Venus (IPA:
/ˈviːnəs/) is the
second-closest
planet to the Sun,
orbiting it every 224.7 Earth days. It is the brightest object in the night sky,
except for the Moon,
reaching an
apparent magnitude of −4.6. Because Venus is an
inferior planet, from
Earth it never
appears to venture far from the Sun, and its
elongation
reaches a maximum of 47.8°. Venus reaches its maximum brightness shortly before
sunrise or shortly after sunset, and is often referred to as the Morning Star
or as the Evening Star.
A
terrestrial planet, it is sometimes called Earth's "sister planet", as the
two are similar in size, gravity, and bulk composition. The planet is covered
with an opaque layer of highly reflective
clouds,
preventing its surface from being seen from space in
visible light, and which made it a subject of great speculation until some
of its secrets were revealed by
planetary science in the twentieth century. Venus has the densest
atmosphere
of the terrestrial planets, consisting mostly of
carbon dioxide, and the
atmospheric pressure at the planet's surface is 90 times that of the Earth.
Venus' surface has been mapped in detail only in the last 20 years. It shows
evidence of extensive
volcanism,
and some of its volcanoes may still be active today. In contrast to the constant
crustal movement seen on Earth, Venus is thought to undergo periodic episodes of
plate tectonics, in which the crust is
subducted
rapidly within a few million years separated by stable periods of a few hundred
million years.
The planet is named after
Venus, the
Roman goddess of
love, and most of its surface features are named after famous and
mythological women. The adjective Venusian is commonly used for items
related to Venus, though the
Latin adjective
is the rarely used Venerean; the now-archaic
Cytherean
is still occasionally encountered. Venus is the only planet in the
Solar
System named after a female figure.
Structure
Venus is one of the four
terrestrial planets, meaning that, like the Earth, it is a rocky body. In
size and mass, it is very similar to the Earth, and is often described as its
'twin'. The diameter of Venus is only 650 km less than the Earth's, and its mass
is 81.5% of the Earth's. However, conditions on the Venusian surface differ
radically from those on Earth, due to its dense
carbon dioxide atmosphere.
Internal structure
Though there is little direct information about its internal structure, the
similarity in size and density between Venus and Earth suggests that it has a
similar internal structure: a
core,
mantle, and
crust. Like that of Earth, the Venusian core is at least partially liquid.
The slightly smaller size of Venus suggests that pressures are significantly
lower in its deep interior than Earth. The principal difference between the two
planets is the lack of
plate tectonics on Venus, likely due to the dry surface and mantle. This
results in reduced heat loss from the planet, preventing it from cooling and
providing a likely explanation for its lack of an internally generated
magnetic field.[1]
Geography
About 80% of Venus' surface consists of smooth volcanic plains. Two highland
'continents' make up the rest of its surface area, one lying in the planet's
northern hemisphere and the other just south of the equator. The northern
continent is called
Ishtar Terra, after
Ishtar, the
Babylonian
goddess of love, and is about the size of
Australia.
Maxwell Montes, the highest mountain on Venus, lies on Ishtar Terra. Its
peak lies 11 km above Venus' average surface elevation; in contrast, Earth's
highest mountain,
Mount
Everest, rises to just under 9 km above
sea level.
The southern continent is called
Aphrodite Terra, after the Greek goddess of love, and is the larger of the
two highland regions at roughly the size of
South
America. Much of this continent is covered by a network of fractures and
faults.[2]
As well as the
impact craters, mountains, and valleys commonly found on rocky planets,
Venus has a number of unique surface features. Among these are flat-topped
volcanic features called farra, which look somewhat like pancakes and
range in size from 20–50 km across, and 100–1000 m high; radial, star-like
fracture systems called novae; features with both radial and concentric
fractures resembling spiders' webs, known as
arachnoids; and coronae, circular rings of fractures sometimes
surrounded by a depression. All of these features are volcanic in origin.[3]
|
|
|
Epoch J2000 |
| Aphelion
distance: |
108,941,849 km
0.728 231 28 AU |
| Perihelion distance: |
107,476,002 km
0.718 432 70 AU |
|
Semi-major axis: |
108,208,926 km
0.723 331 99
AU |
| Orbital
circumference: |
680,000,000 km
4.545 AU |
|
Eccentricity: |
0.006 773 23 |
|
Sidereal period: |
224.700 69 d
(0.615 197 0
a) |
|
Synodic period: |
583.92 d |
| Avg.
