Bootstrapping methods for productive nanosystems: Difference between revisions
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→Related: added link to yet unwritten page: Expanding the catalytic loop |
added section == Bottom up == |
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* self emerging highly distributed self-replicative capabilities | * self emerging highly distributed self-replicative capabilities | ||
== Bottom up == | |||
There are at least three independent orthogonal axes where technological capability can be judged by and scaled along. These are: | |||
* Convergent selfassembly levels | |||
* Material stiffness (SDN, protein, stiffer stuff) | |||
* Degree of introduction of positional assembly aspects | |||
See: [[Thermally driven assembly]] | |||
== Related == | == Related == | ||
Revision as of 17:59, 26 March 2021
Available methods for getting towards the necessary parallelity to produce macroscopic amounts of products
- bottom up: fully parallel (and hierarchical) self assembly of atomically precise chemically pre-produced building blocks
- top down: conventional photolithographic methods (MEMs)
- exponential assembly (the glue in the middle?)
- compact self replication (outdated)
- self emerging highly distributed self-replicative capabilities
Bottom up
There are at least three independent orthogonal axes where technological capability can be judged by and scaled along. These are:
- Convergent selfassembly levels
- Material stiffness (SDN, protein, stiffer stuff)
- Degree of introduction of positional assembly aspects
See: Thermally driven assembly