Difference between revisions of "Lunar Aluminum Production"

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Our satellite lacks of bauxite, therefore, anorthite will be used instead.<ref>http://www.permanent.com/l-minera.htm#aluminum</ref> [[Anorthite]] (CaAl<sub>2</sub>Si<sub>2</sub>O<sub>8</sub>) could be separed from [[Anorthosite]] with mechanical and chemical methods to produce [[Alumina]] (aluminium oxide, Al<sub>2</sub>O<sub>3</sub>). <ref> http://en.wikipedia.org/wiki/Anorthosite</ref>
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Luna lacks bauxite, therefore, anorthite will be used for Aluminium production instead.<ref>http://www.permanent.com/l-minera.htm#aluminum</ref> [[Anorthite]] (CaAl<sub>2</sub>Si<sub>2</sub>O<sub>8</sub>) could be separated from [[Anorthosite]] with mechanical and chemical methods to produce [[Alumina]] (aluminium oxide, Al<sub>2</sub>O<sub>3</sub>).  
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There are several proposed methods to obtain aluminium (even ones that do not require electrolysis). However, almost all require the importation of catalysts and/or reactants. It is true that reactants can be recycled but they limit the total output to the total amount of reactant present and to the speed that the process can recycle them. Another process would be [[Ion-sputtering]] to obtain other material and as a residue [[Aluminium]].
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Aluminium is a strong reducing agent, therefore it requires special conditions to reduce it with carbon.  
  
There are several proposed methods to obtain aluminium (even those that doesn't require electrolysis). However, almost all include an importation of catalysts and/or reactants. It is true that reactants can be recycled but they limit the total output to the total amount of reactant present and to the speed that the process can recycle them. Another process would be [[Ion-sputtering]] to obtain other material and as a residue [[Aluminium]].
 
Aluminium is a strong reducing agent, therefore it cannot undergo a normal [[Reduction]] by carbon. <ref>http://en.wikipedia.org/wiki/Anorthite</ref>
 
  
 
== Proposed Anorthite Production Process ==
 
== Proposed Anorthite Production Process ==
  
Anorthosite is a mix of [[Plagioclase]]s, [[Olivine]]s, and [[Pyroxene]]s. To separate the anorthite, anorthosite a must be grind. Then, magnets could be put in contact with the powder to separate everything from the non-magnetic anorthite.
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Anorthosite is a mix of [[Plagioclase]]s, [[Olivine]]s, and [[Pyroxene]]s. To separate the anorthite, anorthosite must be ground. Then, magnetic separation could leave the non-magnetic anorthite.  Other means would separate silicon, calcium and magnesium.
  
The magnetic materials (even [[Ilmenite]], iron oxide, silica and magnesia) could be stored for production of [[Titanium]] and other metals.
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The magnetic materials ([[Ilmenite]] and iron oxide) could be stored for production of [[Titanium]], iron and oxygen.
  
 
== Proposed Alumina Production Process ==
 
== Proposed Alumina Production Process ==
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On Earth aluminium is subjected to the Hall-Heroult process where bauxite undergoes the Bayer process to become alumina.
 
On Earth aluminium is subjected to the Hall-Heroult process where bauxite undergoes the Bayer process to become alumina.
  
On the Moon [[Alumina]] could be produced from Anorthite by boiling the impurities (between 1500 ºC - 2000 ºC ). The resulting material would be calcium aluminate (CaAlO<sub>4</sub>). That can be leached in sulfuric acid. The following reaction would be:
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On the Moon [[Alumina]] could be produced from Anorthite by boiling out the impurities (between 1500 ºC - 2000 ºC ). The resulting material would be calcium aluminate (CaAlO<sub>4</sub>). That can be leached in sulfuric acid. The following reaction would be:
  
 
CaAl<sub>2</sub>O<sub>4</sub> + 4H<sub>2</sub>SO<sub>4</sub> ==> CaSO<sub>4</sub> + Al<sub>2</sub>(SO<sub>4</sub>)<sub>3</sub> + 4H<sub>2</sub>O
 
CaAl<sub>2</sub>O<sub>4</sub> + 4H<sub>2</sub>SO<sub>4</sub> ==> CaSO<sub>4</sub> + Al<sub>2</sub>(SO<sub>4</sub>)<sub>3</sub> + 4H<sub>2</sub>O
  
Aluminium sulfate in hexadecahydrate form (Al<sub>2</sub>(SO<sub>4</sub>)<sub>3</sub>) is then separated from calcium sulphate (CaSO<sub>4</sub> + Al<sub>2</sub>(SO<sub>4</sub>)<sub>3</sub>) by filtering and from water by evaporation (and then recovered).
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Aluminium sulfate in hexadecahydrate form (Al<sub>2</sub>(SO<sub>4</sub>)<sub>3</sub>) is then separated from calcium sulphate (CaSO<sub>4</sub> + Al<sub>2</sub>(SO<sub>4</sub>)<sub>3</sub>) by filtering and from water by evaporation (and then recovered).  
  