orbital speed: |
35.020 km/s |
| Max.
orbital speed: |
35.259 km/s |
| Min.
orbital speed: |
34.784 km/s |
| Inclination: |
3.394 71°
(3.86° to Sun's equator) |
|
Longitude of ascending node: |
76.680 69° |
|
Argument of perihelion: |
54.852 29° |
|
Satellites: |
None |
|
Physical characteristics |
| Equatorial
radius: |
6,051.9 km
(0.95 Earths) |
|
Surface area: |
4.60×108
km2
(0.902 Earths) |
| Volume: |
9.28×1011
km³
(0.857 Earths) |
| Mass: |
4.8685×1024 kg
(0.815 Earths) |
| Mean density: |
5.204 g/cm3 |
| Equatorial
surface gravity: |
8.87
m/s2
(0.904
g) |
|
Escape velocity: |
10.36 km/s |
| Sidereal rotation period: |
−243.0185 d |
| Rotation velocity at equator: |
6.52 km/h (at the equator) |
| Axial
tilt: |
2.64° |
|
Right ascension of North pole: |
272.76° (18 h 11 min 2 s)
1 |
| Declination: |
67.16° |
| Albedo: |
0.65 |
Surface
temp.:
Surface
Cloud tops |
| min |
mean |
max |
| |
737 K |
773 K |
| 228 K |
|
|
|
| Adjectives: |
Venusian or (rarely) Cytherean |
|
Atmosphere |
| Surface
pressure: |
9.2
MPa |
| Composition: |
~96.5%
Carbon dioxide
~3.5% Nitrogen
.015%
Sulfur dioxide
.007% Argon
.002%
Water vapor
.0017%
Carbon monoxide
.0012% Helium
.0007% Neon
trace
Carbonyl sulfide
trace
Hydrogen chloride
trace
Hydrogen fluoride |
Almost all Venusian surface features are named after historical and
mythological women.[4]
The only exceptions are Maxwell Montes, named after
James Clerk Maxwell, and two highland regions,
Alpha
Regio and
Beta Regio.
These three features were named before the current system was adopted by the
International Astronomical Union, the body that oversees planetary
nomenclature.[5]
Surface geology
Much of Venus' surface appears to have been shaped by volcanic activity.
Overall, Venus has several times as many volcanoes as Earth, and it possesses
some 167 giant volcanoes that are over 100 km across. The only volcanic complex
of this size on Earth is the
Big Island
of Hawaii.
However, this is not because Venus is more volcanically active than Earth, but
because its crust is older. Earth's crust is continually recycled by
subduction
at the boundaries of
tectonic plates, and has an average age of about 100 million years, while
Venus' surface is estimated to be about 500 million years old.[3]
Several lines of evidence point to ongoing volcanic activity on Venus. During
the Russian
Venera program, the Venera 11 and Venera 12 probes detected a constant
stream of
lightning, and Venera 12 recorded a powerful clap of
thunder soon
after it landed. While
rainfall
drives
thunderstorms on Earth, there is no rainfall on Venus. One possibility is
that ash from a volcanic eruption was generating the lightning. Another
intriguing piece of evidence comes from measurements of sulfur dioxide
concentrations in the atmosphere, which were found to drop by a factor of 10
between 1978 and 1986. This may imply that the levels had earlier been boosted
by a large volcanic eruption.[6]
There are almost 1,000 impact craters on Venus, more or less evenly
distributed across its surface. On other cratered bodies, such as the Earth and
the Moon, craters show a range of states of erosion, indicating a continual
process of degradation. On the Moon, degradation is caused by subsequent
impacts, while on Earth, it is caused by wind and rain erosion. However, on
Venus, about 85% of craters are in pristine condition. The number of craters
together with their well-preserved condition indicates that the planet underwent
a total resurfacing event about 500 million years ago.[7]
Earth's crust is in continuous motion, but it is thought that Venus cannot
sustain such a process. Without plate tectonics to dissipate heat from its
mantle, Venus instead undergoes a cyclical process in which mantle temperatures
rise until they reach a critical level that weakens the crust. Then, over a
period of about 100 million years, subduction occurs on an enormous scale,
completely recycling the crust.[3]
Venusian craters range from 3 km to 280 km in diameter. There are no craters
smaller than 3 km, because of the effects of the dense atmosphere on incoming
objects. Objects with less than a certain
kinetic energy are slowed down so much by the atmosphere that they do not
create an impact crater.[8]
Atmosphere
Venus has an extremely thick
atmosphere, which consists mainly of
carbon dioxide and a small amount of
nitrogen.
The pressure at the planet's surface is about 90 times that at Earth's surface—a
pressure equivalent to that at a depth of 1 kilometer under Earth's
oceans. The
enormously CO2-rich atmosphere generates a strong
greenhouse effect that raises the surface temperature to over 400 °C. This
makes Venus' surface hotter than
Mercury's, even though Venus is nearly twice as distant from the Sun and
receives only 25% of the solar
irradiance.
Studies have suggested that several billion years ago Venus' atmosphere was
much more like Earth's than it is now, and that there were probably substantial
quantities of liquid water on the surface, but a runaway greenhouse effect was
caused by the evaporation of that original water, which generated a critical
level of greenhouse gases in its atmosphere.[9]
Venus is thus an extreme example of
climate change, making it a useful tool in climate change studies.
Thermal inertia and the transfer of heat by winds in the lower atmosphere
mean that the temperature of Venus' surface does not vary significantly between
the night and day sides, despite the planet's extremely slow rotation. Winds at
the surface are slow, moving at a few kilometers per hour, but because of the
high density of the atmosphere at Venus' surface, they exert a significant
amount of force against obstructions, and transport dust and small stones across
the surface.[10]
Above the dense CO2 layer are thick clouds consisting mainly of
sulfur dioxide and
sulfuric acid droplets.[11]
These clouds reflect about 60% of the sunlight that falls on them back into
space, and prevent the direct observation of Venus' surface in
visible light. The permanent cloud cover means that although Venus is closer
than Earth to the Sun, the Venusian surface is not as well heated or lit. In the
absence of the greenhouse effect caused by the carbon dioxide in the atmosphere,
the temperature at the surface of Venus would be quite similar to that on Earth.
Strong 300 km/h winds at the cloud tops circle the planet about every four to
five earth days.[12]
Magnetic field and core
In 1980, The
Pioneer Venus Orbiter found that Venus'
magnetic field is both weaker and smaller (i.e. closer to the planet) than
Earth's. What small magnetic field is present is induced by an interaction
between the
ionosphere and the
solar wind,[13]
rather than by an internal
dynamo in the
core like the one inside the Earth. Venus'
magnetosphere is too weak to protect the atmosphere from cosmic radiation.
This lack of an intrinsic magnetic field at Venus was surprising given that
it is similar to Earth in size, and was expected to also contain a dynamo in its
core. A dynamo requires three things: a
conducting liquid, rotation, and
convection.
The core is thought to be electrically conductive, however. Also, while its
rotation is often thought to be too slow, simulations show that it is quite
adequate to produce a dynamo.[14]
[15] This
implies that the dynamo is missing because of a lack of convection in Venus'
core. On Earth, convection occurs in the liquid outer layer of the core because
the bottom of the liquid layer is much hotter than the top. Since Venus has no
plate tectonics to let off heat, it is possible that it has no solid inner
core, or that its core is not currently cooling, so that the entire liquid part
of the core is at approximately the same temperature. Another possibility is
that its core has already completely solidified.
