Difference between revisions of "Colonization of the solar system"

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== External links ==
 
== External links ==
  
* Wikipedia: [https://en.wikipedia.org/wiki/Space_colonization Space colonization]
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Wikipedia:  
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* [https://en.wikipedia.org/wiki/Space_colonization Space colonization]
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* [https://en.wikipedia.org/wiki/List_of_natural_satellites List_of_natural_satellites]

Revision as of 14:49, 18 June 2021

Beside earth the sum of all rocky planets and dwarf planets do not provide much more surface area. Often conditions are very harsh (e.g. high radioactivity on europa). Note that there might be a lot of big transneptunian objects (TNOs) like Pluto missing in this list. Those are hard to reach though.
Planet Ceres (a dwarf planet). Located in the main asteroid belt between Mars and Jupiter it is the nearest big "waterworld" to Earth and perhaps a very attractive target for colonization. Ceres is about 1000km in diameter and the only object in the asteroid belt that is spherical due to it's own gravity. Ceres is similar in size to Saturns moon Thetys (see above image for scale). Image Credit: NASA / JPL-Caltech / UCLA / MPS / DLR / IDA / Justin Cowart


Up: Spaceflight with gem-gum-tec

This page is about how advanced atomically precise manufacturing may be usable to colonize interplanetary space. The focus is on possibilities that are relatively near term (under a century). If more far term stuff comes up this will be especially noted.

Bodies with dense atmospheres ★

Atmospheres can deliver building materials in the easiest usable (do not use "digestable"!) standardized form.


  • Mercury (planet) (the tiniest of our planets) - hard to reach because high delta-v from earth
  • Venus - is paradise for atomically precise manufacturing
  • Earth - seasteading
  • Mars (the second tiniest planet)
    He has an rather thin atmosphere that for humans equals a full vacuum (spacesuit needed).
    But it is still plenty thick enough to be usable as a building material.
  • Asteroid belt - advantages: big surface and area low gravity
  • Ceres - nearest waterworld
  • Psyche - biggest metallic planetary core remnant
  • Ganymede and Callisto - are Jupiters two outermost (and thus least radiation bombarded) planet sized galileian moons
  • Io and Europa - volcanic and radiation grilled - challenging
  • Titan - is Saturns only planet sized moon with an atmosphere that surpasses the one of Earth.
  • Gas giants
  • Triton - biggest moon of Neptune with cryovolcanism
  • Transneptunian objects like Pluto and Charon

Interestingly there are no objects in our solar system with liquid nitrogen oceans on the surface. Titan escapes that fate barely.
Also there are no ones with and liquid hydrogen/helium on the surface (this would need to be big objects very far out so it may be less certain).

Asteroids in the main belt between Mars and Jupiter

The main asteroid belt lies between Mars and Jupiter. Jupiter with its gravitational disturbances played a role in creating it.
There is lots of planetary core material flying around in the main asteroid belt. Shown here is a chunk of "pallasite". A material that is believed to be present in large quantities at the core mantle boundary of larger rocky planets. The green parts are olivine. An iron rich silicate.
  • pro: no gravity traps
  • pro: enormous accessible surface area - probably way greater than all the planets and moons together
  • pro: just the right temperature for the presence of a variety of materials => …
  • pro: … most unobstructed access to the perhaps the most interesting and useful group of elements
    lithophile element, chalkophile elements, and a maybe somewhat limited amount of atmophile (aka volatile) elements.

Meteoroids coming from these (and recent space missions 2020) give us info about the element distribution to expect.
See: Carbonaceous chondrites

  • con: all the material is in the solid state requiring complex mining.
    Well Ceres seems to have some subsurface briny water inside.
  • con: there is quite a bit less solar energy than on earth - but it is still enough to be useful
  • con: laggy telecommunication in a dispersed net due to light-speed run-times

M-type asteroids

These asteroids are essentially pieces of smashed up/open proto-planetrary cores.
They are giving us the only option to physically access pretty much the same material environment that is present very very deep within out earth. A material environment that will likely remain inaccessible even with advanced APM available. Check out the deep drilling page for details).

