Outer space, or simply space, is the expanse that exists beyond Earth and between celestial bodies. Outer space is not completely empty—it is a hard vacuum containing a low density of particles, predominantly a plasma of hydrogen and helium, as well as electromagnetic radiation, magnetic fields, neutrinos, dust, and cosmic rays. The baseline temperature of outer space, as set by the background radiation from the Big Bang, is 2.7 kelvins (−270.45 °C; −454.81 °F). The plasma between galaxies accounts for about half of the baryonic (ordinary) matter in the universe; it has a number density of less than one hydrogen atom per cubic metre and a temperature of millions of kelvins. Local concentrations of matter have condensed into stars and galaxies. Studies indicate that 90% of the mass in most galaxies is in an unknown form, called dark matter, which interacts with other matter through gravitational but not electromagnetic forces. Observations suggest that the majority of the mass-energy in the observable universe is dark energy, a type of vacuum energy that is poorly understood. Intergalactic space takes up most of the volume of the universe, but even galaxies and star systems consist almost entirely of empty space.
Outer space does not begin at a definite altitude above the Earth’s surface. The Kármán line, an altitude of 100 km (62 mi) above sea level, is conventionally used as the start of outer space in space treaties and for aerospace records keeping. The framework for international space law was established by the Outer Space Treaty, which entered into force on 10 October 1967. This treaty precludes any claims of national sovereignty and permits all states to freely explore outer space. Despite the drafting of UN resolutions for the peaceful uses of outer space, anti-satellite weapons have been tested in Earth orbit.
Humans began the physical exploration of space during the 20th century with the advent of high-altitude balloon flights. This was followed by manned rocket flights and, then, manned Earth orbit, first achieved by Yuri Gagarin of the Soviet Union in 1961. Due to the high cost of getting into space, manned spaceflight has been limited to low Earth orbit and the Moon. On the other hand, unmanned spacecraft have reached all of the known planets in the Solar System.
Outer space represents a challenging environment for human exploration because of the hazards of vacuum and radiation. Microgravity also has a negative effect on human physiology that causes both muscle atrophy and bone loss. In addition to these health and environmental issues, the economic cost of putting objects, including humans, into space is very high.
- 1Formation and state
- 3Effect on biology and human bodies
- 5Earth orbit
- 7Legal status
- 8Discovery, exploration and applications
- 9See also
- 11External links
Formation and state
This is an artist’s concept of the metric expansion of space, where a volume of the Universe is represented at each time interval by the circular sections. At left is depicted the rapid inflation from the initial state, followed thereafter by steady expansion to the present day, shown at right.Main article: Big Bang
According to the Big Bang theory, the very early Universe was an extremely hot and dense state about 13.8 billion years ago which rapidly expanded. About 380,000 years later the Universe had cooled sufficiently to allow protons and electrons to combine and form hydrogen—the so-called recombination epoch. When this happened, matter and energy became decoupled, allowing photons to travel freely through the continually expanding space. Matter that remained following the initial expansion has since undergone gravitational collapse to create stars, galaxies and other astronomical objects, leaving behind a deep vacuum that forms what is now called outer space. As light has a finite velocity, this theory also constrains the size of the directly observable universe. This leaves open the question as to whether the Universe is finite or infinite.
The present day shape of the universe has been determined from measurements of the cosmic microwave background using satellites like the Wilkinson Microwave Anisotropy Probe. These observations indicate that the spatial geometry of the observable universe is “flat“, meaning that photons on parallel paths at one point remain parallel as they travel through space to the limit of the observable universe, except for local gravity. The flat Universe, combined with the measured mass density of the Universe and the accelerating expansion of the Universe, indicates that space has a non-zero vacuum energy, which is called dark energy.
Estimates put the average energy density of the present day Universe at the equivalent of 5.9 protons per cubic meter, including dark energy, dark matter, and baryonic matter (ordinary matter composed of atoms). The atoms account for only 4.6% of the total energy density, or a density of one proton per four cubic meters. The density of the Universe is clearly not uniform; it ranges from relatively high density in galaxies—including very high density in structures within galaxies, such as planets, stars, and black holes—to conditions in vast voids that have much lower density, at least in terms of visible matter. Unlike matter and dark matter, dark energy seems not to be concentrated in galaxies: although dark energy may account for a majority of the mass-energy in the Universe, dark energy’s influence is 5 orders of magnitude smaller than the influence of gravity from matter and dark matter within the Milky Way.
See also: Planetary habitabilityPart of the Hubble Ultra-Deep Field image showing a typical section of space containing galaxies interspersed by deep vacuum. Given the finite speed of light, this view covers the past 13 billion years of the history of outer space.
Outer space is the closest known approximation to a perfect vacuum. It has effectively no friction, allowing stars, planets, and moons to move freely along their ideal orbits, following the initial formation stage. The deep vacuum of intergalactic space is not devoid of matter, as it contains a few hydrogen atoms per cubic meter. By comparison, the air humans breathe contains about 1025 molecules per cubic meter. The low density of matter in outer space means that electromagnetic radiation can travel great distances without being scattered: the mean free path of a photon in intergalactic space is about 1023 km, or 10 billion light years. In spite of this, extinction, which is the absorption and scattering of photons by dust and gas, is an important factor in galactic and intergalactic astronomy.
Stars, planets, and moons retain their atmospheres by gravitational attraction. Atmospheres have no clearly delineated upper boundary: the density of atmospheric gas gradually decreases with distance from the object until it becomes indistinguishable from outer space. The Earth’s atmospheric pressure drops to about 0.032 Pa at 100 kilometres (62 miles) of altitude, compared to 100,000 Pa for the International Union of Pure and Applied Chemistry (IUPAC) definition of standard pressure. Above this altitude, isotropic gas pressure rapidly becomes insignificant when compared to radiation pressure from the Sun and the dynamic pressure of the solar wind. The thermosphere in this range has large gradients of pressure, temperature and composition, and varies greatly due to space weather.
The temperature of outer space is measured in terms of the kinetic activity of the gas, as it is on Earth. The radiation of outer space has a different temperature than the kinetic temperature of the gas, meaning that the gas and radiation are not in thermodynamic equilibrium. All of the observable universe is filled with photons that were created during the Big Bang, which is known as the cosmic microwave background radiation (CMB). (There is quite likely a correspondingly large number of neutrinos called the cosmic neutrino background.) The current black body temperature of the background radiation is about 3 K (−270 °C; −454 °F). The gas temperatures in outer space are always at least the temperature of the CMB but can be much higher. For example, the solar corona reaches temperatures over 1.2–2.6 million K.
Magnetic fields have been detected in the space around just about every class of celestial object. Star formation in spiral galaxies can generate small-scale dynamos, creating turbulent magnetic field strengths of around 5–10 μG. The Davis–Greenstein effect causes elongated dust grains to align themselves with a galaxy’s magnetic field, resulting in weak optical polarization. This has been used to show ordered magnetic fields exist in several nearby galaxies. Magneto-hydrodynamic processes in active elliptical galaxies produce their characteristic jets and radio lobes. Non-thermal radio sources have been detected even among the most distant, high-z sources, indicating the presence of magnetic fields.
Outside a protective atmosphere and magnetic field, there are few obstacles to the passage through space of energetic subatomic particles known as cosmic rays. These particles have energies ranging from about 106 eV up to an extreme 1020 eV of ultra-high-energy cosmic rays. The peak flux of cosmic rays occurs at energies of about 109 eV, with approximately 87% protons, 12% helium nuclei and 1% heavier nuclei. In the high energy range, the flux of electrons is only about 1% of that of protons. Cosmic rays can damage electronic components and pose a health threat to space travelers. According to astronauts, like Don Pettit, space has a burned/metallic odor that clings to their suits and equipment, similar to the scent of an arc welding torch.
Effect on biology and human bodies
See also: Astrobiology, Astrobotany, Plants in space, Animals in space, Effect of spaceflight on the human body, Bioastronautics, and WeightlessnessBecause of the hazards of a vacuum, astronauts must wear a pressurized space suit while off-Earth and outside their spacecraft.
Despite the harsh environment, several life forms have been found that can withstand extreme space conditions for extended periods. Species of lichen carried on the ESA BIOPAN facility survived exposure for ten days in 2007. Seeds of Arabidopsis thaliana and Nicotiana tabacum germinated after being exposed to space for 1.5 years. A strain of bacillus subtilis has survived 559 days when exposed to low-Earth orbit or a simulated martian environment. The lithopanspermia hypothesis suggests that rocks ejected into outer space from life-harboring planets may successfully transport life forms to another habitable world. A conjecture is that just such a scenario occurred early in the history of the Solar System, with potentially microorganism-bearing rocks being exchanged between Venus, Earth, and Mars.
Even at relatively low altitudes in the Earth’s atmosphere, conditions are hostile to the human body. The altitude where atmospheric pressure matches the vapor pressure of water at the temperature of the human body is called the Armstrong line, named after American physician Harry G. Armstrong. It is located at an altitude of around 19.14 km (11.89 mi). At or above the Armstrong line, fluids in the throat and lungs boil away. More specifically, exposed bodily liquids such as saliva, tears, and liquids in the lungs boil away. Hence, at this altitude, human survival requires a pressure suit, or a pressurized capsule.
Out in space, sudden exposure of an unprotected human to very low pressure, such as during a rapid decompression, can cause pulmonary barotrauma—a rupture of the lungs, due to the large pressure differential between inside and outside the chest. Even if the subject’s airway is fully open, the flow of air through the windpipe may be too slow to prevent the rupture. Rapid decompression can rupture eardrums and sinuses, bruising and blood seep can occur in soft tissues, and shock can cause an increase in oxygen consumption that leads to hypoxia.
As a consequence of rapid decompression, oxygen dissolved in the blood empties into the lungs to try to equalize the partial pressure gradient. Once the deoxygenated blood arrives at the brain, humans lose consciousness after a few seconds and die of hypoxia within minutes. Blood and other body fluids boil when the pressure drops below 6.3 kPa, and this condition is called ebullism. The steam may bloat the body to twice its normal size and slow circulation, but tissues are elastic and porous enough to prevent rupture. Ebullism is slowed by the pressure containment of blood vessels, so some blood remains liquid. Swelling and ebullism can be reduced by containment in a pressure suit. The Crew Altitude Protection Suit (CAPS), a fitted elastic garment designed in the 1960s for astronauts, prevents ebullism at pressures as low as 2 kPa. Supplemental oxygen is needed at 8 km (5 mi) to provide enough oxygen for breathing and to prevent water loss, while above 20 km (12 mi) pressure suits are essential to prevent ebullism. Most space suits use around 30–39 kPa of pure oxygen, about the same as on the Earth’s surface. This pressure is high enough to prevent ebullism, but evaporation of nitrogen dissolved in the blood could still cause decompression sickness and gas embolisms if not managed.
Humans evolved for life in Earth gravity, and exposure to weightlessness has been shown to have deleterious effects on human health. Initially, more than 50% of astronauts experience space motion sickness. This can cause nausea and vomiting, vertigo, headaches, lethargy, and overall malaise. The duration of space sickness varies, but it typically lasts for 1–3 days, after which the body adjusts to the new environment. Longer-term exposure to weightlessness results in muscle atrophy and deterioration of the skeleton, or spaceflight osteopenia. These effects can be minimized through a regimen of exercise. Other effects include fluid redistribution, slowing of the cardiovascular system, decreased production of red blood cells, balance disorders, and a weakening of the immune system. Lesser symptoms include loss of body mass, nasal congestion, sleep disturbance, and puffiness of the face.
During long-duration space travel, radiation can pose an acute health hazard. Exposure to high-energy, ionizing cosmic rays can result in fatigue, nausea, vomiting, as well as damage to the immune system and changes to the white blood cell count. Over longer durations, symptoms include an increased risk of cancer, plus damage to the eyes, nervous system, lungs and the gastrointestinal tract. On a round-trip Mars mission lasting three years, a large fraction of the cells in an astronaut’s body would be traversed and potentially damaged by high energy nuclei. The energy of such particles is significantly diminished by the shielding provided by the walls of a spacecraft and can be further diminished by water containers and other barriers.The impact of the cosmic rays upon the shielding produces additional radiation that can affect the crew. Further research is needed to assess the radiation hazards and determine suitable countermeasures.
Space is a partial vacuum: its different regions are defined by the various atmospheres and “winds” that dominate within them, and extend to the point at which those winds give way to those beyond. Geospace extends from Earth’s atmosphere to the outer reaches of Earth’s magnetic field, whereupon it gives way to the solar wind of interplanetary space. Interplanetary space extends to the heliopause, whereupon the solar wind gives way to the winds of the interstellar medium. Interstellar space then continues to the edges of the galaxy, where it fades into the intergalactic void.
Geospace is the region of outer space near Earth, including the upper atmosphere and magnetosphere. The Van Allen radiation belts lie within the geospace. The outer boundary of geospace is the magnetopause, which forms an interface between the Earth’s magnetosphere and the solar wind. The inner boundary is the ionosphere. The variable space-weather conditions of geospace are affected by the behavior of the Sun and the solar wind; the subject of geospace is interlinked with heliophysics—the study of the Sun and its impact on the planets of the Solar System.
The day-side magnetopause is compressed by solar-wind pressure—the subsolar distance from the center of the Earth is typically 10 Earth radii. On the night side, the solar wind stretches the magnetosphere to form a magnetotail that sometimes extends out to more than 100–200 Earth radii. For roughly four days of each month, the lunar surface is shielded from the solar wind as the Moon passes through the magnetotail.
Geospace is populated by electrically charged particles at very low densities, the motions of which are controlled by the Earth’s magnetic field. These plasmas form a medium from which storm-like disturbances powered by the solar wind can drive electrical currents into the Earth’s upper atmosphere. Geomagnetic storms can disturb two regions of geospace, the radiation belts and the ionosphere. These storms increase fluxes of energetic electrons that can permanently damage satellite electronics, interfering with shortwave radio communication and GPS location and timing. Magnetic storms can also be a hazard to astronauts, even in low Earth orbit. They also create aurorae seen at high latitudes in an oval surrounding the geomagnetic poles.
Although it meets the definition of outer space, the atmospheric density within the first few hundred kilometers above the Kármán line is still sufficient to produce significant drag on satellites. This region contains material left over from previous manned and unmanned launches that are a potential hazard to spacecraft. Some of this debris re-enters Earth’s atmosphere periodically.
Lunar Orbital Station, one of the proposed space stations for crewed cislunar travel in the 2030s
Earth’s gravity keeps the Moon in orbit at an average distance of 384,403 km (238,857 mi). The region outside Earth’s atmosphere and extending out to just beyond the Moon’s orbit, including the Lagrangian points, is sometimes referred to as cislunar space.
The region of space where Earth’s gravity remains dominant against gravitational perturbations from the Sun is called the Hill sphere. This extends well out into translunar space to a distance of roughly 1% of the mean distance from Earth to the Sun, or 1.5 million km (0.93 million mi).
Deep space has different definitions as to where it starts. It has been defined by the United States government and others as any region beyond cislunar space. The International Telecommunication Union responsible for radio communication (including satellites) defines the beginning of deep space at about 5 times that distance (2×106 km).
Interplanetary space is defined by the solar wind, a continuous stream of charged particles emanating from the Sun that creates a very tenuous atmosphere (the heliosphere) for billions of kilometers into space. This wind has a particle density of 5–10 protons/cm3 and is moving at a velocity of 350–400 km/s (780,000–890,000 mph). Interplanetary space extends out to the heliopause where the influence of the galactic environment starts to dominate over the magnetic field and particle flux from the Sun. The distance and strength of the heliopause varies depending on the activity level of the solar wind. The heliopause in turn deflects away low-energy galactic cosmic rays, with this modulation effect peaking during solar maximum.