Orbit and rotation
Venus orbits the Sun at an average distance of about 108 million km, and
completes an orbit every 224.65 days. Although all
planetary orbits are
elliptical,
Venus' is the closest to
circular, with
an
eccentricity of less than 1%. When Venus lies between the Earth and the Sun,
a position known as 'inferior conjunction', it makes the closest approach to
Earth of any planet, lying at a distance of about 40 million km. The planet
reaches inferior conjunction every 584 days, on average.
Venus rotates once every 243 days – by far the slowest rotation period of any
of the major planets. A Venusian
sidereal day thus lasts more than a Venusian year (243 versus 224.7 Earth
days). However, the length of a
solar day
on Venus is significantly shorter than the sidereal day; to an observer on the
surface of Venus the time from one sunrise to the next would be 116.75 days.[16]
The Sun would appear to rise in the west and set in the east. At the equator,
Venus' surface rotates at 6.5 km/h; on Earth, the rotation speed at the equator
is about 1,600 km/h.
If viewed from above the Sun's north pole, all of the planets are orbiting in
an anticlockwise direction; but while most planets also rotate anticlockwise,
Venus rotates clockwise in
"retrograde" rotation. The question of how Venus came to have a slow,
retrograde rotation was a major puzzle for scientists when the planet's rotation
period was first measured. When it formed from the
solar
nebula, Venus would have had a much faster, prograde rotation, but
calculations show that over billions of years,
tidal effects on
its dense atmosphere could have slowed down its initial rotation to the value
seen today.[17][18]
A curious aspect of Venus' orbit and rotation periods is that the 584-day
average interval between successive close approaches to the Earth is almost
exactly equal to five Venusian solar days. Whether this relationship arose by
chance or is the result of some kind of
tidal
locking with the Earth, is unknown.[19]
Venus is currently moonless, though the
asteroid 2002 VE68
presently maintains a
quasi-orbital relationship with it.[20]
According to Alex Alemi and David Stevenson of the
California Institute of Technology, their recent study of models of the
early solar system shows that it is very likely that, billions of years ago,
Venus had at least one moon, created by a huge
impact
event.[21][22]
About 10 million years later, according to Alemi and Stevenson, another impact
reversed the planet's spin direction. The reversed spin direction caused the
Venusian moon to gradually
spiral inward[23]
until it collided and merged with Venus. If later impacts created moons, those
moons also were absorbed the same way the first one was. The Alemi/Stevenson
study is recent, and it remains to be seen what sort of acceptance it will
achieve in the scientific community.
Observation
Venus is always brighter than the brightest stars, with its
apparent magnitude ranging from −3.8 to −4.6. This is bright enough to be
seen even in the middle of the day, and the planet can be easy to see when the
Sun is low on the horizon. As an
inferior planet, it always lies within about 47° of the
Sun.[24]
Venus 'overtakes' the Earth every 584 days as it orbits the Sun. As it does
so, it goes from being the 'Evening star', visible after sunset, to being the
'Morning star', visible before sunrise. While
Mercury, the other inferior planet, reaches a maximum
elongation
of only 28° and is often difficult to discern in twilight, Venus is almost
impossible not to identify when it is at its brightest. Its greater maximum
elongation means it is visible in dark skies long after sunset. As the brightest
point-like object in the sky, Venus is a commonly misreported 'unidentified
flying object'. In 1969, future
U.S. President Jimmy
Carter reported having seen a UFO, which later analysis suggested was
probably the planet, and countless other people have mistaken Venus for
something more exotic.[25]
As it moves around its orbit, Venus displays
phases like those of the
Moon: it is new
when it passes between the Earth and the Sun, full when it is on the opposite
side of the Sun, and a crescent when it is at its maximum elongations from the
Sun. Venus is brightest when it is a thin crescent; it is much closer to Earth
when a thin crescent than when
gibbous, or
full.
Venus' orbit is slightly inclined relative to the Earth's orbit; thus, when
the planet passes between the Earth and the Sun, it usually does not cross the
face of the Sun. However,
transits of Venus do occur in pairs separated by eight years, at intervals
of about 120 years, when the planet's
inferior conjunction coincides with its presence in the plane of the Earth's
orbit. The most recent transit was in 2004; the next will be in 2012.
