Difference between revisions of "Microcomponent"

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[Todo: improve stub; add better definition]
 
[Todo: improve stub; add better definition]
  
Microcomponents form (re)composable functional units. They make up [[diamondoid metamaterials]] and thus provide the basis for [[further improvement at technology level III|advanced AP products]].
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'''Microcomponents''' form '''(re)composable''' functional units. They '''make up [[diamondoid metamaterials]]''' and thus provide the '''basis for [[further improvement at technology level III|advanced AP products]]'''.
Microcomponents are mainly composed / buit out of standard [[diamondoid molecular elements]] and are roughly in the size range from 0.2µm to 2.0µm.  
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Microcomponents are mainly composed / buit out of standard [[diamondoid molecular elements]] and are in the '''size range from roughly 0.1µm to 5.0µm'''.  
Their size constitutes a trade-off between re-usability and space usage efficiency and is (in [[technology level III]]) limited by the [[assembly levels|assembly level II]] building chamber sizes of the generating Nanofactory.
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Their size constitutes a '''trade-off between re-usability and space usage efficiency''' and is (in [[technology level III]]) limited by the [[assembly levels|assembly level II]] building chamber sizes of the generating Nanofactory.
  
 
Since it can be desirable to operate microcomponents in a non vacuum environment (separation of [[assembly levels]]) and one should want to be able to [[recycling|recycle]] them, microcomponents should have no exposed open bonds ( = chemical radicals) on their external surfaces and should preferably use reversible [[locking mechanisms]].
 
Since it can be desirable to operate microcomponents in a non vacuum environment (separation of [[assembly levels]]) and one should want to be able to [[recycling|recycle]] them, microcomponents should have no exposed open bonds ( = chemical radicals) on their external surfaces and should preferably use reversible [[locking mechanisms]].
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To get less anisotropic behavior of [[diamondoid metamaterial|metamaterials]] one can
 
To get less anisotropic behavior of [[diamondoid metamaterial|metamaterials]] one can
 
make them have the shape of either of:
 
make them have the shape of either of:
* [http://en.wikipedia.org/wiki/Truncated_octahedron truncated octahedrons] (the [http://en.wikipedia.org/wiki/Wigner%E2%80%93Seitz_cell Wigner Seitz] cell of the body centered cubic system bcc)
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* [http://en.wikipedia.org/wiki/Truncated_octahedron truncated octahedrons] (the [http://en.wikipedia.org/wiki/Wigner%E2%80%93Seitz_cell Wigner Seitz] cell of the body centered cubic system bcc) preserve parts of the cubes <100> surface planes and expose much of the <111> octahedral planes which are conveniently normal to diamond bonds (when standard orientation is choosen).
 
* [http://en.wikipedia.org/wiki/Rhombic_dodecahedron rhombic dodecaherdons] (the Wigner Seitz cell of the face centered cubic system fcc)
 
* [http://en.wikipedia.org/wiki/Rhombic_dodecahedron rhombic dodecaherdons] (the Wigner Seitz cell of the face centered cubic system fcc)
 
* Base cells of more complicated crystal structures or even quasi-crystals will make geometric reasoning exceedingly hard and will therefore probably only be considered if needed for a good reason.
 
* Base cells of more complicated crystal structures or even quasi-crystals will make geometric reasoning exceedingly hard and will therefore probably only be considered if needed for a good reason.
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* tetrahedrons and octahedrons ("geomag-spacefill")
  
 
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Microcomponents are also mentioned on the "[[assembly levels]]" page and all over the place on this wiki.
Microcomponents are briefly described on the "[[assembly levels]]" page.<br>
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Revision as of 20:03, 21 January 2014

[Todo: improve stub; add better definition]

Microcomponents form (re)composable functional units. They make up diamondoid metamaterials and thus provide the basis for advanced AP products. Microcomponents are mainly composed / buit out of standard diamondoid molecular elements and are in the size range from roughly 0.1µm to 5.0µm. Their size constitutes a trade-off between re-usability and space usage efficiency and is (in technology level III) limited by the assembly level II building chamber sizes of the generating Nanofactory.

Since it can be desirable to operate microcomponents in a non vacuum environment (separation of assembly levels) and one should want to be able to recycle them, microcomponents should have no exposed open bonds ( = chemical radicals) on their external surfaces and should preferably use reversible locking mechanisms.

In the simplest case one could use a simple cube as delimiting base shape. Stacking them then forms a simple cubic microcomponent crystal. To get less anisotropic behavior of metamaterials one can make them have the shape of either of:

  • truncated octahedrons (the Wigner Seitz cell of the body centered cubic system bcc) preserve parts of the cubes <100> surface planes and expose much of the <111> octahedral planes which are conveniently normal to diamond bonds (when standard orientation is choosen).
  • rhombic dodecaherdons (the Wigner Seitz cell of the face centered cubic system fcc)
  • Base cells of more complicated crystal structures or even quasi-crystals will make geometric reasoning exceedingly hard and will therefore probably only be considered if needed for a good reason.
  • tetrahedrons and octahedrons ("geomag-spacefill")

Microcomponents are also mentioned on the "assembly levels" page and all over the place on this wiki.