The volume of interplanetary space is a nearly total vacuum, with a mean free path of about one astronomical unit at the orbital distance of the Earth. This space is not completely empty, and is sparsely filled with cosmic rays, which include ionized atomic nuclei and various subatomic particles. There is also gas, plasma and dust, small meteors, and several dozen types of organic molecules discovered to date by microwave spectroscopy. A cloud of interplanetary dust is visible at night as a faint band called the zodiacal light.
Interplanetary space contains the magnetic field generated by the Sun. There are also magnetospheres generated by planets such as Jupiter, Saturn, Mercury and the Earth that have their own magnetic fields. These are shaped by the influence of the solar wind into the approximation of a teardrop shape, with the long tail extending outward behind the planet. These magnetic fields can trap particles from the solar wind and other sources, creating belts of charged particles such as the Van Allen radiation belts. Planets without magnetic fields, such as Mars, have their atmospheres gradually eroded by the solar wind.
Main article: Interstellar medium“Interstellar space” redirects here. For the album, see Interstellar Space.Bow shock formed by the magnetosphere of the young star LL Orionis (center) as it collides with the Orion Nebula flow
Interstellar space is the physical space within a galaxy beyond the influence each star has upon the encompassed plasma. The contents of interstellar space are called the interstellar medium. Approximately 70% of the mass of the interstellar medium consists of lone hydrogen atoms; most of the remainder consists of helium atoms. This is enriched with trace amounts of heavier atoms formed through stellar nucleosynthesis. These atoms are ejected into the interstellar medium by stellar winds or when evolved stars begin to shed their outer envelopes such as during the formation of a planetary nebula. The cataclysmic explosion of a supernova generates an expanding shock wave consisting of ejected materials that further enrich the medium. The density of matter in the interstellar medium can vary considerably: the average is around 106 particles per m3, but cold molecular clouds can hold 108–1012 per m3.
A number of molecules exist in interstellar space, as can tiny 0.1 μm dust particles. The tally of molecules discovered through radio astronomy is steadily increasing at the rate of about four new species per year. Large regions of higher density matter known as molecular clouds allow chemical reactions to occur, including the formation of organic polyatomic species. Much of this chemistry is driven by collisions. Energetic cosmic rays penetrate the cold, dense clouds and ionize hydrogen and helium, resulting, for example, in the trihydrogen cation. An ionized helium atom can then split relatively abundant carbon monoxide to produce ionized carbon, which in turn can lead to organic chemical reactions.
The local interstellar medium is a region of space within 100 parsecs (pc) of the Sun, which is of interest both for its proximity and for its interaction with the Solar System. This volume nearly coincides with a region of space known as the Local Bubble, which is characterized by a lack of dense, cold clouds. It forms a cavity in the Orion Arm of the Milky Way galaxy, with dense molecular clouds lying along the borders, such as those in the constellations of Ophiuchus and Taurus. (The actual distance to the border of this cavity varies from 60 to 250 pc or more.) This volume contains about 104–105 stars and the local interstellar gas counterbalances the astrospheres that surround these stars, with the volume of each sphere varying depending on the local density of the interstellar medium. The Local Bubble contains dozens of warm interstellar clouds with temperatures of up to 7,000 K and radii of 0.5–5 pc.
When stars are moving at sufficiently high peculiar velocities, their astrospheres can generate bow shocks as they collide with the interstellar medium. For decades it was assumed that the Sun had a bow shock. In 2012, data from Interstellar Boundary Explorer (IBEX) and NASA’s Voyager probes showed that the Sun’s bow shock does not exist. Instead, these authors argue that a subsonic bow wave defines the transition from the solar wind flow to the interstellar medium. A bow shock is the third boundary of an astrosphere after the termination shock and the astropause (called the heliopause in the Solar System).
Intergalactic space is the physical space between galaxies. Studies of the large scale distribution of galaxies show that the Universe has a foam-like structure, with groups and clusters of galaxies lying along filaments that occupy about a tenth of the total space. The remainder forms huge voids that are mostly empty of galaxies. Typically, a void spans a distance of (10–40) h−1 Mpc, where h is the Hubble constant in units of 100 km s−1 Mpc−1.
Surrounding and stretching between galaxies, there is a rarefied plasma that is organized in a galactic filamentary structure. This material is called the intergalactic medium (IGM). The density of the IGM is 5–200 times the average density of the Universe. It consists mostly of ionized hydrogen; i.e. a plasma consisting of equal numbers of electrons and protons. As gas falls into the intergalactic medium from the voids, it heats up to temperatures of 105 K to 107 K, which is high enough so that collisions between atoms have enough energy to cause the bound electrons to escape from the hydrogen nuclei; this is why the IGM is ionized. At these temperatures, it is called the warm–hot intergalactic medium (WHIM). (Although the plasma is very hot by terrestrial standards, 105 K is often called “warm” in astrophysics.) Computer simulations and observations indicate that up to half of the atomic matter in the Universe might exist in this warm–hot, rarefied state. When gas falls from the filamentary structures of the WHIM into the galaxy clusters at the intersections of the cosmic filaments, it can heat up even more, reaching temperatures of 108 K and above in the so-called intracluster medium (ICM).
Main article: Geocentric orbit
A spacecraft enters orbit when its centripetal acceleration due to gravity is less than or equal to the centrifugal acceleration due to the horizontal component of its velocity. For a low Earth orbit, this velocity is about 7,800 m/s (28,100 km/h; 17,400 mph); by contrast, the fastest manned airplane speed ever achieved (excluding speeds achieved by deorbiting spacecraft) was 2,200 m/s (7,900 km/h; 4,900 mph) in 1967 by the North American X-15.
To achieve an orbit, a spacecraft must travel faster than a sub-orbital spaceflight. The energy required to reach Earth orbital velocity at an altitude of 600 km (370 mi) is about 36 MJ/kg, which is six times the energy needed merely to climb to the corresponding altitude. Spacecraft with a perigee below about 2,000 km (1,200 mi) are subject to drag from the Earth’s atmosphere, which decreases the orbital altitude. The rate of orbital decay depends on the satellite’s cross-sectional area and mass, as well as variations in the air density of the upper atmosphere. Below about 300 km (190 mi), decay becomes more rapid with lifetimes measured in days. Once a satellite descends to 180 km (110 mi), it has only hours before it vaporizes in the atmosphere. The escape velocity required to pull free of Earth’s gravitational field altogether and move into interplanetary space is about 11,200 m/s (40,300 km/h; 25,100 mph).
There is no clear boundary between Earth’s atmosphere and space, as the density of the atmosphere gradually decreases as the altitude increases. There are several standard boundary designations, namely:
- The Fédération Aéronautique Internationale has established the Kármán line at an altitude of 100 km (62 mi) as a working definition for the boundary between aeronautics and astronautics. This is used because at an altitude of about 100 km (62 mi), as Theodore von Kármán calculated, a vehicle would have to travel faster than orbital velocity 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 mi) as astronauts.
- NASA‘s Space Shuttle used 400,000 feet (122 km, 76 mi) as its re-entry altitude (termed the Entry Interface), which roughly marks the boundary where atmospheric drag becomes noticeable, thus beginning the process of switching from steering with thrusters to maneuvering with aerodynamic control surfaces.
In 2009, scientists reported detailed measurements with a Supra-Thermal Ion Imager (an instrument that measures the direction and speed of ions), which allowed them to establish a boundary at 118 km (73 mi) above Earth. The boundary represents the midpoint of a gradual transition over tens of kilometers from the relatively gentle winds of the Earth’s atmosphere to the more violent flows of charged particles in space, which can reach speeds well over 268 m/s (600 mph).
