Wikipedysta:Getoryk/brudnopisVSE

Kolonizacja kosmosu to tworzenie autonomicznych, samowystarczalnych ludzkich osiedli lokowanych poza Ziemią. Jest to koncepcja bardzo popularna w fantastyce naukowej a zarazem długoterminowy cel różnych narodowych programów kosmicznych. Obecnie tylko Międzynarodowa Stacja Kosmiczna ISS na orbicie Ziemi umożliwia stałą, ale wciąż nie autonomiczną ludzką obecność w kosmosie. W tej chwili najbardziej konkretne plany utworzenia pozaziemskich kolonii, to projekt NASA zbudowania bazy w okolicach jednego z biegunów Księżyca. Poza Księżycem, najczęściej wymienianym obiektem, gdzie mogłyby powstawać ludzkie kolonie, jest Mars.

Obecne propozycje zakładają lokalizowanie kosmicznych kolonii w trzech typach miejsc:

• powierzchnia planet (np. Mars, Merkury) lub księżyców (np. Księżyc, Kallisto, Tytan)
• unoszących się w atmosferach planet (np. Wenus lub planety gazowe Jowisz, Saturn itd.)
• na orbitach planet lub w punktach libracyjnych

Budowanie kolonii w kosmosie będzie wymagało dostępu do żywności, przestrzeni, ludzi, materiałów konstrukcyjnych, energii, transportu, komunikacji, systemów podtrzymywania życia, ochrony przed promieniowaniem a w niektórych przypadkach także symulowanej grawitacji. Prawdopodobnie lokalizacje kolonii będą tak wybierane aby pomóc spełnić te warunki.

Kolonie na Marsie i Księżycu mogą korzystać z lokalnych materiałów, chociaż Księżyc jest ubogi na przykład w wodór (ale podejrzewa się istnienie pewnych zasobów wody w okolicach biegunowych) i azot, ale za to posiada spore ilości tlenu, krzemu, metali takich jak żelazo, aluminium, tytan. Dostarczanie materiałów koniecznych do budowy z Ziemi jest bardzo drogie, ze względu na stosunkowo silne ziemskie pole grawitacyjne, więc surowce mogą pochodzić z Księżyca, planetoid albo komet, lub księżyców Marsa: Fobosa i Dejmosa. Wiele planetoid zawiera na przykład spore ilości metali, tlenu, wodoru, i węgla, niektóre mogą zawierać azot.

Słońce jest wydajnym i powszechnie stosowanym dzisiaj źródłem energii elektrycznej w satelitach, w rejonach Układu Słonecznego do orbity Marsa światła słonecznego jest pod dostatkiem. W przestrzeni kosmicznej nie ma nocy, chmur czy atmosfery, które to czynniki mogłyby ograniczyć dostęp do tego typu energii. Poziom energii słonecznej w watach na metr kwadratowy, dostępnej w danej odległości od Słońca d, można obliczyć korzystając ze wzoru: E = 1366/d², gdzie d jest wyrażona w jednostkach astronomicznych.

W szczególności, w warunkach nieważkości, światło słoneczne może być użyte bezpośrednio, za pomocą dużych skupiających zwierciadeł zrobionych z lekkiej, metalicznej folii, pozwalając uzyskać temperaturę tysięcy stopni Celsjusza. Promienie słoneczne mogą być także odbijane i kierowane na uprawy roślin w celu umożliwienia fotosyntezy.

Noc na Księżycu trwa dwa ziemskie tygodnie, a Mars oprócz występowania cyklu dobowego, ma bogatą w pył atmosferę, jest także położony dalej od Słońca, więc dla tych miejsc bardziej atrakcyjna mogłaby się okazać energia nuklearna.

The Moon has nights of two Earth weeks in duration and Mars has night, dust, and is farther from the Sun, reducing solar energy available by a factor of about ½-⅔, and possibly making nuclear power more attractive on these bodies. Alternatively, continuousSzablon:Dubious energy could be beamed to the lunar surface from a solar power satellite at the Lagrange L1 location.