Historically, transits of Venus were important, because they allowed astronomers
to directly determine the size of the
astronomical unit, and hence of the solar system.
Captain Cook's exploration of the east coast of Australia came after he had
sailed to Tahiti
in 1768 to observe a transit of Venus.
A long-standing mystery of Venus observations is the so-called 'ashen
light'—an apparent weak illumination of the dark side of the planet, seen when
the planet is in the crescent phase. The first claimed observation of ashen
light was made as long ago as 1643, but the existence of the illumination has
never been reliably confirmed. Observers have speculated that it may result from
electrical activity in the Venusian atmosphere, but it may be illusory,
resulting from the physiological effect of observing a very bright
crescent-shaped object.[26]
Studies of Venus
Early studies
Venus was known in the Hindu
Jyotisha
since early times as the
planet Shukra. In the
West, before the advent of the
telescope,
Venus was known only as a 'wandering
star'. Several cultures historically held its appearances as a morning and
evening star to be those of two separate bodies.
Pythagoras
is usually credited with recognizing in the sixth century BC that the morning
and evening stars were a single body, though he espoused the view that Venus
orbited the Earth. When
Galileo first
observed the planet in the early 17th century, he found that it showed
phases like the Moon's, varying from crescent to gibbous to full and vice
versa. This could be possible only if Venus orbited the Sun, and this was among
the first observations to clearly contradict the Ptolemaic geocentric model that
the solar system was concentric and centered on the Earth.[27]
Venus' atmosphere was discovered as early as
1790 by
Johann Schröter. Schröter found that when the planet was a thin crescent,
the cusps extended through more than 180°. He correctly surmised that this was
due to
scattering of sunlight in a dense atmosphere. Later,
Chester Smith Lyman observed a complete ring around the dark side of the
planet when it was at
inferior conjunction, providing further evidence for an atmosphere.[28]
The atmosphere complicated efforts to determine a rotation period for the
planet, and observers such as
Giovanni Cassini and Schröter incorrectly estimated periods of about 24
hours from the motions of markings on the planet's apparent surface.[29]
Ground-based research
Little more was discovered about Venus until the 20th century. Its almost
featureless disc gave no hint as to what its surface might be like, and it was
only with the development of
spectroscopic,
radar and
ultraviolet observations that more of its secrets were revealed. The first
UV observations were carried out in the 1920s, when
Frank
E. Ross found that UV photographs revealed considerable detail that was
absent in visible and
infrared
radiation. He suggested that this was due to a very dense yellow lower
atmosphere with high
cirrus clouds
above it.[30]
Spectroscopic observations in the 1900s gave the first clues about Venus'
rotation.
Vesto
Slipher tried to measure the
Doppler shift of light from Venus, but found that he could not detect any
rotation. He surmised that the planet must have a much longer rotation period
than had previously been thought.[31]
Later work in the 1950s showed that the rotation was retrograde. Radar
observations of Venus were first carried out in the 1960s, and provided the
first measurements of the rotation period which were close to the modern value.[32]
Radar observations in the 1970s revealed details of Venus' surface for the
first time. Pulses of radio waves were beamed at the planet using the 300 m
radio telescope at
Arecibo Observatory, and the echoes revealed two highly reflective regions,
designated the Alpha and Beta regions. The observations also revealed a bright
region attributed to mountains, which was called Maxwell Montes.[33]
These three features are now the only ones on Venus which do not have female
names.
The best radar images obtainable from Earth revealed features no smaller than
about 5 km across. More detailed exploration of the planet could only be carried
out from space.
Exploration of Venus
Early efforts
The first
unmanned space mission to Venus, and the first to any planet, began on
12
February 1961
with the launch of the
Venera 1
probe. The first craft of the otherwise highly successful Soviet
Venera program, Venera 1 was launched on a direct impact trajectory, but
contact was lost seven days into the mission, when the probe was about
2 million km from Earth. It was estimated to have passed within 100,000 km from
Venus in mid-May.