The Outer Space Treaty provides the basic framework for international space law. It covers the legal use of outer space by nation states, and includes in its definition of outer space the Moon and other celestial bodies. The treaty states that outer space is free for all nation states to explore and is not subject to claims of national sovereignty. It also prohibits the deployment of nuclear weapons in outer space. The treaty was passed by the United Nations General Assembly in 1963 and signed in 1967 by the USSR, the United States of America and the United Kingdom. As of 2017, 105 state parties have either ratified or acceded to the treaty. An additional 25 states signed the treaty, without ratifying it.
Since 1958, outer space has been the subject of multiple United Nations resolutions. Of these, more than 50 have been concerning the international co-operation in the peaceful uses of outer space and preventing an arms race in space. Four additional space law treaties have been negotiated and drafted by the UN’s Committee on the Peaceful Uses of Outer Space. Still, there remains no legal prohibition against deploying conventional weapons in space, and anti-satellite weapons have been successfully tested by the US, USSR, China, and in 2019, India The 1979 Moon Treaty turned the jurisdiction of all heavenly bodies (including the orbits around such bodies) over to the international community. The treaty has not been ratified by any nation that currently practices manned spaceflight.
In 1976, eight equatorial states (Ecuador, Colombia, Brazil, Congo, Zaire, Uganda, Kenya, and Indonesia) met in Bogotá, Colombia. With their “Declaration of the First Meeting of Equatorial Countries”, or “the Bogotá Declaration”, they claimed control of the segment of the geosynchronous orbital path corresponding to each country. These claims are not internationally accepted.
Discovery, exploration and applications
See also: Space science
In 350 BCE, Greek philosopher Aristotle suggested that nature abhors a vacuum, a principle that became known as the horror vacui. This concept built upon a 5th-century BCE ontological argument by the Greek philosopher Parmenides, who denied the possible existence of a void in space. Based on this idea that a vacuum could not exist, in the West it was widely held for many centuries that space could not be empty. As late as the 17th century, the French philosopher René Descartes argued that the entirety of space must be filled.
In ancient China, the 2nd-century astronomer Zhang Heng became convinced that space must be infinite, extending well beyond the mechanism that supported the Sun and the stars. The surviving books of the Hsüan Yeh school said that the heavens were boundless, “empty and void of substance”. Likewise, the “sun, moon, and the company of stars float in the empty space, moving or standing still”.
The Italian scientist Galileo Galilei knew that air had mass and so was subject to gravity. In 1640, he demonstrated that an established force resisted the formation of a vacuum. It would remain for his pupil Evangelista Torricelli to create an apparatus that would produce a partial vacuum in 1643. This experiment resulted in the first mercury barometer and created a scientific sensation in Europe. The French mathematician Blaise Pascal reasoned that if the column of mercury was supported by air, then the column ought to be shorter at higher altitude where the air pressure is lower. In 1648, his brother-in-law, Florin Périer, repeated the experiment on the Puy de Dôme mountain in central France and found that the column was shorter by three inches. This decrease in pressure was further demonstrated by carrying a half-full balloon up a mountain and watching it gradually expand, then contract upon descent.The original Magdeburg hemispheres (lower left) used to demonstrate Otto von Guericke’s vacuum pump (right)
In 1650, German scientist Otto von Guericke constructed the first vacuum pump: a device that would further refute the principle of horror vacui. He correctly noted that the atmosphere of the Earth surrounds the planet like a shell, with the density gradually declining with altitude. He concluded that there must be a vacuum between the Earth and the Moon.
Back in the 15th century, German theologian Nicolaus Cusanus speculated that the Universe lacked a center and a circumference. He believed that the Universe, while not infinite, could not be held as finite as it lacked any bounds within which it could be contained. These ideas led to speculations as to the infinite dimension of space by the Italian philosopher Giordano Bruno in the 16th century. He extended the Copernican heliocentric cosmology to the concept of an infinite Universe filled with a substance he called aether, which did not resist the motion of heavenly bodies. English philosopher William Gilbert arrived at a similar conclusion, arguing that the stars are visible to us only because they are surrounded by a thin aether or a void. This concept of an aether originated with ancient Greek philosophers, including Aristotle, who conceived of it as the medium through which the heavenly bodies move.
The concept of a Universe filled with a luminiferous aether retained support among some scientists until the early 20th century. This form of aether was viewed as the medium through which light could propagate. In 1887, the Michelson–Morley experiment tried to detect the Earth’s motion through this medium by looking for changes in the speed of light depending on the direction of the planet’s motion. The null result indicated something was wrong with the concept. The idea of the luminiferous aether was then abandoned. It was replaced by Albert Einstein‘s theory of special relativity, which holds that the speed of light in a vacuum is a fixed constant, independent of the observer’s motion or frame of reference.
The first professional astronomer to support the concept of an infinite Universe was the Englishman Thomas Digges in 1576. But the scale of the Universe remained unknown until the first successful measurement of the distance to a nearby star in 1838 by the German astronomer Friedrich Bessel. He showed that the star system 61 Cygni had a parallax of just 0.31 arcseconds (compared to the modern value of 0.287″). This corresponds to a distance of over 10 light years. In 1917, Heber Curtis noted that novae in spiral nebulae were, on average, 10 magnitudes fainter than galactic novae, suggesting that the former are 100 times further away. The distance to the Andromeda Galaxy was determined in 1923 by American astronomer Edwin Hubble by measuring the brightness of cepheid variables in that galaxy, a new technique discovered by Henrietta Leavitt. This established that the Andromeda galaxy, and by extension all galaxies, lay well outside the Milky Way.
The modern concept of outer space is based on the “Big Bang” cosmology, first proposed in 1931 by the Belgian physicist Georges Lemaître. This theory holds that the universe originated from a very dense form that has since undergone continuous expansion.
The earliest known estimate of the temperature of outer space was by the Swiss physicist Charles É. Guillaume in 1896. Using the estimated radiation of the background stars, he concluded that space must be heated to a temperature of 5–6 K. British physicist Arthur Eddington made a similar calculation to derive a temperature of 3.18 K in 1926. German physicist Erich Regener used the total measured energy of cosmic rays to estimate an intergalactic temperature of 2.8 K in 1933. American physicists Ralph Alpher and Robert Herman predicted 5 K for the temperature of space in 1948, based on the gradual decrease in background energy following the then-new Big Bang theory. The modern measurement of the cosmic microwave background is about 2.7K.
The term outward space was used in 1842 by the English poet Lady Emmeline Stuart-Wortley in her poem “The Maiden of Moscow”. The expression outer space was used as an astronomical term by Alexander von Humboldt in 1845. It was later popularized in the writings of H. G. Wells in 1901. The shorter term space is older, first used to mean the region beyond Earth’s sky in John Milton‘s Paradise Lost in 1667.
Exploration and application
Main articles: Astronomy, Astronautics, Spaceflight, Earth observation, Commercialization of space, Space exploration, Human spaceflight, Space habitat, Space advocacy, Space colonization, Benefits of space exploration, and Space manufacturingThe first image taken by a human of the whole Earth, probably photographed by William Anders of Apollo 8. South is up; South America is in the middle.
For most of human history, space was explored by observations made from the Earth’s surface—initially with the unaided eye and then with the telescope. Before reliable rocket technology, the closest that humans had come to reaching outer space was through balloon flights. In 1935, the U.S. Explorer II manned balloon flight reached an altitude of 22 km (14 mi). This was greatly exceeded in 1942 when the third launch of the German A-4 rocket climbed to an altitude of about 80 km (50 mi). In 1957, the unmanned satellite Sputnik 1 was launched by a Russian R-7 rocket, achieving Earth orbit at an altitude of 215–939 kilometres (134–583 mi). This was followed by the first human spaceflight in 1961, when Yuri Gagarin was sent into orbit on Vostok 1. The first humans to escape low-Earth orbit were Frank Borman, Jim Lovell and William Anders in 1968 on board the U.S. Apollo 8, which achieved lunar orbit and reached a maximum distance of 377,349 km (234,474 mi) from the Earth.