 
Finally Alumina is obtained by roasting the aluminium sulfate releasing S<sub>2</sub>.<ref>http://www.moonminer.com/Lunar_Aluminum.html</ref>
 
Finally Alumina is obtained by roasting the aluminium sulfate releasing S<sub>2</sub>.<ref>http://www.moonminer.com/Lunar_Aluminum.html</ref>
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Alumina is dissolved in molten cryolite ([[Sodium]] hexafluoroaluminate, Na<sub>3</sub> AlF<sub>6 </sub>) around 1400 ºC. This mix is electrolyzed to separate two byproducts: aluminium and CO<sub>2</sub>.
 
Alumina is dissolved in molten cryolite ([[Sodium]] hexafluoroaluminate, Na<sub>3</sub> AlF<sub>6 </sub>) around 1400 ºC. This mix is electrolyzed to separate two byproducts: aluminium and CO<sub>2</sub>.
  
Pure alumina can be electrolyzed, but, it melts around the impractical 2000 ºC without the addition of cryolite. It is not known how refractory containers are going to be made on the Moon, neither if the Hall-Heroult process can be adapted with or without the importation of fluorine for the cryolite.<ref>http://en.wikipedia.org/wiki/Hall-H%C3%A9roult_process</ref>
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Pure alumina can be electrolyzed, but, it melts around the impractical 2000 ºC without the addition of cryolite. It is not known how refractory containers are going to be made on the Moon, nor whether the Hall-Heroult process can be adapted with or without the importation of fluorine for the cryolite.<ref>http://en.wikipedia.org/wiki/Hall-H%C3%A9roult_process</ref>
  
 
== Subchloride Process ==
 
== Subchloride Process ==
  
Chlorine and carbon would be imported from Earth. The alumina is then carbochlorinated (carbonated and chlorinated) to yeild AlCl<sub>3</sub> which is electrolyzed. Electrolysis of AlCl<sub>3</sub> does not consume the precious lunar carbon electrodes as does conventional Hall-Heroult electrolysis of alumina.  The carbochlorination byproduct CO<sub>2</sub> must be [[recycled]]. <ref>http://www.moonminer.com/Lunar_Aluminum.html</ref>
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Chlorine and carbon would be imported from Earth. The alumina is then carbochlorinated (carbonated and chlorinated) to yeild AlCl<sub>3</sub> which is electrolyzed. Electrolysis of AlCl<sub>3</sub> does not consume the precious lunar carbon electrodes as does conventional Hall-Heroult electrolysis of alumina.  The carbochlorination byproduct CO<sub>2</sub> must be [[recycled]]. <ref>http://www.moonminer.com/Lunar_Aluminum.html </ref>
  
 
== Proposed Carbothermal Reduction ==
 
== Proposed Carbothermal Reduction ==
  
Carbon would be imported from Earth. Then the alumina would be mixed with silica and carbon and melted near 2000 ºC. An aluminium-silicon alloy will form. This could be separated by cooling the Al-Si mixture to 700 ºC-1000 ºC. and the silicon will solidify and settle out of the melt. CO<sub>2</sub> must be recovered and carbon recycled. <ref>http://www.moonminer.com/Lunar_Aluminum.html</ref>
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Carbon would be imported from Earth. Then the alumina would be mixed with silica and carbon and melted near 2000 C. An aluminium-silicon alloy will form. This could be separated by cooling the Al-Si mixture to 700 -1000 C. and the silicon will solidify and settle out of the melt. CO<sub>2</sub> must be recovered and carbon recycled. <ref>http://www.moonminer.com/Lunar_Aluminum.html </ref>
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== Alternate Carbothermal Process == 
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Al<sub>2</sub>0<sub>3</sub> and carbon can be processed at high temperatures and low pressure into Al<sub>4</sub>C<sub>3</sub>.<ref> [http://en.wikipedia.org/wiki/Aluminium ''Aluminum'' section ''Production and refinement''] </ref>
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<ref> [http://www.moonminer.com/Lunar_Aluminum.html ''Lunar Aluminum'' at ''Moondust index''] </ref>  This breaks down into Aluminium and Carbon between 1900 and 2000 centigrade.  Carbon monoxide given off in processing<ref> [http://en.wikipedia.org/wiki/Aluminum_carbide ''Aluminium carbide'' at ''Wikipedia''] </ref> can be recycled into carbon.
  
 
== Other Electrolysis Methods ==
 
== Other Electrolysis Methods ==
  
There are two process that doesn't require importation on Earth.
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There are two process that do not require imported chemicals from Earth.
  
