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Terraforming of Mars

From Wikipedia, the free encyclopedia

Artist's conception of the process of terraforming Mars.

The terraforming of Mars is the hypothetical process by which the climate, surface, and known properties of Mars would be deliberately changed with the goal of making it habitable by humans and other terrestrial life, thus providing the possibility of safe and sustainable colonization of large areas of the planet. The concept relies on the assumption that the environment of a planet can be altered through artificial means; the feasibility of creating a planetary biosphere is undetermined. There are several proposed methods, some of which present prohibitive economic and natural resource costs, and others which may be currently technologically achievable.^[1]

Reasons for terraforming

Background

Changes required

**Comparison of dry atmosphere**
	Mars	Earth
Pressure	0.6 kPa (0.087 psi)	101.3 kPa (14.69 psi)
Carbon dioxide (CO₂)	95.32%	0.04%
Nitrogen (N₂)	2.70%	78.08%
Argon (Ar)	1.60%	0.93%
Oxygen (O₂)	0.13%	20.94%

Artist's conception of a terraformed Mars centered on the Tharsis region

Artist's conception of a terraformed Mars. This portrayal is approximately centered on the prime meridian and 30° North latitude, and a hypothesized ocean with a sea level at approximately two kilometers below average surface elevation. The ocean submerges what are now Vastitas Borealis, Acidalia Planitia, Chryse Planitia, and Xanthe Terra; the visible landmasses are Tempe Terra at the left, Aonia Terra at the bottom, Terra Meridiani at the lower right, and Arabia Terra at the upper right. Rivers that feed the ocean at the lower right occupy what are now Valles Marineris and Ares Vallis, while the large lake at the lower right occupies what is now Aram Chaos.

Terraforming Mars would entail three major interlaced changes: building up the atmosphere, keeping it warm, and keeping the atmosphere from being lost to outer space. The atmosphere of Mars is relatively thin and thus has a very low surface pressure of 0.6 kilopascals (0.087 psi) (0.0059 atmospheres) and a pressure of 0.003 kilopascals (0.00044 psi) at the top of Olympus Mons (22 kilometres (14 mi)); compared to Earth with 101.3 kilopascals (14.69 psi) at sea level and 4.0 kilopascals (0.58 psi) at an altitude of 22 kilometres (14 mi). The atmosphere on Mars consists of 95% carbon dioxide (CO₂), 3% nitrogen, 1.6% argon, and contains only traces of oxygen, water, and methane. Since its atmosphere consists mainly of CO₂, a known greenhouse gas, once the planet begins to heat, the CO₂ may help to keep thermal energy near the surface. Moreover, as the planet heats, more CO₂ should enter the atmosphere from the frozen reserves on the poles, enhancing the greenhouse effect. This means that the two processes of building the atmosphere and heating it would augment one another, favoring terraforming.
The tremendous air currents generated by the moving gasses would create large, sustained dust storms, which would heat the atmosphere (by absorbing solar radiation)^{[citation needed]}.
Artificially creating a magnetosphere would assist in retaining the atmosphere. See the sections below on Magnetic field and Solar radiation for the benefits of a magnetosphere.

Carbon dioxide sublimation

There is presently enough carbon dioxide (CO₂) as ice in the Martian south pole and absorbed by regolith (soil) around the planet that, if sublimated to gas by a climate warming of only a few degrees, would increase the atmospheric pressure to 300 millibars,^[6] comparable to twice the altitude of the peak of Mount Everest. While this would not be comfortably breathable by humans, it would eliminate the present need for pressure suits, melt the water ice at Mars's north pole (flooding the northern basin), and bring the year-round climate above freezing over approximately half of Mars's surface. This would enable^{[citation needed]} the introduction of plant life, particularly plankton in the new northern sea, to start converting the atmospheric CO₂ into oxygen. Phytoplankton can also convert dissolved CO₂ into oxygen, which is important because Mars's low temperature will, by Henry's law, lead to a high ratio of dissolved CO₂ to atmospheric CO₂ in the flooded northern basin.