The first spacecraft to reach escape velocity was the Soviet Luna 1, which performed a fly-by of the Moon in 1959. In 1961, Venera 1 became the first planetary probe. It revealed the presence of the solar wind and performed the first fly-by of Venus, although contact was lost before reaching Venus. The first successful planetary mission was the 1962 fly-by of Venus by Mariner 2. The first fly-by of Mars was by Mariner 4 in 1964. Since that time, unmanned spacecraft have successfully examined each of the Solar System’s planets, as well their moons and many minor planets and comets. They remain a fundamental tool for the exploration of outer space, as well as for observation of the Earth. In August 2012, Voyager 1 became the first man-made object to leave the Solar System and enter interstellar space.
The absence of air makes outer space an ideal location for astronomy at all wavelengths of the electromagnetic spectrum. This is evidenced by the spectacular pictures sent back by the Hubble Space Telescope, allowing light from more than 13 billion years ago—almost to the time of the Big Bang—to be observed. Not every location in space is ideal for a telescope. The interplanetary zodiacal dust emits a diffuse near-infrared radiation that can mask the emission of faint sources such as extrasolar planets. Moving an infrared telescope out past the dust increases its effectiveness. Likewise, a site like the Daedalus crater on the far side of the Moon could shield a radio telescope from the radio frequency interference that hampers Earth-based observations.
Unmanned spacecraft in Earth orbit are an essential technology of modern civilization. They allow direct monitoring of weather conditions, relay long-range communications like television, provide a means of precise navigation, and allow remote sensing of the Earth. The latter role serves a wide variety of purposes, including tracking soil moisture for agriculture, prediction of water outflow from seasonal snow packs, detection of diseases in plants and trees, and surveillance of military activities.
The deep vacuum of space could make it an attractive environment for certain industrial processes, such as those requiring ultraclean surfaces. Like asteroid mining, space manufacturing would require a large financial investment with little prospect of immediate return. An important factor in the total expense is the high cost of placing mass into Earth orbit: $8,000–$25,000 per kg, according to a 2006 estimate (allowing for inflation since then). The cost of access to space has declined since 2013. Partially reusable rockets such as the Falcon 9 have lowered access to space below 3500 dollars per kilogram. With these new rockets the cost to send materials into space remains prohibitively high for many industries. Proposed concepts for addressing this issue include, fully reusable launch systems, non-rocket spacelaunch, momentum exchange tethers, and space elevators.
Interstellar travel for a human crew remains at present only a theoretical possibility. The distances to the nearest stars mean it would require new technological developments and the ability to safely sustain crews for journeys lasting several decades. For example, the Daedalus Project study, which proposed a spacecraft powered by the fusion of deuterium and helium-3, would require 36 years to reach the “nearby” Alpha Centauri system. Other proposed interstellar propulsion systems include light sails, ramjets, and beam-powered propulsion. More advanced propulsion systems could use antimatter as a fuel, potentially reaching relativistic velocities.
- Earth’s location in the Universe
- List of government space agencies
- List of topics in space
- Outline of space science
- Space and survival
- Space environment
- Space race
- Space station
- Space technology
- Space weather
- Space weathering
- Timeline of knowledge about the interstellar and intergalactic medium
- Timeline of Solar System exploration
- Timeline of spaceflight
- ^ Chuss, David T. (June 26, 2008), Cosmic Background Explorer, NASA Goddard Space Flight Center, archivedfrom the original on May 9, 2013, retrieved 2013-04-27.
- ^ Jump up to:a b Gupta, Anjali; Galeazzi, M.; Ursino, E. (May 2010), “Detection and Characterization of the Warm-Hot Intergalactic Medium”, Bulletin of the American Astronomical Society, 41: 908, Bibcode:2010AAS…21631808G.
- ^ Freedman & Kaufmann 2005, pp. 573, 599–601.
- ^ Trimble, V. (1987), “Existence and nature of dark matter in the universe”, Annual Review of Astronomy and Astrophysics, 25: 425–472, Bibcode:1987ARA&A..25..425T, doi:10.1146/annurev.aa.25.090187.002233.
- ^ “Dark Energy, Dark Matter”, NASA Science, archivedfrom the original on June 2, 2013, retrieved May 31, 2013,
It turns out that roughly 68% of the Universe is dark energy. Dark matter makes up about 27%.
- ^ Freedman & Kaufmann 2005, pp. 650–653.
- ^ Jump up to:a b O’Leary 2009, p. 84.
- ^ Jump up to:a b “Where does space begin? – Aerospace Engineering, Aviation News, Salary, Jobs and Museums”. Aerospace Engineering, Aviation News, Salary, Jobs and Museums. Archived from the original on 2015-11-17. Retrieved 2015-11-10.
- ^ Planck Collaboration (2014), “Planck 2013 results. I. Overview of products and scientific results”, Astronomy & Astrophysics, 571: 1, arXiv:1303.5062, Bibcode:2014A&A…571A…1P, doi:10.1051/0004-6361/201321529.
- ^ Jump up to:a b Turner, Michael S. (September 2009), “Origin of the Universe”, Scientific American, 301 (3): 36–43, Bibcode:2009SciAm.301c..36T, doi:10.1038/scientificamerican0909-36, PMID 19708526.
- ^ Silk 2000, pp. 105–308.
- ^ WMAP – Shape of the universe, NASA, December 21, 2012, archived from the original on June 1, 2012, retrieved June 4, 2013.
- ^ Sparke & Gallagher 2007, pp. 329–330.
- ^ Wollack, Edward J. (June 24, 2011), What is the Universe Made Of?, NASA, archived from the original on July 26, 2016, retrieved 2011-10-14.
- ^ Krumm, N.; Brosch, N. (October 1984), “Neutral hydrogen in cosmic voids”, Astronomical Journal, 89: 1461–1463, Bibcode:1984AJ…..89.1461K, doi:10.1086/113647.
- ^ Peebles, P.; Ratra, B. (2003). “The cosmological constant and dark energy”. Reviews of Modern Physics. 75 (2): 559–606. arXiv:astro-ph/0207347. Bibcode:2003RvMP…75..559P. doi:10.1103/RevModPhys.75.559.
- ^ Tadokoro, M. (1968), “A Study of the Local Group by Use of the Virial Theorem”, Publications of the Astronomical Society of Japan, 20: 230, Bibcode:1968PASJ…20..230T. This source estimates a density of 7 × 10−29 g/cm3 for the Local Group. An atomic mass unit is 1.66 × 10−24 g, for roughly 40 atoms per cubic meter.
- ^ Borowitz & Beiser 1971.
- ^ Tyson, Patrick (January 2012), The Kinetic Atmosphere: Molecular Numbers (PDF), archived from the original(PDF) on 16 March 2014, retrieved 13 September 2013.
- ^ Davies 1977, p. 93.
- ^ Fitzpatrick, E. L. (May 2004), “Interstellar Extinction in the Milky Way Galaxy”, in Witt, Adolf N.; Clayton, Geoffrey C.; Draine, Bruce T. (eds.), Astrophysics of Dust, ASP Conference Series, 309, p. 33, arXiv:astro-ph/0401344, Bibcode:2004ASPC..309…33F.
- ^ Chamberlain 1978, p. 2.
- ^ Squire, Tom (September 27, 2000), “U.S. Standard Atmosphere, 1976”, Thermal Protection Systems Expert and Material Properties Database, NASA, archived from the original on October 15, 2011, retrieved 2011-10-23.
- ^ Forbes, Jeffrey M. (2007), “Dynamics of the thermosphere” (PDF), Journal of the Meteorological Society of Japan, Series II, 85B: 193–213, doi:10.2151/jmsj.85b.193, archived from the original(PDF) on 2012-04-15, retrieved 2012-03-25.
- ^ Jump up to:a b Prialnik 2000, pp. 195–196.
- ^ Spitzer 1978, p. 28–30.