Setting up base at one of these asteroids would/will allow access to huge amounts siderophile elements (see Goldschmidt classification) These elements include Gold Au Platinum Pt and Iridium (among others) and are much more scarce on earth because they are highly depleted in our Earths crust.

Still, most interesting elements for large scale construction with advanced APM remain the most common ones.

Iron: First and foremost in M-type asteroids there is are huge amounts of iron.
This is presumably due to iron having the lowest energy per nucleon and thus being the "nuclear ash" final end product that cannot be further fusioned or fissioned any further.
(wiki-TODO: maybe add the classic energy per nucleon chart for illustration here)
And of course due to its high specific weight making it sink to protoplanetrary cores (aka the process of "differentiation").

  • Con: Iron does not form very strong gemstones with oxygen.
  • Pro: In space iron does not rust since there is no oxygen around.
  • Pro: Also as a metal with an electron gas iron may feature a bit more self healing after mild radiation hits.
  • Con: Pure metals such as iron are not optimal for APM but they can be used as long as some conditions are met which are:
  • -- (1) for preventing surface diffusion: operation at low temperatures (e.g. far out the solar system) and/or flat surfaces
  • -- (2) to prevent irreversible seamless welding: keeping nanoscale surfaces from coming too close together

Nickel: Nickel is usually mentioned as the second most common element in earths core but …
When checking out the compositions of metallic meteroids it seems that there is actually very little nickel in there and athere elements take second place. (TODO: investigate what is going on here a bit deeper)

(TODO: list most common elements beyond iron)

Bodies in the outer solar system

Here considered outer solar system: Jupiter beyond [[1]] all the way out to the Oorth cloud.

These are usually covered in thick sheets of structurally mostly useless ices like water ice ammonia ice or (when really far out) even methane ice and nitrogen ice. One exception to this "rule" is Jupiters innermost giant moon Io which got/gets tidally heated so much that it volcanically evaporated off all of its volatile elements despite its large distance to the sun. At least that is the naive conclusion from observations.

The only in bulk structural useful ices from volatile elements are dry-ice (CO2) an methane-ice (CH4) due to their carbon content. Titans Hydrocarbon lakes can be counted to that.

Moons and dwarf planets in the outer solar system

Furter out in the solar system small bodies become increasingly icy. Water ice and at some point even nitrogen ice becomes rock forming material. If not enough carbon and silicon is present one might want to mechanosynthesize weaker bonding ices there and use those materials for not too demanding structural purposes

Flavors of diamondoid gem gum technology

Vastly differing chemical and thermal conditions at different places in the solar system could lead to differentiation (do not use "speciation"!) of diamondoid technology into very different branches.

Structures built out of water ice via cryonic inter-molecular mechanosynthesis wont find much use beside ephemeral consumables on earth since they quickly melt when uncooled or diffuse when insufficiently cooled. Further out and farther from the sun though ice and other compounds that are volatiles on earth can be seriously used as permanent building materials. This materials are also the most abundant materials in those regions so they are likely to be used.

Unlike methane water can't be safely polymerized to stuff that does not melt above 0°C. Long peroxide chains are a powerful explosives. Also oxygen polymers are un-branched linear chains and thus can't form tight meshed poly-cyclically looped covalent stiff diamondoid materials. So technology that uses only the elements oxygen and hydrogen for structural components (that is water) stays out there. Reasonably safely making explosive crystals from mostly water that do not melt will certainly be possible via mechanosynthesis since they can be made practically perfectly clean - the usefulness may be questionable.

  • Chemically reducing environments (nonoxidic compounds)
  • high temperature environments (refractory materials)
  • metal rich environments (planetary core material in the asteroid belt)

Related


External links

Wikipedia: