:''For the Atari video game, see
Outer Space (video game).''
:''"Deep space" redirects here. For the NASA space probes, see
Deep Space 1 and
Deep Space 2.''
'Outer space', sometimes simply called ''
space'', refers to the relatively empty regions of the
universe outside the
atmospheres of
celestial bodies. ''Outer'' space is used to distinguish it from
airspace (and terrestrial locations). Contrary to popular understanding, outer space is not completely empty (i.e. a
perfect vacuum) but contains a low density of particles, predominantly
hydrogen plasma, as well as
electromagnetic radiation,
dark matter and
dark energy.
Earth's boundary
There is no clear boundary between
Earth's atmosphere and space as the
density of the atmosphere gradually decreases as the
altitude increases. Nevertheless, the
Fédération Aéronautique Internationale has established the
Kármán line at an altitude of
100 km (
62 miles) as a working definition for the boundary between aeronautics and astronautics. This is used because above an altitude of roughly 100 km, as
Theodore von Kármán calculated, a vehicle would have to travel faster than
orbital velocity in order to derive sufficient
aerodynamic lift from the atmosphere to support itself. The
United States designates people who travel above an altitude of 80 km (50 statute miles) as
astronauts. During
re-entry, roughly 120 km (75 miles) marks the boundary where
atmospheric drag becomes noticeable, depending on the
ballistic coefficient of the vehicle.
Solar system
Outer space within the
solar system is called
interplanetary space, which passes over into
interstellar space at the
heliopause. The
vacuum of outer space is not really empty; it is sparsely filled with several dozen types of
organic molecules discovered to date by
microwave spectroscopy. According to the
Big bang theory,
2.7 K blackbody radiation was left over from the 'big bang' and the origin of the universe, and
cosmic rays, which include
ionized
atomic nuclei and various
subatomic particles. There is also gas,
plasma and dust, and small
meteors and material left over from previous manned and unmanned launches that are a potential hazard to
spacecraft. Some of this
debris re-enters the atmosphere periodically.
The absence of
air makes outer space (and the surface of the
Moon) ideal locations for
astronomy at all wavelengths of the
electromagnetic spectrum, as evidenced by the spectacular pictures sent back by the
Hubble Space Telescope, allowing light from about 13.7 billion years ago — almost to the time of the Big Bang — to be observed. Pictures and other data from unmanned space vehicles have provided invaluable information about the
planets,
asteroids and
comets in our solar system.
The "vacuum of space"
While not being an actual
perfect vacuum, outer space contains such sparse matter that it can be effectively thought of as one. The pressure of interstellar space is about 10
pPa (1×10
-11 Pa). For comparison, the pressure at sea level (as defined in the unit of
atmospheric pressure) is about 101 kPa (1×10
5 Pa).
Contrary to popular belief,
[1] a person suddenly exposed to the
vacuum would not explode,
freeze to death (space may be cold, but it's mostly vacuum, a perfect insulator; the main temperature worry for space suits is how to get rid of naturally generated body heat), or die from boiling blood, but would take a short while to die by
asphyxiation (suffocation).
Air would immediately leave the lungs due to the enormous
pressure gradient. Any oxygen dissolved in the blood would empty into the lungs to try to equalize the
partial pressure gradient. Once the deoxygenated blood arrived at the brain, death would quickly follow.
Water vapor would also rapidly
evaporate off from exposed areas such as the lungs,
cornea of the
eye and mouth, cooling the body.
Satellites
There are many
artificial satellites orbiting Earth, including
geosynchronous communication satellites 35,786 km (22,241 miles) above mean sea level at the
Equator. There is also increasing reliance, for both
military and
civilian uses, on satellites which enable the
Global Positioning System (GPS). A common misconception is that people in orbit are outside Earth's
gravity because they are "floating". They are floating because they are in "
free fall": the force of gravity is creating an inward
centripetal force which is stopping them from flying out into space, balanced by the (reactive)
centrifugal force induced by their linear velocity. Earth's gravity reaches out far past the
Van Allen belt and keeps the Moon in orbit at an average distance of 384,403 km (238,857 miles).
According to the theory of
gravity, the gravity of all
celestial bodies drops off toward zero with the
inverse square of the distance.
Milestones on the way to space
★ Sea level - 101.3 kPa (1 atm; 1.013 bar; 29.92 in Hg; 760 mm Hg; 14.5 lbf/in²) of atmospheric pressure
★ 3.0 km (10,000 ft)(1.9 miles) -
FAA requires supplemental oxygen for aircraft pilots in unpressurized aircraft.
[2]
★ 5.0 km (16,400 ft)(3.1 miles) - 50 kPa of atmospheric pressure
★ 5.3 km (17,400 ft)(3.3 miles) - Half of the Earth's atmosphere is below this altitude.
★ 8.0 km (26,200 ft)(5 miles) -
Death zone for human climbers
★ 8.85 km (29,035 ft)(5.5 miles) - Summit of
Mount Everest, the highest mountain on Earth (26 kPa)
★ 16 km (52,500 ft)(9.9 miles) - Pressurized cabin or pressure suit required.