- ^ Chiaki, Yanagisawa (June 2014), “Looking for Cosmic Neutrino Background”, Frontiers in Physics, 2: 30, Bibcode:2014FrP…..2…30Y, doi:10.3389/fphy.2014.00030.
- ^ Fixsen, D. J. (December 2009), “The Temperature of the Cosmic Microwave Background”, The Astrophysical Journal, 707 (2): 916–920, arXiv:0911.1955, Bibcode:2009ApJ…707..916F, doi:10.1088/0004-637X/707/2/916.
- ^ Withbroe, George L. (February 1988), “The temperature structure, mass, and energy flow in the corona and inner solar wind”, Astrophysical Journal, Part 1, 325: 442–467, Bibcode:1988ApJ…325..442W, doi:10.1086/166015.
- ^ Wielebinski, Richard; Beck, Rainer (2010), “Cosmic Magnetic Fields − An Overview”, in Block, David L.; Freeman, Kenneth C.; Puerari, Ivânio (eds.), Galaxies and their Masks: A Conference in Honour of K.C. Freeman, FRS, Springer Science & Business Media, pp. 67–82, Bibcode:2010gama.conf…67W, doi:10.1007/978-1-4419-7317-7_5, ISBN 978-1441973177, archived from the original on 2017-09-20.
- ^ Letessier-Selvon, Antoine; Stanev, Todor (July 2011), “Ultrahigh energy cosmic rays”, Reviews of Modern Physics, 83 (3): 907–942, arXiv:1103.0031, Bibcode:2011RvMP…83..907L, doi:10.1103/RevModPhys.83.907.
- ^ Lang 1999, p. 462.
- ^ Lide 1993, p. 11-217.
- ^ What Does Space Smell Like?, Live Science, July 20, 2012, archived from the original on February 28, 2014, retrieved February 19, 2014.
- ^ Lizzie Schiffman (July 17, 2013), What Does Space Smell Like, Popular Science, archived from the original on February 24, 2014, retrieved February 19, 2014.
- ^ Raggio, J.; et al. (May 2011), “Whole Lichen Thalli Survive Exposure to Space Conditions: Results of Lithopanspermia Experiment with Aspicilia fruticulosa”, Astrobiology, 11 (4): 281–292, Bibcode:2011AsBio..11..281R, doi:10.1089/ast.2010.0588, PMID 21545267.
- ^ Tepfer, David; et al. (May 2012), “Survival of Plant Seeds, Their UV Screens, and nptII DNA for 18 Months Outside the International Space Station” (PDF), Astrobiology, 12 (5): 517–528, Bibcode:2012AsBio..12..517T, doi:10.1089/ast.2011.0744, PMID 22680697, archived(PDF) from the original on 2014-12-13, retrieved 2013-05-19.
- ^ Wassmann, Marko; et al. (May 2012), “Survival of Spores of the UV-ResistantBacillus subtilis Strain MW01 After Exposure to Low-Earth Orbit and Simulated Martian Conditions: Data from the Space Experiment ADAPT on EXPOSE-E”, Astrobiology, 12 (5): 498–507, Bibcode:2012AsBio..12..498W, doi:10.1089/ast.2011.0772, PMID 22680695.
- ^ Nicholson, W. L. (April 2010), “Towards a General Theory of Lithopanspermia”, Astrobiology Science Conference 2010, 1538, pp. 5272–528, Bibcode:2010LPICo1538.5272N.
- ^ Piantadosi 2003, pp. 188–189.
- ^ Jump up to:a b Bolonkin, Alexander (2009), “Man in Outer Space Without a Special Space Suit”, American Journal of Engineering and Applied Sciences, 2 (4): 573–579, doi:10.3844/ajeassp.2009.573.579, archived from the original on 2017-08-29, retrieved 2011-12-15.
- ^ Krebs, Matthew B.; Pilmanis, Andrew A. (November 1996), Human pulmonary tolerance to dynamic over-pressure, United States Air Force Armstrong Laboratory, archived from the original on 2012-11-30, retrieved 2011-12-23.
- ^ Harding, R. M.; Mills, F. J. (April 30, 1983), “Aviation medicine. Problems of altitude I: hypoxia and hyperventilation”, British Medical Journal, 286 (6375): 1408–1410, doi:10.1136/bmj.286.6375.1408, PMC 1547870, PMID 6404482.
- ^ Hodkinson, P. D. (March 2011), “Acute exposure to altitude” (PDF), Journal of the Royal Army Medical Corps, 157 (1): 85–91, doi:10.1136/jramc-157-01-15, PMID 21465917, archived from the original (PDF) on 2012-02-20, retrieved 2011-12-16.
- ^ Billings 1973, pp. 1–34.
- ^ Landis, Geoffrey A. (August 7, 2007), Human Exposure to Vacuum, http://www.geoffreylandis.com, archived from the original on July 21, 2009, retrieved 2009-06-19.
- ^ Webb, P. (1968), “The Space Activity Suit: An Elastic Leotard for Extravehicular Activity”, Aerospace Medicine, 39 (4): 376–383, PMID 4872696.
- ^ Ellery 2000, p. 68.
- ^ Davis, Johnson & Stepanek 2008, pp. 270–271.
- ^ Kanas, Nick; Manzey, Dietrich (2008), “Basic Issues of Human Adaptation to Space Flight”, Space Psychology and Psychiatry, Space Technology Library, 22: 15–48, Bibcode:2008spp..book…..K, doi:10.1007/978-1-4020-6770-9_2, ISBN 978-1-4020-6769-3.
- ^ Williams, David; et al. (June 23, 2009), “Acclimation during space flight: effects on human physiology”, Canadian Medical Association Journal, 180 (13): 1317–1323, doi:10.1503/cmaj.090628, PMC 2696527, PMID 19509005.
- ^ Kennedy, Ann R., Radiation Effects, National Space Biological Research Institute, archived from the original on 2012-01-03, retrieved 2011-12-16.
- ^ Curtis, S. B.; Letaw, J. W. (1989), “Galactic cosmic rays and cell-hit frequencies outside the magnetosphere”, Advances in Space Research, 9 (10): 293–298, Bibcode:1989AdSpR…9..293C, doi:10.1016/0273-1177(89)90452-3, PMID 11537306
- ^ Setlow, Richard B. (November 2003), “The hazards of space travel”, Science and Society, 4 (11): 1013–1016, doi:10.1038/sj.embor.7400016, PMC 1326386, PMID 14593437.
- ^ Jump up to:a b Schrijver & Siscoe 2010, p. 363.
- ^ Jump up to:a b Abby Cessna (July 5, 2009), “Interplanetary space”, Universe Today, archived from the original on March 19, 2015.
- ^ Jump up to:a b Jia-Rui Cook (September 12, 2013), “How do we know when Voyager reaches interstellar space?”, JPL News, 2013-278, archived from the original on September 15, 2013.
- ^ Kintner, Paul; GMDT Committee and Staff (September 2002), Report of the Living With a Star Geospace Mission Definition Team (PDF), NASA, archived (PDF) from the original on 2012-11-02, retrieved 2012-04-15.
- ^ Fichtner & Liu 2011, pp. 341–345.
- ^ Koskinen 2010, pp. 32, 42.
- ^ Hones Jr., Edward W. (March 1986), “The Earth’s Magnetotail”, Scientific American, 254 (3): 40–47, Bibcode:1986SciAm.254c..40H, doi:10.1038/scientificamerican0386-40, JSTOR 24975910
- ^ Mendillo 2000, p. 275.
- ^ Goodman, John M. (2006). Space Weather & Telecommunications. Springer Science & Business Media. p. 244. ISBN 978-0-387-23671-1.
- ^ “Geomagnetic Storms” (PDF), OECD/IFP Futures Project on “Future Global Shocks”, CENTRA Technology, Inc., pp. 1–69, January 14, 2011, archived (PDF) from the original on March 14, 2012, retrieved 2012-04-07.
