Difference between revisions of "Mechanosynthetic water splitting"

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* gaining oxygen when the hydrogen is needed too (seldom case) otherwise [[mechanosynthetic splitting of dioxygen|mechanosynthetic splitting of atmospheric dioxigen]] is a better choice
 
* gaining oxygen when the hydrogen is needed too (seldom case) otherwise [[mechanosynthetic splitting of dioxygen|mechanosynthetic splitting of atmospheric dioxigen]] is a better choice
  
'''Todo:''' How does the basic diamondoid [[mechanosynthesis]] toolset (consisting of nine tools) need to be extended to be able to reversibly rip H<sub>2</sub>O apart?
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{{todo|How does the basic diamondoid [[mechanosynthesis]] toolset (consisting of nine tools) need to be extended to be able to reversibly rip H<sub>2</sub>O apart?}}
  
= Notes =
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= Diffeculties (error rate) =
  
According to the book [[Nanosystems]] oxygen is one of the more difficult elements to handle at room temperature ['''todo:''' check for correctness and add chapter] due to its weaker bond strengths. Also oxygen (like its group companion sulfur) normally forms only two bonds under average conditions. Electron deficiency bonds (e.g. with boron) that grab the lone pair of oxygen may be usable but this has not yet been analyzed. But ''it has been proven'' that even hydrogen which normally forms only one bond can be mechanosynthetically transferred, so there should be no fundamental problems.
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According to the book [[Nanosystems]] oxygen is one of the more difficult elements to handle at room temperature due to its weaker bond strengths. {{todo| check for correctness and add chapter|Nanosystem says oxygen splitting is hard at room temperature}}
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= How can something be placed that has only two bonds to "hold" it =
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Also oxygen (like its group companion sulfur) normally forms only two bonds under average conditions. Electron deficiency bonds (e.g. with boron) that grab the lone pair of oxygen (effectively as a third bond) may be usable but this has not yet been analyzed (2016).
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Either way ''it has been proven'' that even hydrogen which normally forms only one bond can reliably be mechanosynthetically transferred, so there should be no fundamental problems.
  
 
[[Category:Technology level III]]
 
[[Category:Technology level III]]
 
[[Category:Mechanosynthesis]]
 
[[Category:Mechanosynthesis]]

Revision as of 07:57, 13 February 2016

This article is a stub. It needs to be expanded.
CPK model of a water molecule

Use cases

(TODO: How does the basic diamondoid mechanosynthesis toolset (consisting of nine tools) need to be extended to be able to reversibly rip H2O apart?)

Diffeculties (error rate)

According to the book Nanosystems oxygen is one of the more difficult elements to handle at room temperature due to its weaker bond strengths. (TODO: check for correctness and add chapter)

How can something be placed that has only two bonds to "hold" it

Also oxygen (like its group companion sulfur) normally forms only two bonds under average conditions. Electron deficiency bonds (e.g. with boron) that grab the lone pair of oxygen (effectively as a third bond) may be usable but this has not yet been analyzed (2016). Either way it has been proven that even hydrogen which normally forms only one bond can reliably be mechanosynthetically transferred, so there should be no fundamental problems.