For both solar thermal and nuclear power generation in airless environments, such as the Moon and space, and to a lesser extent the very thin Martian atmosphere, one of the main difficulties is dispersing the inevitable heat generated. This requires fairly large radiator areas. Alternatively, the waste heat can be used to melt ice on the poles of a planet like Mars.

Szablon:See Transportation to orbit is often the limiting factor in space endeavours. To settle space, much cheaper launch vehicles are required, as well as a way to avoid serious damage to the atmosphere from the thousands, perhaps millions, of launches required. One possibility is air-breathing hypersonic spaceplane under development by NASA and other organizations, both public and private. There are also proposed projects such as building a space elevator or a mass driver; or launch loops.

Transportation of large quantities of materials from the Moon, Phobos, Deimos, and Near Earth asteroids to orbital settlement construction sites is likely to be necessary.

Transportation using off-Earth resources for propellant in relatively conventional rockets would be expected to massively reduce in-space transportation costs compared to the present day; propellant launched from the Earth is likely to be prohibitively expensive for space colonization, even with improved space access costs.

Other technologies such as tether propulsion, VASIMR, ion drives, solar thermal rockets, solar sails, magnetic sails, and nuclear thermal propulsion can all potentially help solve the problems of high transport cost once in space.

For lunar materials, one well-studied possibility is to build electronic catapults to launch bulk materials to waiting settlements. Alternatively, lunar space elevators might be employed.

Compared to the other requirements, communication is relatively easy for orbit and the Moon. A great proportion of current terrestrial communications already passes through satellites. Yet, as colonies further from the earth are considered, communication becomes more of a burden. Transmissions to and from Mars suffer from significant delays due to the speed of light and the greatly varying distance between conjunction and opposition — the lag will range between 7 and 44 minutes — making real-time communication impractical. Other means of communication that do not require live interaction such as e-mail and voice mail systems should pose no problem.

People need air, water, food, gravity and reasonable temperatures to survive for long periods. On Earth, a large complex biosphere provides these. In space settlements, a relatively small, closed ecological system must recycle or import all the nutrients without "crashing."

The closest terrestrial analogue to space life support is possibly that of the nuclear submarine. Nuclear submarines use mechanical life support systems to support humans for months without surfacing, and this same basic technology could presumably be employed for space use. However, nuclear submarines run "open loop" and typically dump carbon dioxide overboard, although they recycle oxygen. Recycling of the carbon dioxide has been approached in the literature using the Sabatier process or the Bosch reaction.

Alternatively, and more attractive to many, the Biosphere 2 project in Arizona has shown that a complex, small, enclosed, man-made biosphere can support eight people for at least a year, although there were many problems. A year or so into the two-year mission oxygen had to be replenished, which strongly suggests that they achieved atmospheric closure.

The relationship between organisms, their habitat and the non-Earth environment can be:

• Organisms and their habitat fully isolated from the environment (examples include artificial biosphere, Biosphere 2, life support system)
• Changing the environment to become a life-friendly habitat, a process called terraforming.
• Changing organisms to become more compatible with the environment, (See genetic engineering, transhumanism, cyborg)

97–99% of the light energy provided to the plant ends up as heat and needs to be dissipated somehow to avoid overheating the habitat.

A combination of the above technologies is also possible.

Cosmic rays and solar flares create a lethal radiation environment in space. In Earth orbit, the Van Allen belts make living above the Earth's atmosphere difficult. To protect life, settlements must be surrounded by sufficient mass to absorb most incoming radiation. Somewhere around 5–10 tons of material per square meter of surface area is required. This can be achieved cheaply with leftover material (slag) from processing lunar soil and asteroids into oxygen, metals, and other useful materials, however it represents a significant obstacle to maneuvering vessels with such massive bulk. Inertia would necessitate powerful thrusters to start or stop rotation.