The
United States' exploration of Venus also started badly with the loss of the
Mariner 1
probe on launch. The subsequent
Mariner 2
mission enjoyed greater success, and after a 109-day
transfer orbit on
14
December 1962
it became the world's first successful interplanetary mission, passing 34,833 km
above the surface of Venus. Its
microwave
and infrared radiometers
revealed that while Venus' cloud tops were cool, the surface was extremely hot —
at least 425°C, finally ending any hopes that the planet might harbor
ground-based life. Mariner 2 also obtained improved estimates of Venus' mass and
of the
astronomical unit, but was unable to detect either a
magnetic field or
radiation belts.[34]
Atmospheric entry
The Venera 3
probe crash-landed on Venus on
March 1,
1966. It was the
first man-made object to enter the atmosphere and strike the surface of another
planet, though its communication system failed before it was able to return any
planetary data. Venus' next encounter with an unmanned probe came on
October 18,
1967 when
Venera 4
successfully entered the atmosphere and deployed a number of science
experiments. Venera 4 showed that the surface temperature was even hotter than
Mariner 2 had measured at almost 500°C, and that the atmosphere was about 90 to
95% carbon dioxide. The Venusian atmosphere was considerably denser than Venera
4's designers had anticipated, and its slower than intended parachute descent
meant that its batteries ran down before the probe reached the surface. After
returning descent data for 93 minutes, Venera 4's last pressure reading was
18 bar at an altitude of 24.96 km.
Another probe arrived at Venus one day later on
October 19,
1967 when
Mariner 5
conducted a flyby at a distance of less than 4,000 km above the cloud tops.
Mariner 5 was originally built as backup for the
Mars-bound
Mariner 4,
but when that mission was successful, the probe was refitted for a Venus
mission. A suite of instruments more sensitive than those on Mariner 2, in
particular its radio
occultation experiment, returned data on the composition, pressure and
density of Venus' atmosphere.[35]
The joint Venera 4–Mariner 5 data were analyzed by a combined Soviet-American
science team in a series of colloquia over the following year, in an early
example of space cooperation.
Armed with the lessons and data learned from Venera 4, the Soviet Union
launched the twin probes
Venera 5
and Venera 6
five days apart in January 1969; they encountered Venus a day apart on
May 16 and
May 17 that
year. The probes were strengthened to improve their
crush
depth to 25 atmospheres and were equipped with smaller parachutes to achieve
a faster descent. Since the then current atmospheric models of Venus suggested a
surface pressure of between 75 and 100 atmospheres, neither were expected to
survive to the surface. After returning atmospheric data for a little over fifty
minutes, they both were crushed at altitudes of approximately 20 km before going
on to strike the surface on the night side of Venus.
Surface science
Venera 7
represented a concerted effort to return data from the planet's surface, and was
constructed with a reinforced descent module capable of withstanding a pressure
of 180 bar. The module was pre-cooled prior to entry and equipped with a
specially reefed
parachute for a rapid 35-minute descent. Entering the atmosphere on
15
December
1970, the parachute is believed to have partially torn during the descent,
and the probe struck the surface with a hard, yet not fatal, impact. Probably
tilted onto its side, it returned a weak signal supplying temperature data for
23 minutes, the first
telemetry
received from the surface of another planet.
The Venera program continued with
Venera 8
sending data from the surface for 50 minutes, and
Venera 9
and Venera 10
sending the first images of the Venusian landscape. The two landing sites
presented very different visages in the immediate vicinities of the landers:
Venera 9 had landed on a 20 degree slope scattered with boulders around 30-40 cm
across; Venera 10 showed
basalt-like
rock slabs interspersed with
weathered
material.
In the meantime, the United States had sent the
Mariner 10
probe on a
gravitational slingshot trajectory past Venus on its way to
Mercury. On
February 5,
1974, Mariner 10
passed within 5790 km of Venus, returning over 4,000 photographs as it did so.