The first one is just boil the anothite and to obtain gases at different temperatures, first silica glass then calcium aluminate. With more temperature we obtain alumina and calcium oxide the temperature is reduced and the gases condensed and the liquid is electrolyzed to obtain aluminium, calcium and oxygen (all of them pure). This would require temperatures over 2560 ºC, very efficient super-refractories and a tremendous input of energy. <ref>http://www.moonminer.com/Lunar_Aluminum.html</ref>
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The first one is just boil the anothite and to obtain gases at different temperatures, first silica glass then calcium aluminate. With more temperature we obtain alumina and calcium oxide the temperature is reduced and the gases condensed and the liquid is electrolyzed to obtain aluminium, calcium and oxygen (all of them pure). This would require temperatures over 2560 ºC and a tremendous input of energy.  The bath would be heated in the center and contained by the cooled crust on the outside. <ref>http://www.moonminer.com/Lunar_Aluminum.html </ref>
  
The second is not going that far with just electrolyzing anorthite at about 1600 ºC. The other byproduct would be calcium oxide.<ref>http://www.moonminer.com/Lunar_Aluminum.html</ref>
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The second just electrolyzing anorthite at about 1600 C. The other byproduct would be calcium oxide. <ref>http://www.moonminer.com/Lunar_Aluminum.html </ref>
  
  

Revision as of 22:36, 14 November 2010

Luna lacks bauxite, therefore, anorthite will be used for Aluminium production instead.[1] Anorthite (CaAl2Si2O8) could be separated from Anorthosite with mechanical and chemical methods to produce Alumina (aluminium oxide, Al2O3). There are several proposed methods to obtain aluminium (even ones that do not require electrolysis). However, almost all require the importation of catalysts and/or reactants. It is true that reactants can be recycled but they limit the total output to the total amount of reactant present and to the speed that the process can recycle them. Another process would be Ion-sputtering to obtain other material and as a residue Aluminium. Aluminium is a strong reducing agent, therefore it requires special conditions to reduce it with carbon.


Proposed Anorthite Production Process

Anorthosite is a mix of Plagioclases, Olivines, and Pyroxenes. To separate the anorthite, anorthosite must be ground. Then, magnetic separation could leave the non-magnetic anorthite. Other means would separate silicon, calcium and magnesium.

The magnetic materials (Ilmenite and iron oxide) could be stored for production of Titanium, iron and oxygen.

Proposed Alumina Production Process

On Earth aluminium is subjected to the Hall-Heroult process where bauxite undergoes the Bayer process to become alumina.

On the Moon Alumina could be produced from Anorthite by boiling out the impurities (between 1500 ºC - 2000 ºC ). The resulting material would be calcium aluminate (CaAlO4). That can be leached in sulfuric acid. The following reaction would be:

CaAl2O4 + 4H2SO4 ==> CaSO4 + Al2(SO4)3 + 4H2O

Aluminium sulfate in hexadecahydrate form (Al2(SO4)3) is then separated from calcium sulphate (CaSO4 + Al2(SO4)3) by filtering and from water by evaporation (and then recovered).

Finally Alumina is obtained by roasting the aluminium sulfate releasing S2.[2]

Future Hall-Heroult Adaptation

Alumina is dissolved in molten cryolite (Sodium hexafluoroaluminate, Na3 AlF6 ) around 1400 ºC. This mix is electrolyzed to separate two byproducts: aluminium and CO2.

Pure alumina can be electrolyzed, but, it melts around the impractical 2000 ºC without the addition of cryolite. It is not known how refractory containers are going to be made on the Moon, nor whether the Hall-Heroult process can be adapted with or without the importation of fluorine for the cryolite.[3]

Subchloride Process

Chlorine and carbon would be imported from Earth. The alumina is then carbochlorinated (carbonated and chlorinated) to yeild AlCl3 which is electrolyzed. Electrolysis of AlCl3 does not consume the precious lunar carbon electrodes as does conventional Hall-Heroult electrolysis of alumina. The carbochlorination byproduct CO2 must be recycled. [4]

Proposed Carbothermal Reduction

Carbon would be imported from Earth. Then the alumina would be mixed with silica and carbon and melted near 2000 C. An aluminium-silicon alloy will form. This could be separated by cooling the Al-Si mixture to 700 -1000 C. and the silicon will solidify and settle out of the melt. CO2 must be recovered and carbon recycled. [5]

Alternate Carbothermal Process

Al203 and carbon can be processed at high temperatures and low pressure into Al4C3.[6] [7] This breaks down into Aluminium and Carbon between 1900 and 2000 centigrade. Carbon monoxide given off in processing[8] can be recycled into carbon.

Other Electrolysis Methods

There are two process that do not require imported chemicals from Earth.

The first one is just boil the anothite and to obtain gases at different temperatures, first silica glass then calcium aluminate. With more temperature we obtain alumina and calcium oxide the temperature is reduced and the gases condensed and the liquid is electrolyzed to obtain aluminium, calcium and oxygen (all of them pure). This would require temperatures over 2560 ºC and a tremendous input of energy. The bath would be heated in the center and contained by the cooled crust on the outside. [9]

The second just electrolyzing anorthite at about 1600 C. The other byproduct would be calcium oxide. [10]


See Also

References