Self-replication is an optional attribute, but many think it the ultimate goal because it allows a much more rapid increase in colonies, while eliminating costs to and dependence on Earth. It could be argued that the establishment of such a colony would be Earth's first act of self-replication (see Gaia spore). Intermediate goals include colonies that expect only information from Earth (science, engineering, entertainment, etc.) and colonies that just require periodic supply of light weight objects, such as integrated circuits, medicines, genetic material and perhaps some tools.

See also: von Neumann probe, clanking replicator, Molecular nanotechnology

In 2002, the anthropologist John H. Moore estimated that a population of 150–180 would allow normal reproduction for 60 to 80 generations — equivalent to 2000 years.

A much smaller initial population of as little as two female humans should be viable as long as human embryos are available from Earth. Use of a sperm bank from Earth also allows a smaller starting base with negligible inbreeding.

Researchers in conservation biology have tended to adopt the "50/500" rule of thumb initially advanced by Franklin and Soule. This rule says a short-term effective population size (N_e) of 50 is needed to prevent an unacceptable rate of inbreeding, while a long‐term N_e of 500 is required to maintain overall genetic variability. The ${\displaystyle N_{e}=50}$ prescription corresponds to an inbreeding rate of 1% per generation, approximately half the maximum rate tolerated by domestic animal breeders. The ${\displaystyle N_{e}=500}$ value attempts to balance the rate of gain in genetic variation due to mutation with the rate of loss due to genetic drift.

Effective population size N_e depends on the number of males N_m and females N_f in the population according to the formula:

${\displaystyle N_{e}={\frac {4\times N_{m}\times N_{f}}{N_{m}+N_{f}}}}$

Location is a frequent point of contention between space colonization advocates.

The location of colonization can be:

• On a planet, natural satellite, or asteroid
• In orbit around the Earth, Sun, Lagrangian point or other object

Some planetary colonization advocates cite the following potential locations:

Mars is a frequent topic of discussion. Its overall surface area is similar to the dry land surface of Earth, it may have large water reserves, and has carbon (locked as carbon dioxide in the atmosphere).

Mars may have gone through similar geological and hydrological processes as Earth and contain valuable mineral ores, but this is debated. Equipment is available to extract in situ resources (water, air, etc.) from the Martian ground and atmosphere. There is a strong scientific interest in colonizing Mars due to the possibility that life could have existed on Mars at some point in its history, and may even still exist in some parts of the planet.

However, its atmosphere is very thin (averaging 800 Pa or about 0.8% of Earth sea-level atmospheric pressure); so the pressure vessels necessary to support life are very similar to deep space structures. The climate of Mars is colder than Earth's. Its gravity is only around a third that of Earth's; it is unknown whether this is sufficient to support human beings for extended periods of time (all long-term human experience to date has been at around Earth gravity or one g).

The atmosphere is thin enough, when coupled with Mars' lack of magnetic field, that radiation is more intense on the surface, and protection from solar storms would require radiation shielding.

Mars is often the topic of discussion regarding terraforming to make the entire planet or at least large portions of it habitable.

See also: Exploration of Mars, Martian terraforming

There is a suggestion that Mercury could be colonized using the same technology, approach and equipment that is used in colonization of the Moon. Such colonies would almost certainly be restricted to the polar regions due to the extreme daytime temperatures elsewhere on the planet.

While the surface of Venus is far too hot and features atmospheric pressure at least 90 times that at sea level on Earth, its massive atmosphere offers a possible alternate location for colonization. At a height of approximately 50 km, the pressure is reduced to a few atmospheres, and the temperature would be between 40–100 °C, depending on the height. This part of the atmosphere is probably within dense clouds which contain some sulfuric acid. Even these may have a certain benefit to colonization, as they present a possible source for the extraction of water.