The images, the best then achieved, showed the planet to be almost featureless
in visible light, but
ultraviolet light revealed details in the clouds that had never been seen in
Earth-bound observations.[36]
The American
Pioneer Venus project consisted of two separate missions.[37]
The
Pioneer Venus Orbiter was inserted into an elliptical orbit around Venus on
December 4,
1978, and remained
there for over thirteen years studying the atmosphere and mapping the surface
with radar. The
Pioneer Venus Multiprobe released a total of five probes which entered the
atmosphere on
December 9,
1978, returning
data on its composition, winds and heat fluxes.
Four more Venera lander missions took place over the next four years, with
Venera 11
and Venera 12
detecting Venusian
electrical storms; and
Venera 13
and Venera 14,
landing four days apart on
March 1 and
March 5,
1982, returning the
first color photographs of the surface. All four missions deployed parachutes
for braking in the upper atmosphere, but released them at altitudes of 50 km,
the dense lower atmosphere providing enough friction to allow for an unaided
soft landing. Both Venera 13 and 14 analyzed soil samples with an on-board
X-ray
fluorescence
spectrometer, and attempted to measure the compressibility of the soil with
an impact probe. Venera 14, though, had the misfortune to strike its own ejected
camera lens cap and its probe failed to make contact with the soil. The Venera
program came to a close in October 1983 when
Venera 15
and Venera 16
were placed in orbit to conduct mapping of the Venusian terrain with
synthetic aperture radar.
The Soviet Union had not finished with Venus, and in 1985 it took advantage
of the opportunity to combine missions to Venus and
Comet
Halley, which passed through the inner solar system that year. En route to
Halley, on June
11 and June
15, 1985 the
two spacecraft of the
Vega
program each dropped a Venera-style probe (of which Vega 1's partially
failed) and released a balloon-supported
aerobot into
the upper atmosphere. The balloons achieved an equilibrium altitude of around
53 km, where pressure and temperature are comparable to those at Earth's
surface. They remained operational for around 46 hours, and discovered that the
Venusian atmosphere was more turbulent than previously believed, and subject to
high winds and powerful
convection cells.[38][39]
Radar mapping
The United States'
Magellan probe was launched on
4 May 1989 with a mission
to map the surface of Venus with radar.[5]
The high-resolution images it obtained during its 4½ years of operation far
surpassed all prior maps and were comparable to visible-light photographs of
other planets. Magellan imaged over 98% of Venus' surface by radar and mapped
95% of its gravity field. In 1994, at the end of its mission, Magellan was
deliberately sent to its destruction into the atmosphere of Venus in an effort
to quantify its density. Venus was observed by the
Galileo and
Cassini spacecraft during flybys on their respective missions to the
outer planets, but Magellan would otherwise be the last dedicated mission to
Venus for over a decade.
Current and future missions
The
Venus
Express probe successfully assumed orbit around Venus on
April 11,
2006. It was
designed and built by the
European Space Agency and launched by the
Russian Federal Space Agency on
November 9,
2005. On
April 11 of
the following year, its main engine was successfully fired to place it in a
polar
orbit about the planet. The probe is undertaking a detailed study of the
Venusian atmosphere and clouds, and will also map the planet's
plasma environment and surface characteristics, particularly temperatures.
Its mission is intended to last a nominal 500 Earth days, or around two Venusian
years.[40]
One of the first results emerging from Venus Express is the discovery that a
huge double
atmospheric vortex exists at the south pole of the planet.
Japan's aerospace body
JAXA (formerly
ISAS) is planning
to launch its Venus climate orbiter, the
PLANET-C,
in 2010.
Future flybys en route to other destinations include the
MESSENGER
and
BepiColombo missions to Mercury.
Venus in human culture
Historic connections
As one of the brightest objects in the sky, Venus has been known since
prehistoric times and from the earliest days has had a significant impact on
human culture. It is described in
Babylonian
cuneiformic texts such as the
Venus tablet of Ammisaduqa, which relates observations that possibly date
from 1600 BC. The Babylonians named the planet
Ishtar, the
personification of womanhood, and goddess of love. The
Ancient Egyptians believed Venus to be two separate bodies and knew the
morning star as Tioumoutiri and the evening star as Ouaiti.
