Difference between revisions of "Topological atomic precision"
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| + | Up: [[Precision]] | ||
| + | Up: [[Atomic precision]] | ||
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With '''atomic precision''' one refers to structures where the '''positions of all the included atoms are known in a topological sense''' meaning one knows which atom connects with which. | With '''atomic precision''' one refers to structures where the '''positions of all the included atoms are known in a topological sense''' meaning one knows which atom connects with which. | ||
| − | An atomically precise structure may well be floppy such that thermal movement makes the actual positions of the atoms completely unknown. | + | An [[atomically precise structure]] may well be floppy such that thermal movement makes the actual positions of the atoms completely unknown. |
Many base structures for self assembly (in [[technology level 0]] and [[technology level I]]) are examples for floppy AP structures e.g. short DNA half strands (oglionucleotides). | Many base structures for self assembly (in [[technology level 0]] and [[technology level I]]) are examples for floppy AP structures e.g. short DNA half strands (oglionucleotides). | ||
| − | + | * In [[technology level I]] whole sturdy structures out of sturdy '''AP-building blocks''' are assembled in a digital fashion. One is dealing with atomically precise structures but one only needs sub block size positioning precision for [[positional assembly]]. | |
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| − | In [[technology level II]] and [[technology level III]] [[diamondoid]] materials are the main building material. | + | * In [[technology level II]] and [[technology level III]] [[diamondoid]] materials are the main building material. They allow not only the topological position but also the position in three dimensional space to be known ([[positional atomic precision]]). |
| − | They allow not only the topological position but also the position in three dimensional space to be known | + | |
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Atoms do roughly behave like a construction set with elastic linkages only if the right set of atoms is chosen. | Atoms do roughly behave like a construction set with elastic linkages only if the right set of atoms is chosen. | ||
| − | Metals with their undirected bonding tend to diffuse at room temperature destroying topological order and thus often do not preserve AP making them unsuitable for nanomachinery. | + | Metals with their undirected bonding tend to diffuse at room temperature destroying topological order and thus often do not preserve Atomic precision (AP) making them unsuitable for nanomachinery. |
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| + | == Related == | ||
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| + | * [[Atomically precise manufacturing]] | ||
| + | * [[Atomic precision]] | ||
| + | * [[Positional atomic precision]] | ||
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| + | [[Category:General]] | ||
Latest revision as of 13:27, 15 July 2021
Up: Precision Up: Atomic precision
With atomic precision one refers to structures where the positions of all the included atoms are known in a topological sense meaning one knows which atom connects with which.
An atomically precise structure may well be floppy such that thermal movement makes the actual positions of the atoms completely unknown. Many base structures for self assembly (in technology level 0 and technology level I) are examples for floppy AP structures e.g. short DNA half strands (oglionucleotides).
- In technology level I whole sturdy structures out of sturdy AP-building blocks are assembled in a digital fashion. One is dealing with atomically precise structures but one only needs sub block size positioning precision for positional assembly.
- In technology level II and technology level III diamondoid materials are the main building material. They allow not only the topological position but also the position in three dimensional space to be known (positional atomic precision).
Atoms do roughly behave like a construction set with elastic linkages only if the right set of atoms is chosen. Metals with their undirected bonding tend to diffuse at room temperature destroying topological order and thus often do not preserve Atomic precision (AP) making them unsuitable for nanomachinery.