It may also be possible to colonize the three farthest gas giants with floating cities in their atmospheres. By heating hydrogen balloons, large masses can be suspended underneath at roughly Earth gravity. Jupiter would be less suitable for habitation due to its high gravity, escape velocity and radiation. Such colonies could export Helium-3 for use in fusion reactors if they ever become practical.

Due to its proximity and relative familiarity, Earth's Moon is also frequently discussed as a target for colonization. It has the benefits of proximity to Earth and lower escape velocity, allowing for easier exchange of goods and services. A major drawback of the Moon is its low abundance of volatiles necessary for life such as hydrogen and carbon. Water ice deposits that may exist in some polar craters could serve as a source for these elements. An alternative solution is to bring hydrogen from NE asteroids and combine it with oxygen extracted from lunar rock.

The moon's low surface gravity is also a concern (it is unknown whether 1/6g is sufficient to support human habitation for long periods — see microgravity).

The Artemis Project designed a plan to colonize Europa, one of Jupiter's moons. Scientists were to inhabit igloos and drill down into the Europan ice crust, exploring any sub-surface ocean. This plan also discusses possible use of "air pockets" for human inhabitation.

The moons of Mars may be an appealing target for space colonization. Low delta-v is needed to reach the Earth from Phobos and Deimos, allowing delivery of material to cislunar space, as well as transport around the Martian system. The moons themselves may be inhabited, with methods similar to those for asteroids. The original DOOM game featured a colony on Deimos and one on Phobos.

Titan has been suggested as an appealing target for colonization,^[1] because it is the only moon in our solar system to have a dense atmosphere and is rich in carbon-bearing compounds.^[2]

Free space locations in space would necessitate a space habitat, also called space colony and orbital colony, or a space station which would be intended as a permanent settlement rather than as a simple waystation or other specialized facility. They would be literal "cities" in space, where people would live and work and raise families. Many design proposals have been made with varying degrees of realism by both science fiction authors and engineers.

A space habitat would also serve as a proving ground for how well a generation ship could function as a long-term home for hundreds or thousands of people. Such a space habitat could be isolated from the rest of humanity for a century, but near enough to Earth for help. This would test if thousands of humans can survive a century on their own before sending them beyond the reach of any help.

Compared to other locations, Earth orbit has substantial advantages and one major, but solvable, problem. Orbits close to Earth can be reached in hours, whereas the Moon is days away and trips to Mars take months. There is ample continuous solar power in high Earth orbits, whereas all planets lose sunlight at least half the time. Weightlessness makes construction of large colonies considerably easier than in a gravity environment. Astronauts have demonstrated moving multi-ton satellites by hand. 0g recreation is available on orbital colonies, but not on the Moon or Mars. Finally, the level of (pseudo-) gravity is controlled at any desired level by rotating an orbital colony. Thus, the main living areas can be kept at 1 g, whereas the Moon has 1/6 g and Mars 1/3 g. It's not known what the minimum g-force is for ongoing health but 1 g is known to ensure that children grow up with strong bones and muscles.

The main disadvantage of orbital colonies is lack of materials. These may be expensively imported from the Earth, or more cheaply from extraterrestrial sources, such as the Moon (which has ample metals, silicon, and oxygen), Near Earth Asteroids, comets, or elsewhere.

Another near-Earth possibility are the five Earth-Moon Lagrange points. Although they would generally also take a few days to reach with current technology, many of these points would have near-continuous solar power capability since their distance from Earth would result in only brief and infrequent eclipses of light from the Sun.

The five Earth-Sun Lagrange points would totally eliminate eclipses, but only L1 and L2 would be reachable in a few days' time. The other three Earth-Sun points would require months to reach.

However, the fact that Lagrange points L4 and L5 tend to collect dust and debris, while L1-L3 require active station-keeping measures to maintain a stable position, make them somewhat less suitable places for habitation than was originally believed.

