
2004, and of these, twelve have walked on the
Moon. Most of the
time the only humans in space are those on the
International Space Station, currently three people who are usually replaced
every 6 months. See
human spaceflight.
Solar system
It takes the Earth, on average, 23 hours, 56 minutes and 4.091 seconds (one
sidereal day) to rotate around the
axis that connects the
north
and the
south poles. From Earth, the main apparent motion of celestial bodies in the
sky (except that of
meteors within the atmosphere and low-orbiting satellites) is to the west at
a rate of 15 °/h = 15'/min, i.e., an apparent Sun or Moon diameter every two
minutes.
Earth orbits the Sun at an average distance of about 150 million kilometers
(93.2 million miles) every 365.2564 mean solar days (1
sidereal year). From Earth, this gives an apparent movement of the Sun with
respect to the stars at a rate of about 1 °/day, i.e., a Sun or Moon diameter
every 12 hours, eastward. The orbital speed of the Earth averages about 30 km/s
(108,000 km/h), which is enough to cover the planet's diameter (~12,600 km) in
seven minutes, and the distance to the Moon (384,000 km) in four hours.
The Moon
revolves with the Earth around a common
barycenter,
from fixed star to fixed star, every 27.32 days. When combined with the
Earth–Moon system's common revolution around the Sun, the period of the
synodic month, from new moon to new moon, is 29.53 days. The
Hill
sphere (gravitational
sphere of influence) of the Earth is about 1.5 Gm (930,000 miles) in radius.
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
(without a tilt, there would be an eclipse every two weeks, alternating between
lunar
eclipses and
solar
eclipses).
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 Earth's equatorial bulge because of its
oblateness. In a reference frame attached to the solid body of the Earth, its
rotation is also slightly irregular from
polar
motion. The polar motion is quasi-periodic, containing an annual component
and a component with a 14-month period called the
Chandler wobble. In addition, the rotational velocity varies, in a
phenomenon known as
length of day variation.
In modern times, Earth's
perihelion
occurs around
January 3, and the
aphelion
around July 4
(near the
solstices, which are on about
December
21 and June
21). For other eras, see
precession
and
Milankovitch cycles.
Phases
From
space, the Earth can be seen to go through phases similar to the phases of
the
Moon and Venus. This appearance is caused by light that reflects off the
Earth as it moves around the
Sun. The phases seen
depend upon the observer's location in space. The phases of the Earth can be
simulated by shining light on a globe of the Earth.
From orbit around the Earth, one can see all of the phases of the Earth in
progression from New Earth to New Earth. The speed at which one sees these
phases is related to the orbit of the observer and the speed of the observer
around the Earth.
A Martian observer can see the Earth go through phases similar to those that
an Earth-bound observer sees the
phases of Venus (as discovered be
Galileo),
going for the Martian's perspective from New Earth to Fat Crescent to wane to
New Earth. It is can be shown that an imaginary observer on the
Sun would not see the
Earth going through phases. The sun observer would only be able to see the lit
side of the earth.
Magnetic field
The
Earth's magnetic field is shaped roughly as a
magnetic dipole, with the poles currently located proximate to the planet's
geographic poles. The field forms the
magnetosphere, which deflects particles in the
solar wind.
The bow shock
is located about at 13.5 RE. The collision between the magnetic field
and the solar wind forms the
Van Allen radiation belts, a pair of concentric,
torus-shaped
regions of energetic
charged particles. When the
plasma enters the Earth's atmosphere at the magnetic poles, it forms the
aurora.
Moon
| Name |
Diameter (km) |
Mass (kg) |
Semi-major axis (km) |
Orbital period |
| Moon |
3,474.8 |
7.349×1022 |
384,400 |
27 days, 7 hours, 43.7 minutes |
The Moon, sometimes called 'Luna', is a relatively large, terrestrial,
planet-like satellite, with a diameter about one-quarter of the Earth's. It is
the largest moon in the solar system relative to the size of its planet. (Charon
is larger relative to
dwarf
planet Pluto.)
The
natural satellites orbiting other planets are called "moons", after Earth's
Moon.
The gravitational attraction between the Earth and Moon cause
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.
Because of their
tidal interaction, the Moon recedes from Earth at the rate of approximately
38 mm a
year. Over millions of years, these tiny modifications—and the lengthening of
Earth's day by about 17
µs a
year—add up to significant changes. During the
Devonian
period, there were 400 days in a year, with each day lasting 21.8 hours.
The Moon may dramatically affect the development of life by taming the
weather. Paleontological evidence and computer simulations show that Earth's
axial tilt
is stabilized by tidal interactions with the Moon.[20]
Some theorists believe that without this stabilization against the
torques applied
by the Sun and planets to the Earth's equatorial bulge, the rotational axis
might be chaotically unstable, as it appears to be for
Mars. If Earth's axis of rotation were to approach the
plane of the
ecliptic, extremely severe weather could result from the resulting extreme
seasonal differences. 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.[21]
However, this is a controversial subject, and further studies of Mars—which
shares Earth's
rotation period and
axial tilt,
but not its large moon or liquid core—may settle the matter.
