Difference between revisions of "Diamondoid waste incineration"
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= Further topics = | = Further topics = | ||
− | * [[ | + | * [[Refractory materials]] |
* [[Recycling]] | * [[Recycling]] | ||
* [[Atomically precise disassembly]] | * [[Atomically precise disassembly]] | ||
+ | * [[Soil processing]] in [[mining]] for [[resource molecules]] | ||
+ | * [[Gem-gum waste dissolution]] | ||
* [[Gem-gum waste crisis]] | * [[Gem-gum waste crisis]] | ||
* Products made from [[common stones]] are as incombustible as these stones | * Products made from [[common stones]] are as incombustible as these stones | ||
* [[Rock digestion chamber]] | * [[Rock digestion chamber]] | ||
+ | * [[Hot gas phase recycling cycle]] | ||
[[Category:Technology level III]] | [[Category:Technology level III]] | ||
[[Category:Site specific definitions]] | [[Category:Site specific definitions]] |
Latest revision as of 12:50, 15 February 2024
Ultimately damaged diamondoid AP products (microcomponents or macro sized parts) beyond the poit where they can be recycled often do hardly decay by themselves. If badly designed they may even release DME - splinters in the environment so they need to be burnt or disintegrated to reusable or harmless substances in an other way. Conventional furnaces will probably suffice but AP manufactured combustion cells for microcomponents or makro objects are desirable nontheless. They may be able to better filter combustion fumes and also better solve other issues. - Reseach needed.
For now a list of potential diamondoid refractory materials can be found at the "consistent design for external limiting factors" page.
Contents
Slacks
The oxides of the elements C,H,O,N,S are all gasses thus if the product to dispose of contains only those elements it can be completely burned to gasses. If other elements are included burning will produce an amorphous glassy slack which may be very hard to recycle.
On the positive side products that form large amounts of slack have the tendency to self quench large fires. (See: Design of crystolecules)
Maybe possible ways to regain molecular feed-stocks from slack
Hydrogenation
Heating parts up in a hot and dense hydrogen atmosphere might be usable to extend the list of elements that can be reverted to easy to process resource gasses. e.g. Silicon -> Silane.
Making soluble with sodium
Melting sodium into low melting slacks or shooting sodium ions into refractory waste might do the trick since sodium compounds have a tendency to be water soluble - silicon and aluminum can be solvated that way. (this method should also be usable for dissolving hard rock in underground working - sodium silicate is actually used as drilling fluid today)
- Na4O4Si sodium orthosilicate - molecular non polymeric from - few data available - (wikipedia (de))
- Na2SiO3 sodium silicate (wikipedia) - chain polymeric form
- NaXAlYOZ sodium aluminates (wikipedia (de)) - also used for removing transition metal salts from water
Microcomponents
- Microcomponents are a lot easier to burn since their large surface area in relation to their volume.
- Also its easier too keep them free of elements that produce oxidic slacks. If documented they can be seperated regarding their composition and disposed of seperately such that elements do not mix too much.
- Microcomponents could maybe be put into a beam of ionized oxygen such that walls can be magnetically protected.
Chlorine
Chlorine is an interesting case. When burning organochlorides (or diamondchlorides with similar elemental composition) usually toxic combustion byproducts are produced.
Although Chlorine is an abundant element (huge amounts in the sea) and it can form sturdy bonds to carbon molecular biology almost doesn't make use of it in biomolecules but instead only uses it as ions (it is an essential element). [Todo: find out why] Only very few natural occuring organochlorides (wikipedia) are known that occur in notable quantities (examples: bipyrrol Q1, chlormethane).
Further topics
- Refractory materials
- Recycling
- Atomically precise disassembly
- Soil processing in mining for resource molecules
- Gem-gum waste dissolution
- Gem-gum waste crisis
- Products made from common stones are as incombustible as these stones
- Rock digestion chamber
- Hot gas phase recycling cycle