Many small asteroids in orbit around the Sun have the advantage that they pass closer than Earth's moon several times per decade. In between these close approaches to home, the asteroid may travel out to a furthest distance of some 350,000,000 kilometers from the Sun (its aphelion) and 500,000,000 kilometers from Earth.

Colonization of asteroids would require space habitats. The asteroid belt has significant overall material available, although it is thinly distributed as it covers a vast region of space. Unmanned supply craft should be practical with little technological advance, even crossing 1/2 billion kilometers of cold vacuum. The colonists would have a strong interest in assuring that their asteroid did not hit Earth or any other body of significant mass, but would have extreme difficulty in moving an asteroid of any size. The orbits of the Earth and most asteroids are very distant from each other in terms of delta-v and the asteroidal bodies have enormous momentum. Rockets or mass drivers can perhaps be installed on asteroids to direct their path into a safe course.

Statites or "static satellites" employ solar sails to position themselves in orbits that gravity alone could not accomplish. Such a solar sail colony would be free to ride solar radiation pressure and travel off the ecliptic plane. Navigational computers with an advanced understanding of flocking behavior could organize several statite colonies into the beginnings of the true "swarm" concept of a Dyson sphere.

Looking beyond our solar system, there are billions of potential suns with possible colonization targets.

Physicist Stephen Hawking has said:^[3][4]

The long-term survival of the human race is at risk as long as it is confined to a single planet. Sooner or later, disasters such as an asteroid collision or nuclear war could wipe us all out. But once we spread out into space and establish independent colonies, our future should be safe. There isn't anywhere like the Earth in the solar system, so we would have to go to another star.

Space colonization technology could in principle allow human expansion at high, but sub-relativistic speeds, substantially less than the speed of light, c.  An interstellar colony ship would be similar to a space habitat, with the addition of major propulsion capabilities and independent energy generation. Hypothetical starship concepts proposed both by scientists and in hard science fiction include:

• A generation ship would travel much slower than light, with consequent interstellar trip times of many decades or centuries. The crew would go through generations before the journey is complete, so that none of the initial crew would be expected to survive to arrive at the destination, assuming current human lifespans.
• A sleeper ship, in which most or all of the crew spend the journey in some form of hibernation or suspended animation, allowing some or all who undertake the journey to survive to the end.
• An Embryo-carrying Interstellar Starship (EIS), much smaller than a generation ship or sleeper ship, transporting human embryos or DNA in a frozen or dormant state to the destination. (Obvious biological and psychological problems in birthing, raising, and educating such voyagers, neglected here, may not be fundamental.)
• A nuclear fusion or fission powered ship (eg, ion drive) of some kind, achieving velocities of up to perhaps 10% c  permitting one-way trips to nearby stars with durations comparable to a human lifetime.
• A Project Orion-ship, a nuclear-powered concept proposed by Freeman Dyson which would use nuclear explosions to propel a starship. A special case of the preceding nuclear rocket concepts, with similar potential velocity capability, but possibly easier technology.
• Laser propulsion concepts, using some form of beaming of power from the Solar System might allow a light-sail or other ship to reach high speeds, comparable to those theoretically attainable by the fusion-powered electric rocket, above. These methods would need some means, such as supplementary nuclear propulsion, to stop at the destination, but a hybrid (light-sail for acceleration, fusion-electric for deceleration) system might be possible.

The above concepts all appear limited to high, but still sub-relativistic speeds, due to fundamental energy and reaction mass considerations, and all would entail trip times which might be enabled by space colonization technology, permitting self-contained habitats with lifetimes of decades to centuries. Yet human interstellar expansion at average speeds of even 0.1% of c  would permit settlement of the entire Galaxy (assuming it is not inhabited already) in less than one half of a galactic rotation period of ~250,000,000 years, which is comparable to the timescale of other galactic processes. Thus, even if interstellar travel at near relativistic speeds is never feasible (which cannot be clearly determined at this time), the development of space colonization could allow human expansion beyond the Solar System without requiring technological advances that cannot yet be reasonably foreseen. This could greatly improve the chances for the survival of intelligent life over cosmic timescales, given the many natural and human-related hazards that have been widely noted.