- ^ Jump up to:a b Kennewell, John; McDonald, Andrew (2011), Satellite Lifetimes and Solar Activity, Commonwealth of Australia Bureau of Weather, Space Weather Branch, archived from the original on 2011-12-28, retrieved 2011-12-31.
- ^ Portree, David; Loftus, Joseph (1999), Orbital Debris: A Chronology (PDF), NASA, p. 13, archived from the original (PDF) on 2000-09-01, retrieved 2012-05-05.
- ^ Strickland, John K. (October 1, 2012). “The cislunar gateway with no gate”. The Space Review. Archived from the original on February 7, 2016. Retrieved 2016-02-10.
- ^ Yoder, Charles F. (1995), “Astrometric and Geodetic Properties of Earth and the Solar System”, in Ahrens, Thomas J. (ed.), Global earth physics a handbook of physical constants (PDF), AGU reference shelf Series, 1, Washington, DC: American Geophysical Union, p. 1, Bibcode:1995geph.conf….1Y, ISBN 978-0-87590-851-9, archived from the original (PDF) on April 26, 2012, retrieved 2011-12-31.. This work lists a Hill sphere radius of 234.9 times the mean radius of Earth, or 234.9 × 6,371 km = 1.5 million km.
- ^ Barbieri 2006, p. 253.
- ^ Dickson 2010, p. 57.
- ^ United States, p. 536.
- ^ Williamson 2006, p. 97.
- ^ “Definition of ‘deep space'”, Collins English Dictionary, retrieved 2018-01-15.
- ^ “ITU-R Radio Regulations, Article 1, Terms and definitions, Section VIII, Technical terms relating to space, paragraph 1.177” (PDF). International Telecommunication Union. Retrieved 2018-02-05.
- ^ Jump up to:a b Papagiannis 1972, pp. 12–149.
- ^ Phillips, Tony (2009-09-29), Cosmic Rays Hit Space Age High, NASA, archived from the original on 2009-10-14, retrieved 2009-10-20.
- ^ Kohler, Susanna (December 1, 2017), “A Shifting Shield Provides Protection Against Cosmic Rays”, Nova, American Astronomical Society, retrieved 2019-01-31.
- ^ NASA (12 March 2019). “What scientists found after sifting through dust in the solar system”. EurekAlert!. Retrieved 12 March 2019.
- ^ Flynn, G. J.; et al. (2003), “The Origin of Organic Matter in the Solar System: Evidence from the Interplanetary Dust Particles”, in Norris, R.; Stootman, F. (eds.), Bioastronomy 2002: Life Among the Stars, Proceedings of IAU Symposium No. 213, 213, p. 275, Bibcode:2004IAUS..213..275F.
- ^ Leinert, C.; Grun, E. (1990), “Interplanetary Dust”, Physics of the Inner Heliosphere I: 207, Bibcode:1990pihl.book..207L.
- ^ Johnson, R. E. (August 1994), “Plasma-Induced Sputtering of an Atmosphere”, Space Science Reviews, 69 (3–4): 215–253, Bibcode:1994SSRv…69..215J, doi:10.1007/BF02101697.
- ^ Jump up to:a b Ferrière, Katia M. (2001), “The interstellar environment of our galaxy”, Reviews of Modern Physics, 73 (4): 1031–1066, arXiv:astro-ph/0106359, Bibcode:2001RvMP…73.1031F, doi:10.1103/RevModPhys.73.1031.
- ^ Witt, Adolf N. (October 2001), “The Chemical Composition of the Interstellar Medium”, Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences – Origin and early evolution of solid matter in the Solar System, 359, p. 1949, Bibcode:2001RSPTA.359.1949W, doi:10.1098/rsta.2001.0889.
- ^ Boulares, Ahmed; Cox, Donald P. (December 1990), “Galactic hydrostatic equilibrium with magnetic tension and cosmic-ray diffusion”, Astrophysical Journal, Part 1, 365: 544–558, Bibcode:1990ApJ…365..544B, doi:10.1086/169509.
- ^ Rauchfuss 2008, pp. 72–81.
- ^ Klemperer, William (August 15, 2006), “Interstellar chemistry”, Proceedings of the National Academy of Sciences of the United States of America, 103 (33): 12232–12234, Bibcode:2006PNAS..10312232K, doi:10.1073/pnas.0605352103, PMC 1567863, PMID 16894148.
- ^ Redfield, S. (September 2006), “The Local Interstellar Medium”, New Horizons in Astronomy; Proceedings of the Conference Held 16–18 October 2005 at The University of Texas, Austin, Texas, USA, Frank N. Bash Symposium ASP Conference Series, 352, p. 79, arXiv:astro-ph/0601117, Bibcode:2006ASPC..352…79R.
- ^ McComas, D. J.; et al. (2012), “The Heliosphere’s Interstellar Interaction: No Bow Shock”, Science, 336 (6086): 1291–3, Bibcode:2012Sci…336.1291M, doi:10.1126/science.1221054, PMID 22582011.
- ^ Jump up to:a b Fox, Karen C. (May 10, 2012), NASA – IBEX Reveals a Missing Boundary at the Edge of the Solar System, NASA, archived from the original on May 12, 2012, retrieved 2012-05-14.
- ^ Wszolek 2013, p. 67.
- ^ Jafelice, Luiz C.; Opher, Reuven (July 1992), “The origin of intergalactic magnetic fields due to extragalactic jets”, Monthly Notices of the Royal Astronomical Society, 257 (1): 135–151, Bibcode:1992MNRAS.257..135J, doi:10.1093/mnras/257.1.135.
- ^ Wadsley, James W.; et al. (August 20, 2002), “The Universe in Hot Gas”, Astronomy Picture of the Day, NASA, archived from the original on June 9, 2009, retrieved 2009-06-19.
- ^ Jump up to:a b Fang, T.; et al. (2010), “Confirmation of X-Ray Absorption by Warm-Hot Intergalactic Medium in the Sculptor Wall”, The Astrophysical Journal, 714 (2): 1715, arXiv:1001.3692, Bibcode:2010ApJ…714.1715F, doi:10.1088/0004-637X/714/2/1715.
- ^ Bykov, A. M.; Paerels, F. B. S.; Petrosian, V. (February 2008), “Equilibration Processes in the Warm-Hot Intergalactic Medium”, Space Science Reviews, 134 (1–4): 141–153, arXiv:0801.1008, Bibcode:2008SSRv..134..141B, doi:10.1007/s11214-008-9309-4.
- ^ Wakker, B. P.; Savage, B. D. (2009), “The Relationship Between Intergalactic H I/O VI and Nearby (z<0.017) Galaxies”, The Astrophysical Journal Supplement Series, 182(1): 378, arXiv:0903.2259, Bibcode:2009ApJS..182..378W, doi:10.1088/0067-0049/182/1/378.
- ^ Mathiesen, B. F.; Evrard, A. E. (2001), “Four Measures of the Intracluster Medium Temperature and Their Relation to a Cluster’s Dynamical State”, The Astrophysical Journal, 546 (1): 100, arXiv:astro-ph/0004309, Bibcode:2001ApJ…546..100M, doi:10.1086/318249.
- ^ Hill, James V. H. (April 1999), “Getting to Low Earth Orbit”, Space Future, archived from the original on 2012-03-19, retrieved 2012-03-18.
- ^ Shiner, Linda (November 1, 2007), X-15 Walkaround, Air & Space Magazine, retrieved 2009-06-19.
- ^ Dimotakis, P.; et al. (October 1999), 100 lbs to Low Earth Orbit (LEO): Small-Payload Launch Options, The Mitre Corporation, pp. 1–39, archived from the original on 2017-08-29, retrieved 2012-01-21.
- ^ Ghosh 2000, pp. 47–48.
- ^ Williams, David R. (November 17, 2010), “Earth Fact Sheet”, Lunar & Planetary Science, NASA, archived from the original on October 30, 2010, retrieved 2012-05-10.
- ^ Michael Coren (July 14, 2004), “Private craft soars into space, history”, CNN.com, archived from the original on April 2, 2015.
- ^ Wong & Fergusson 2010, p. 16.
- ^ Petty, John Ira (February 13, 2003), “Entry”, Human Spaceflight, NASA, archived from the original on October 27, 2011, retrieved 2011-12-16.
- ^ Thompson, Andrea (April 9, 2009), Edge of Space Found, space.com, archived from the original on July 14, 2009, retrieved 2009-06-19.
- ^ Sangalli, L.; et al. (2009), “Rocket-based measurements of ion velocity, neutral wind, and electric field in the collisional transition region of the auroral ionosphere”, Journal of Geophysical Research, 114 (A4): A04306, Bibcode:2009JGRA..114.4306S, doi:10.1029/2008JA013757.
- ^ Status of International Agreements relating to activities in outer space as of 1 January 2017 (PDF), United Nations Office for Outer Space Affairs/ Committee on the Peaceful Uses of Outer Space, March 23, 2017, archived from the original (PDF) on March 22, 2018, retrieved 2018-03-22.
- ^ Treaty on Principles Governing the Activities of States in the Exploration and Use of Outer Space, including the Moon and Other Celestial Bodies, United Nations Office for Outer Space Affairs, January 1, 2008, archived from the original on February 22, 2011, retrieved 2009-12-30.
- ^ Index of Online General Assembly Resolutions Relating to Outer Space, United Nations Office for Outer Space Affairs, 2011, archived from the original on 2010-01-15, retrieved 2009-12-30.
- ^ Wong & Fergusson 2010, p. 4.
- ^ Solanki, Lalit (2019-03-27). “India Enters the Elite Club: Successfully Shot Down Low Orbit Satellite”. The Mirk. Retrieved 2019-03-28.
- ^ Columbus launch puts space law to the test, European Science Foundation, November 5, 2007, archived from the original on December 15, 2008, retrieved 2009-12-30.
- ^ Representatives of the States traversed by the Equator (December 3, 1976), “Declaration of the first meeting of equatorial countries”, Space Law, Bogota, Republic of Colombia: JAXA, archived from the original on November 24, 2011, retrieved 2011-10-14.
- ^ Gangale, Thomas (2006), “Who Owns the Geostationary Orbit?”, Annals of Air and Space Law, 31, archived from the original on 2011-09-27, retrieved 2011-10-14.
- ^ Grant 1981, p. 10.
- ^ Porter, Park & Daston 2006, p. 27.
- ^ Eckert 2006, p. 5.
- ^ Needham & Ronan 1985, pp. 82–87.
- ^ Holton & Brush 2001, pp. 267–268.
- ^ Cajori 1917, pp. 64–66.
- ^ Genz 2001, pp. 127–128.
- ^ Tassoul & Tassoul 2004, p. 22.
- ^ Gatti 2002, pp. 99–104.
- ^ Kelly 1965, pp. 97–107.
- ^ Olenick, Apostol & Goodstein 1986, p. 356.
- ^ Hariharan 2003, p. 2.
- ^ Olenick, Apostol & Goodstein 1986, pp. 357–365.
- ^ Thagard 1992, pp. 206–209.
- ^ Maor 1991, p. 195.
- ^ Webb 1999, pp. 71–73.
- ^ Curtis, Heber D. (January 1988), “Novae in Spiral Nebulae and the Island Universe Theory”, Publications of the Astronomical Society of the Pacific, 100: 6–7, Bibcode:1988PASP..100….6C, doi:10.1086/132128.
- ^ Cepheid Variable Stars & Distance Determination, CSIRO Australia, October 25, 2004, archived from the original on August 30, 2011, retrieved 2011-09-12.
- ^ Tyson & Goldsmith 2004, pp. 114–115.
- ^ Lemaître, G. (May 1931), “The Beginning of the World from the Point of View of Quantum Theory”, Nature, 127 (3210): 706, Bibcode:1931Natur.127..706L, doi:10.1038/127706b0.
- ^ Jump up to:a b Assis, A. K. T.; Paulo, São; Neves, M. C. D. (July 1995), “History of the 2.7 K Temperature Prior to Penzias and Wilson”, Apeiron, 2 (3): 79–87.
- ^ Stuart Wortley 1841, p. 410.
- ^ Von Humboldt 1845, p. 39.
- ^ Harper, Douglas, “Outer”, Online Etymology Dictionary, archived from the original on 2010-03-12, retrieved 2008-03-24.
- ^ Harper, Douglas (November 2001), Space, The Online Etymology Dictionary, archived from the original on 2009-02-24, retrieved 2009-06-19.
- ^ Woods, W. David; O’Brien, Frank (2006). “Day 1: The Green Team and Separation”. Apollo 8 Flight Journal. NASA. Archived from the original on September 23, 2008. Retrieved October 29, 2008. TIMETAG 003:42:55.
- ^ Pfotzer, G. (June 1972), “History of the Use of Balloons in Scientific Experiments”, Space Science Reviews, 13 (2): 199–242, Bibcode:1972SSRv…13..199P, doi:10.1007/BF00175313.
- ^ O’Leary 2009, pp. 209–224.
- ^ Harrison 2002, pp. 60–63.
- ^ Orloff 2001.
- ^ Hardesty, Eisman & Krushchev 2008, pp. 89–90.
- ^ Collins 2007, p. 86.
- ^ Harris 2008, pp. 7, 68–69.
- ^ Wall, Mike (September 12, 2013), “Voyager 1 Has Left Solar System”, Web, Space.com, archived from the original on 14 September 2013, retrieved 13 September 2013.
- ^ Harrington, J.D.; Villard, Ray; Weaver, Donna (12 December 2012), NASA’s Hubble Provides First Census of Galaxies Near Cosmic Dawn, NASA, 12-428, archived from the original on 22 March 2015.
- ^ Landgraf, M.; et al. (February 2001), “IRSI/Darwin: peering through the interplanetary dust cloud”, ESA Bulletin, 105 (105): 60–63, arXiv:astro-ph/0103288, Bibcode:2001ESABu.105…60L.
- ^ Maccone, Claudio (August 2001), “Searching for bioastronomical signals from the farside of the Moon”, in Ehrenfreund, P.; Angerer, O.; Battrick, B. (eds.), Exo-/astro-biology. Proceedings of the First European Workshop, 496, Noordwijk: ESA Publications Division, pp. 277–280, Bibcode:2001ESASP.496..277M, ISBN 978-92-9092-806-5.
- ^ Razani 2012, pp. 97–99.
- ^ Chapmann, Glenn (May 22–27, 1991), “Space: the Ideal Place to Manufacture Microchips”, in Blackledge, R.; Radfield, C.; Seida, S. (eds.), Proceedings of the 10th International Space Development Conference (PDF), San Antonio, Texas, pp. 25–33, archived from the original (PDF) on 2011-07-06, retrieved 2010-01-12.
- ^ Forgan, Duncan H.; Elvis, Martin (October 2011), “Extrasolar asteroid mining as forensic evidence for extraterrestrial intelligence”, International Journal of Astrobiology, 10 (4): 307–313, arXiv:1103.5369, Bibcode:2011IJAsB..10..307F, doi:10.1017/S1473550411000127.
- ^ Burton, Rodney; Brown, Kevin; Jacobi, Anthony (May 2005), “Low-Cost Launch of Payloads to Low Earth Orbit”, Journal of Spacecraft and Rockets, 43 (3): 696–698, Bibcode:2006JSpRo..43..696B, doi:10.2514/1.16244.
- ^ Bolonkin 2010, p. xv.
- ^ Crawford, I. A. (September 1990), “Interstellar Travel: A Review for Astronomers”, Quarterly Journal of the Royal Astronomical Society, 31: 377–400, Bibcode:1990QJRAS..31..377C.