Likewise believing Venus to be two bodies, the
Ancient Greeks called the morning star Φωσφόρος, Phosphorus, the
"Bringer of Light" or Εωσφόρος, Eosphorus, the "Bringer of Dawn"; the
evening star they called Hesperos (Ἓσπερος, the star of the dusk) — by
Hellenistic times, it was realized they were the same planet. Hesperos would
be translated into
Latin as Vesper
and Phosphorus as
Lucifer, a poetic term later used to refer to the fallen angel cast out of
heaven.[41]
The
Romans would later name the planet in honor of their goddess of love,
Venus, whereas the Greeks used the name of its Greek counterpart,
Aphrodite.
To the Hebrews
it was known as Noga ("shining"), Ayeleth-ha-Shakhar ("deer of the
dawn") and Kochav-ha-'Erev ("star of the evening"). Venus was important
to the Mayan
civilization, who developed a
religious calendar based in part upon its motions, and held the motions of
Venus to determine the propitious time for events such as war. The
Maasai people
named the planet
Kileken,
and have an
oral tradition about it called The Orphan Boy. In western
astrology,
derived from its historical connotation with goddesses of femininity and love,
Venus is held to influence those aspects of human life. In
Vedic astrology, where such an association was not made, Venus or
Shukra
affected wealth, comfort, and attraction. Early Chinese astronomers called the
body Tai-pe, or the "beautiful white one". Modern
Chinese,
Korean,
Japanese and
Vietnamese
cultures refer to the planet literally as the metal star (Chinese:
金星), based on the
Five elements. Lakotan spirituality refers to Venus as the daybreak star.
They associate it with the last stage of life and wisdom.
The
astronomical symbol for Venus is the same as that used in biology for the
female sex, a stylized representation of the goddess Venus' hand mirror: a
circle with a small cross underneath. The Venus symbol also represents
femininity,
and in ancient
alchemy stood for the metal
copper.
Alchemists constructed the symbol from a circle (representing
spirit) above a
cross (representing
matter).
In fiction
Venus' impenetrable cloud cover gave
science fiction writers free rein to speculate on conditions at its surface;
all the more so when early observations showed that it was very similar in size
to Earth and possessed a substantial atmosphere. The planet was frequently
depicted as warmer than Earth beneath the clouds, but still
habitable by humans. The
genre reached its
peak between the 1930s and 1950s, at a time when science had revealed some
aspects of Venus, but not yet the harsh reality of its surface conditions.
Robert Heinlein's
Future History series was set on a Venus inspired by the chemist
Svante Arrhenius's prediction of a steamy
carboniferous
swamp upon which the rain dripped incessantly. It probably inspired
Henry
Kuttner to the subsequent depiction given in his novel Fury.
Ray
Bradbury's short stories
The
Long Rain (found in the collection
The Illustrated Man) and
All Summer in a Day (found in the collection
A Medicine for Melancholy) also depicted Venus as a habitable planet
with incessant rain. Other works, such as
C. S.
Lewis's 1943
Perelandra
or
Isaac Asimov's 1954
Lucky Starr and the Oceans of Venus, drew from a vision of a
Cambrian-like
Venus covered by a near planet-wide
ocean filled with
exotic aquatic life.
As scientific knowledge of Venus has advanced, the authors of science fiction
have endeavoured to keep pace, particularly by conjecturing human attempts to
terraform Venus. In his 1997 novel
3001: The Final Odyssey,
Arthur C. Clarke postulated humans steering
cometary
fragments to impact Venus, the resulting addition of water to the Venus
environment intended to lower its temperature and absorb carbon dioxide. A
terraformed Venus is the setting for a number of diverse works of fiction that
have included
Star Trek,
Exosquad,
Cowboy
Bebop and the
manga
Venus Wars,
and the theme seems to be in little danger of dying out. A variation of this
theme is
Frederik Pohl's
The Merchants of Venus (1972), which started his celebrated
Heechee
Series, where Venus was colonised long ago by mysterious aliens whose abandoned
dwellings and artifacts make human colonization both materially easier and
provide a strong economic incentive.