The star Tau Ceti, about eleven light years away, has an abundance of cometary and asteroidal material in orbit around it. These materials could be used for the construction of space habitats for human settlement.

The most famous attempt to build an analogue to a self-sufficient colony is Biosphere 2, which attempted to duplicate Earth's biosphere.

Many space agencies build testbeds for advanced life support systems, but these are designed for long duration human spaceflight, not permanent colonization.

Remote research stations in inhospitable climates, such as the Amundsen-Scott South Pole Station or Devon Island Mars Arctic Research Station, can also provide some practice for off-world outpost construction and operation. The Mars Desert Research Station has a habitat for similar reasons, but the surrounding climate is not strictly inhospitable.

In animation Mobile Suit Gundam (1979–1980), space colonization has undergone for long, but a war has broken out as a result in unfair policy on people in space colonies.

The literature for space colonization began in 1869 when Edward Everett Hale wrote about an inhabited artificial satellite.^[5]

The Russian schoolmaster and physicist Konstantin Tsiolkovsky foresaw elements of the space community in his book Beyond Planet Earth written about 1900. Tsiolkovsky had his space travelers building greenhouses and raising crops in space.^[6]

Others have also written about space colonies as Lasswitz in 1897 and Bernal, Oberth, Von Pirquet and Noordung in the 1920s. Wernher von Braun contributed his ideas in a 1952 Colliers article. In the 1950s and 1960s, Dandridge M. Cole^[7] published his ideas.

Another seminal book on the subject was the book The High Frontier: Human Colonies in Space by Gerard K. O'Neill^[8] in 1977 which was followed the same year by Colonies in Space by T. A. Heppenheimer.^[9]

M. Dyson wrote Home on the Moon; Living on a Space Frontier in 2003;^[10] Peter Eckart wrote Lunar Base Handbook in 2006^[11] and then Harrison Schmitt's Return to the Moon written in 2007.^[12]

In 2001, the space news website Space.com asked Freeman Dyson, J. Richard Gott and Sid Goldstein for reasons why some humans should live in space. Their respective answers were:^[13]

• Spread life and beauty throughout the Universe
• Ensure the survival of our species
• Make money from solar power satellites, asteroid mining, and space manufacturing
• Save the environment of Earth by moving people and industry into space
• Provide entertainment value in order to distract from immediate surroundings
• Ensure sufficient supply of rare materials, including from the Outer Solar System – natural gas (in connection with expected world-wide hydrocarbons peak) and drinking water (in connection with expected world-wide water shortage)

Louis J. Halle, formerly of the United States Department of State, wrote in Foreign Affairs (Summer 1980) that the colonization of space will protect humanity in the event of global nuclear warfare.^[14]

The scientist Paul Davies also supports the view that if a planetary catastrophe threatens the survival of the human species on Earth, a self-sufficient colony could "reverse-colonize" the Earth and restore human civilization.

The author and journalist William E. Burrows and the biochemist Robert Shapiro proposed a private project, the Alliance to Rescue Civilization, with the goal of establishing an off-Earth backup of human civilization.^[15]

Another important reason used to justify space is the effort to increase the knowledge and technological abilities of humanity.

Szablon:Weasel words

Colonizing space can be viewed as too expensive and a waste of time.

The argument to live together on the earth we have suggests that if even half the money of space exploration were spent for terrestrial betterment, there would be greater good for a greater number of people, at least in the short term. This assumes that money not spent on space would go toward socially beneficial projects. It also assumes that space colonization is not itself a sufficiently valuable goal (see Space and survival).