★ 18 km (59,100 ft)(11.2 miles) - Boundary between troposphere and stratosphere
★ 20 km (65,600 ft)(12.4 miles) - Water at room temperature boils without a pressurized container. (The popular notion that bodily fluids would start to boil at this point is false because the body generates enough internal pressure to prevent it.)
★ 24 km (78,700 ft)(14.9 miles) - Regular aircraft pressurization systems no longer function.
★ 32 km (105,000 ft)(19.9 miles) -
Turbojets no longer function.
★ 34.7 km (113,740 ft)(21.5 miles) - Altitude record for manned balloon flight
★ 45 km (147,600 ft)(28 miles) -
Ramjets no longer function.
★ 50 km (164,000 ft)(31 miles) - Boundary between
stratosphere and
mesosphere
★ 80.5 km (264,000 ft)(50 miles) - Boundary between
mesosphere and
thermosphere. USA definition of space flight.
★ 100 km (328,100 ft)(62.1 miles) -
Kármán line, defining the limit of outer space according to the Fédération Aéronautique Internationale. Aerodynamic surfaces ineffective due to low atmospheric density. Lift speed generally exceeds orbital velocity.
Turbopause.
★ 120 km (393,400 ft)(74.6 miles) - First noticeable atmospheric drag during re-entry from orbit
★ 200 km (124.2 miles) - Lowest possible orbit with short-term stability (stable for a few days)
★ 307 km (190.8 miles) -
STS-1 mission orbit
★ 350 km (217.4 miles) - Lowest possible orbit with long-term stability (stable for many years)
★ 360 km (223.7 miles) -
ISS average orbit, which still varies due to drag and periodic boosting.
★ 390 km (242.3 miles) -
Mir mission orbit
★ 440 km (273.4 miles) -
Skylab mission orbit
★ 587 km (364.8 miles) -
HST orbit
★ 690 km (428.7 miles) - Boundary between thermosphere and exosphere
★ 780 km (484.7 miles) - Iridium orbit
★ 1,374 km (850 miles) - Highest altitude by a manned Earth-orbiting flight (
Gemini XI with
Agena Target Vehicle)
★ 20,200 km (12,600 miles) - GPS orbit
★ 35,786 km (22,237 miles) -
Geostationary orbit height
★ 320,000 km (200,000 miles) - Lunar gravity exceeds Earth's (at
Lagrange point)
★ 348,200 km (238,700 miles) - lunar perigee
★ 402,100 km (249,900 miles) - lunar apogee
Regions of outer space
★
Cislunar space
★
Interplanetary space
★
Interstellar medium
★
Intergalactic space
Space does not equal orbit
To perform an
orbital spaceflight, a spacecraft must travel away from Earth faster than it must for a
sub-orbital spaceflight. A spacecraft has not entered
orbit until it is traveling with a sufficiently great horizontal velocity such that the
acceleration due to
gravity on the spacecraft is less than or equal to the
centripetal acceleration being caused by its horizontal velocity (see
circular motion). So to enter
orbit, a spacecraft must not only reach space, but must also achieve a sufficient
orbital speed (
angular velocity). For a low-Earth orbit, this is about 7.9 km/s (18,000 mph).
Konstantin Tsiolkovsky was the first to realize that, given the
energy available from any available
chemical fuel, a several-stage
rocket would be required. The
escape velocity to pull free of Earth's gravitational field altogether and move into
interplanetary space is about 40,000 km/h (25,000 mph or 11,000
m/s). The energy required to reach velocity for low Earth orbit (
32 MJ/kg) is about twenty times the energy required simply to climb to the corresponding altitude (10 kJ/(km·kg)).
There is a major difference between
sub-orbital and
orbital spaceflights. The minimum altitude for a stable orbit around Earth (that is, one without significant
atmospheric drag) begins at around 350 km (220 miles) above mean sea level. A common misunderstanding about the boundary to space is that orbit occurs simply by reaching this altitude. Achieving orbital speed can theoretically occur at any altitude, although atmospheric drag precludes an orbit that is too low. At sufficient speed, an airplane would need a way to keep it from flying off into space, but at present, this speed is several times greater than anything within reasonable technology.
See also
★
Outer Space Treaty
★
NASA
★
Astronaut Badge
★
Extraterrestrial life
★
Interplanetary Internet
★
Space station
★
Space and survival
★
Space colonization
★
Space exploration
★
Private space flight
★
Space science
★
Space technology
★
Solar wind
★
Karman line
★
List of space flights
References
1. NASA Human Body in a Vacuum
2. FAR 121.329, http://www.flightsimaviation.com/data/FARS/part_121-329.html
External links
★
Morgan Freeman's Space Exploration Channel "Our Space" on ClickStar
★
Profits set to soar in outer space
★
Newscientist Space.
★
X PRIZE Foundation.
★
Images of Earth and space taken from outer space
★
Space Wallpapers (1.25 resolutions) and
Space Wallpapers (1.33 resolutions)
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