Importing ammonia

Another, more intricate, method uses ammonia as a powerful greenhouse gas (as it is possible that large amounts of it exist in frozen form on asteroidal objects orbiting in the outer Solar System); it may be possible to move these (for example, by using nuclear bombs to blast them in the right direction) and send them into Mars's atmosphere.^[7] Since ammonia (NH₃) is high in nitrogen it might also take care of the problem of needing a buffer gas in the atmosphere. Sustained smaller impacts will also contribute to increases in the temperature and mass of the atmosphere.
The need for a buffer gas is a challenge that will face any potential atmosphere builders. On Earth, nitrogen is the primary atmospheric component, making up 78% of the atmosphere. Mars would require a similar buffer-gas component although not necessarily as much. Obtaining sufficient quantities of nitrogen, argon or some other comparatively inert gas is difficult.

Importing hydrocarbons

Another way would be to import methane or other hydrocarbons,^[8]^[9] which are common in Titan's atmosphere (and on its surface). The methane could be vented into the atmosphere where it would act to compound the greenhouse effect.
Methane (or other hydrocarbons) could be helpful to increase atmospheric pressure. These gases also can be used to produce water and CO₂ for the Martian atmosphere:

CH₄ + 4 Fe₂O₃ => CO₂ + 2 H₂O + 8 FeO

This reaction could probably be initiated by heat or by Martian solar UV irradiation. Large amounts of the resulting products (CO₂ and water) are necessary for photosynthesis, which would be the next step in terraforming.

Importing hydrogen

Hydrogen could be imported for atmosphere and hydrosphere engineering.^[10] For example, hydrogen could react with iron(III) oxide from the Martian soil, which would give water as a product:

H₂ + Fe₂O₃ => H₂O + 2FeO

Depending on the level of carbon dioxide in the atmosphere, importation and reaction of hydrogen would produce heat, water and graphite via the Bosch reaction. Alternatively, reacting hydrogen with the carbon dioxide atmosphere via the Sabatier reaction would yield methane and water.

Using fluorine compounds

Since long-term climate stability would be required for sustaining a human population, the use of especially powerful fluorine-bearing greenhouse gases possibly including sulfur hexafluoride or halocarbons such as chlorofluorocarbons (or CFCs) and perfluorocarbons (or PFCs) has been suggested.^[11] These gases are the most cited candidates for artificial insertion into the Martian atmosphere because they produce a strong effect as a greenhouse gas, thousands of times stronger than CO₂. This can conceivably be done relatively cheaply by sending rockets with payloads of compressed CFCs on collision courses with Mars.^[4] When the rockets crash onto the surface they release their payloads into the atmosphere. A steady barrage of these "CFC rockets" would need to be sustained for a little more than a decade while the planet changes chemically and becomes warmer.
In order to sublimate the south polar CO₂ glaciers, Mars would require the introduction of approximately 0.3 microbars of CFCs into Mars's atmosphere. This is equivalent to a mass of approximately 39 million metric tons. This is about three times the amount of CFC manufactured on Earth from 1972 to 1992 (when CFC production was banned by international treaty). Mineralogical surveys^{[citation needed]} of Mars have found significant amounts of the ores necessary to produce CFCs.
A proposal to mine fluorine-containing minerals as a source of CFCs and PFCs is supported by the belief that since these minerals are expected to be at least as common on Mars as on Earth, this process could sustain the production of sufficient quantities of optimal greenhouse compounds (CF₃SCF₃, CF₃OCF₂OCF₃, CF₃SCF₂SCF₃, CF₃OCF₂NFCF₃) to maintain Mars at 'comfortable' temperatures, as a method of maintaining an Earth-like atmosphere produced previously by some other means.^[11]

Orbiting mirrors

Mirrors made of thin aluminized PET film could be placed in orbit around Mars to increase the total insolation it receives.^[1] This would direct the sunlight onto the surface and could increase the planet's surface temperature directly. The mirror could be positioned as a statite, using its effectiveness as a solar sail to orbit in a stationary position relative to Mars, near the poles, to sublimate the CO₂ ice sheet and contribute to the warming greenhouse effect.

Albedo

Reducing the albedo of the Martian surface would also make more efficient use of incoming sunlight.^[12] This could be done by spreading dark dust from Mars's moons, Phobos and Deimos, which are among the blackest bodies in the Solar System; or by introducing dark extremophile microbial life forms such as lichens, algae and bacteria. The ground would then absorb more sunlight, warming the atmosphere.
If algae or other green life were established, it would also contribute a small amount of oxygen to the atmosphere, though not enough to allow humans to breathe. On 26 April 2012, scientists reported that lichen survived and showed remarkable results on the adaptation capacity of photosynthetic activity within the simulation time of 34 days under Martian conditions in the Mars Simulation Laboratory (MSL) maintained by the German Aerospace Center (DLR).^[13]^[14]

Asteroid impact

Another way to increase the temperature could be to direct small asteroids onto the Martian surface; the impact energy would be released as heat. This heat could sublimate CO₂ or, if there is liquid water present at this stage of the terraforming proccess, could vaporize it to steam, which is also a greenhouse gas. Asteroids could also be chosen for their composition, such as ammonia, which would then disperse into the atmosphere on impact, adding greenhouse gases to the atmosphere. Lightning may have built up nitrate beds in the soil over the life of the planet.^[6] Impacting asteroids on these nitrate beds would release additional nitrogen and oxygen into the atmosphere.

Magnetic field

The thin atmosphere on Mars may be partly due to it lacking a magnetosphere. Energy from the solar wind enables particles in the top atmospheric layer to reach escape velocity and leave Mars. Indeed, this effect has even been detected by Mars-orbiting probes. Another theory is that solar wind rips the atmosphere away from the planet as it becomes trapped in bubbles of magnetic fields called plasmoids.^[15] Venus, however, shows that the lack of a magnetosphere does not preclude a dense atmosphere (albeit a dry one).
A thick atmosphere could also provide protection against solar radiation, similar to Earth's. In the past, Earth has regularly had periods where the magnetosphere changed direction and collapsed for some time.^[16]
Earth abounds with water because its ionosphere is permeated with a magnetic field. The hydrogen ions present in its ionosphere move very fast due to their small mass, but they cannot escape to outer space because their trajectories are deflected by the magnetic field. Venus has a dense atmosphere, but only traces of water vapor (20 ppm) because it has no magnetic field. The Martian atmosphere also loses water to space.
Earth's ozone layer provides additional protection. Ultraviolet light is blocked before it can dissociate water into hydrogen and oxygen. Since little water vapor rises above the troposphere and the ozone layer is in the upper stratosphere, little water is dissociated into hydrogen and oxygen.

Solar radiation

Mars would be uninhabitable to most life-forms due to high solar radiation levels.^[17]^[18]^[19] Without a protective magnetic field, colonists would be exposed to increased cosmic ray flux. The health threat depends on the flux, energy spectrum, and nuclear composition of the rays. The flux and energy spectrum depend on a variety of factors, which are incompletely understood. The Mars Radiation Environment Experiment (MARIE) was launched in 2001 in order to collect more data.
Estimates are that humans unshielded in interplanetary space would receive annually roughly 400 to 900 millisieverts (mSv) (compared to 2.4 mSv on Earth) and that a Mars mission (12 months in flight and 18 months on Mars) might expose shielded astronauts to ~500 to 1000 mSv.^[20] These doses approach the 1 to 4 Sv career limits advised by the National Council on Radiation Protection and Measurements for Low Earth orbit activities.
Shielding from cosmic rays can be accomplished by placing habitation modules either within lava tubes or under igloo structures built from sintered regolith bricks.^[21]

Fossil Evidence of Early Life

Friday, August 3, 2012

Pictures