Other objections include concern about creating a culture in which humans are no longer seen as human, but rather as material assets. The issues of human dignity, morality, philosophy, culture, bioethics, and the threat of megalomaniac leaders in these new "societies" would all have to be addressed in order to space colonization to meet the psychological and social needs of people living in isolated colonies or generation ships. Although they are not being utilized yet, cultural anthropologists may have something to offer to the space programs.

As an alternative or addendum for the future of the human race, many science fiction writers have focused on the realm of the 'inner-space', that is the computer aided exploration of the human mind and human consciousness.

The argument of need: The population of Earth continues to increase, while its carrying capacity and available resources do not. If the resources of space are opened to use and viable life-supporting habitats can be built, the Earth will no longer define the limitations of growth (see extraterrestrial population growth).

The argument of cost: Very many people greatly overestimate how much money is spent on space, and underestimate how much money is spent on defense or health care. For example, as of 2008, over $845 billion has been spent on the current war in Iraq. In comparison, it only cost $2 billion to create the Hubble Space Telescope, and NASA's annual budget averages only about $16 billion. In other words, the money that has been spent on the Iraq war could have theoretically funded NASA for approximately 52 years.^[16]

The argument of Nationalism: Space proponents counter this argument by pointing out that humanity as a whole has been exploring and expanding into new territory since long before Europe's colonial age, going back into prehistory (the nationalist argument also ignores multinational cooperative space efforts); that seeing the Earth as a single, discrete object instills a powerful sense of the unity and connectedness of the human environment and of the immateriality of political borders; and that in practice, international collaboration in space has shown its value as a unifying and cooperative endeavor.

The argument of 'Inner Space': This form of exploration need not be exclusive to space colonization, as exemplified for example by Transhumanist philosophies.

Space advocacy organizations:

• The Alliance to Rescue Civilization plans to establish backups of human civilization on the Moon and other locations away from Earth.
• The Colonize the Cosmos site advocates orbital colonies.^[17]
• The Artemis Project plans to set up a private lunar surface station.
• The British Interplanetary Society, founded in 1933, is the world's longest established space society.
• The Living Universe Foundation has a detailed plan in which the entire galaxy is colonized.
• The Mars Society promotes Robert Zubrin's Mars Direct plan and the settlement of Mars.
• The National Space Society is an organization with the vision of "people living and working in thriving communities beyond the Earth."
• The Planetary Society is the largest space interest group, but has an emphasis on robotic exploration and the search for extraterrestrial life.
• The Space Frontier Foundation promotes strong free market, capitalist views about space development.
• The Space Settlement Institute is searching for ways to make space colonization happen in our lifetimes.^[18]
• The Space Studies Institute was founded by Gerard K. O'Neill to fund the study of space habitats.
• Students for the Exploration and Development of Space (SEDS) is a student organization founded in 1980 at MIT and Princeton.^[19]
• Foresight Nanotechnology Institute – The space challenge.^[20]

Although established space colonies are a stock element in science fiction stories, fictional works that explore the themes, social or practical, of the settlement and occupation of a habitable world are much rarer. The following list is restricted to works dealing primarily with the initial stages of colonization.

• Coyote: A Novel of Interstellar Revolution (2002) by Allen Steele. Adventure story involving the colonization of a planet of 47 Ursae Majoris.
• Farmer in the Sky (1950) by Robert A. Heinlein. A family joins a not-yet-successful colony on Ganymede.
• The Martian Chronicles (1950) by Ray Bradbury. Describes the exploration, settlement, and abandonment of colonies on Mars, in a poetic but unrealistic way.
• Red Mars (1992) by Kim Stanley Robinson. Explores the initial stages of development of a Martian colony