Viewed from Earth, the Moon is just far enough away to have very nearly the
same apparent angular size as the Sun (the Sun is 400 times larger, and the Moon
is 400 times closer). This allows total
eclipses and annular eclipses to occur on Earth.
The most widely accepted theory of the Moon's origin, the
giant impact theory, states that it was formed from the collision of a
Mars-size
protoplanet with the early Earth. This hypothesis explains (among other
things) the Moon's relative lack of iron and volatile elements, and the fact
that its composition is nearly identical to that of the Earth's crust.
Earth has at least two
co-orbital satellites, the
asteroids 3753
Cruithne and
2002 AA29.
Descriptions
Earth has often been personified as a
deity, in
particular a
goddess (see
Gaia and
Mother
Earth). The
Chinese Earth goddess
Hou-Tu is similar to Gaia, the deification of the Earth. As the patroness of
fertility, her element is Earth. In
Norse mythology, the Earth goddess
Jord was the mother
of Thor and the
daughter of Annar.
Ancient Egyptian mythology is different from that of other cultures because
Earth is male, Geb,
and sky is female,
Nut (goddess).
Although commonly thought to be a sphere, the Earth is actually an
oblate spheroid. It bulges slightly at the equator and is slightly flattened
at the poles. In the past there were varying levels of belief in a
flat Earth,
but ancient
Greek philosophers and, in the
Middle
Ages, thinkers such as
Thomas Aquinas believed that
it was spherical. A 19th-century organization called the
Flat Earth Society advocated the even-then discredited idea that the Earth
was actually disc-shaped,
with the
North Pole at its center and a 150
foot (50 m)
high wall of ice at the outer edge. It and similar organizations continued to
promote this idea, based on religious beliefs and
conspiracy theories, through the 1970s. Today, the subject is more
frequently treated
tongue-in-cheek or with mockery.
Prior to the introduction of
space
flight, these inaccurate beliefs were countered with deductions based on
observations of the secondary effects of the Earth's shape and parallels drawn
with the shape of other planets.
Cartography, the study and practice of map making, and vicariously
geography,
have historically been the disciplines devoted to depicting the Earth.
Surveying,
the determination of locations and distances, to a lesser extent
navigation,
the determination of position and direction, have developed alongside
cartography and geography, providing and suitably quantifying the requisite
information.
The technological developments of the latter half of the 20th century are
widely considered to have altered the public's perception of the Earth. Before
space flight, the popular image of Earth was of a green world.
Science fiction artist
Frank
R. Paul provided perhaps the first image of a cloudless blue planet
(with sharply defined land masses) on the back cover of the July 1940 issue of
Amazing Stories, a common depiction for several decades thereafter.[22]
Apollo 17's
1972 "Blue
Marble" photograph of Earth from
cislunar space became the current iconic image of the planet as a marble of
cloud-swirled blue ocean broken by green-brown continents. A photo taken of a
distant Earth by
Voyager 1
in 1990 inspired
Carl Sagan
to describe the planet as a "Pale
Blue Dot."[23]
Earth has also been described as a massive
spaceship,
with a
life support system that requires maintenance, or as having a
biosphere
that forms one large
organism.
See
Spaceship Earth and
Gaia
theory.
Future
The future of the planet is closely tied to that of the
Sun. The
luminosity of the Sun will continue to steadily increase, growing from the
current luminosity by 10% in 1.1 billion years (1.1 Gyr)
and up to 40% in 3.5 Gyr.[24]
Climate models indicate that the increase in radiation reaching the Earth is
likely to have dire consequences, including possible loss of the oceans.[25]
The Sun, as part of its solar lifespan, will expand to a
red
giant in 5 Gyr. Models predict that the Sun will expand out to about 99% of
the distance to the Earth's present orbit (1
astronomical unit, or AU). However, by that time, the orbit of the Earth may
have expanded to about 1.7
AUs because of the diminished mass of the Sun. The planet might thus escape
envelopment.[24]
The increased heat will accelerate the inorganic CO2 cycle,
reducing its concentration to the lethal dose for plants (10 ppm for C4
photosynthesis) in 900 million years. But even if the Sun were eternal and
stable, the continued internal cooling of the Earth would have resulted in a
loss of much of its atmosphere and oceans (due to lower
volcanism).[26]
More specifically, for Earth's oceans, the lower temperatures in the crust will
permit their water to leak more deeply than today (at certain depth the water is
evaporating) resulting in their total disappearance in 1 billion years.
However, it might be possible to move the Earth's orbit outwards, and thus it
would not suffer a runaway greenhouse effect.[27]