• Alien Legacy (1994), computer game. Player has to manage new colonies on the planets of Beta Caeli.
• Ascendancy (1995), computer game. Player tries to grow a colony into a spacefaring civilization.
• Halo (2001), computer game. Player fights for Earth's colonies against the alien Covenant.
• Outpost (1994), computer game. Player plans and manages a colony on another planet.
• Outpost 2 (1997), computer game. Player manages a colony on the fictional planet of New Terra.
• Sid Meier's Alpha Centauri (1999), computer game. Player tries to expand a human colony on Alpha Centauri.
• Starfarers of Catan (1999), tabletop game. Player manages trade and colonization in the fictional planetary system of Catan.
• Freelancer Players can explore several planets and systems colonized centuries prior to the start of the game.
• Starlancer Several colonies located on planets in the Sol systems are mentioned throughout the game.
• Marathon A early game by Bungie that show a human generation ship, fighting off alien slavers on their way to Tau Ceti.
• Gradius Gaiden The player uses the Vic Viper and 3 other craft to defend planet Gradius and it's colonies against unknown forces from the Dark Nebula.
• Mass Effect

• 2001 Nights (1996) by Yukinobu Hoshino. Includes stories relating to problems of colonization.

• Battlestar Galactica (1978–1979) and (2003-present), a television franchise. In both series, mankind lives on the Twelve Colonies as well as the thirteenth colony of Earth, having evolved on the planet Kobol.
• Gundam (1979-present), anime television franchise beginning with Mobile Suit Gundam (1979–1980). The series as well as its sequels and spin-offs mostly revolve around the conflicts between the Earth and the space colonies.
• Macross (1982-present) or Robotech (1985), anime television franchise. The series and its sequels mostly revolve around space colony fleets known as "Macross".
• Earth 2 (1994–1995), television series. A refugee group travels to and tries to colonize a distant Earth-like planet.
• Firefly (2002–2003), a television series. The series, and the followup film Serenity, dealt with a mass exodus from an overcrowded Earth to a new solar system, involving the terraforming and colonisation of these new worlds.
• Planetes (2003–2004), anime series. Humanity has colonized parts of Earth's Moon and Mars.
• Doctor Who (2005–present), television series. The Great and Bountiful Human Empire is repeatedly mentioned to have sent colonists into different parts of space, sometimes interfering with or even destroying native species.

• 2300 AD (1987) by Game Designers Workshop, a role playing game. Mankind has colonized about 30 planets and found 8 different alien civilizations.

• Szablon:HSW
• American Institute of Aeronautics and Astronautics (AIAA) Space Colonization Technical Committee (SCTC) [1]
• "Is the surface of a planet really the right place for expanding technological civilization?" Interviewing Gerard O'Neill
• Biological Effects of Weightlessness
• space colony – The Encyclopedia of Astrobiology, Astronomy, and Spaceflight
• Visualizing the Steps of Solar System Colonization
• HobbySpace: Life in Space: Section C: Colonies, Habitats, Space Industry, etc Extensive collection of links
• Orbital Space Settlements NASA's orbital space habitats site, which includes a contest for K-12 students
• The Political Economy of Very Large Space Projects John Hickman argues that only government can afford the high initial investment for very large space development projects.
• Spaceflight or Extinction Academics and other leaders explain that we should colonize space to improve our chance of survival. Authors include Stephen Hawking and Carl Sagan.
• Using space colonization to prevent the end of civilization Academic Paper
• PERMANENT Projects to Employ Resources of the Moon and Asteroids Near Earth in the Near Term; a guide to websites about asteroid mining and space settlement.
• Mars colonization:
  • http://mars.esa.int
  • http://mars.jpl.nasa.gov/mer
• Testimony of Michael D. Griffin Hearing on "The Future of Human Space Flight". Michael D. Griffin believes that the "human space flight program is in the long run possibly the most significant activity in which our nation is engaged".
• Island One Society – ideas about libertarian space colonization.
• National Space Society – non-profit organization that promotes a spacefaring civilization.
• 4Frontiers Corporation – for profit company pursing a number of technology, education and entertainment ventures related to Mars settlement.
• Mars Foundation – Non-Profit Organization pursing public outreach and technology development for Mars settlement.

Szablon:Solar System

Category:Space exploration Category:Space