Difference between revisions of "On chip microcomponent recomposer"
(→Related: added link to microcomponent maintenance unit and brief explanation of relation) |
(→Thermal bunching: added link to yet unwritten page: Thermal bunching) |
||
| (13 intermediate revisions by the same user not shown) | |||
| Line 1: | Line 1: | ||
{{site specific term}} | {{site specific term}} | ||
| − | + | An on-chip microcomponent recomposer is a production device that constitutes a standalone sub part of a [[nanofactory]]. <br> | |
| − | It is something like an incomplete [[nanofactory]]. | + | It is something like an incomplete [[nanofactory]]. <br> |
| + | An on-chip microcomponent recomposer only contains the upper [[assembly levels]] beginning with microcomponent assembly (level III or IIb). | ||
| − | + | An on-chip microcomponent recomposer can handle bigger parts that can be taken apart again - that is: | |
* [[Product fragment]]s out of many [[microcomponent]]s | * [[Product fragment]]s out of many [[microcomponent]]s | ||
| − | And in contrast to a full nanofactory | + | And in contrast to a full nanofactory an on-chip microcomponent recomposer can't handle smaller parts that often can't be taken apart again - these are: |
* The many [[crystolecule]]s in microcomponents <br> (Note: After assembly microcomponents often can't be disassembled to their constituting crystolecules because of irreversible fusion of dense [[surface interface]]s. Also the possibly necessary vacuum lock in is much more difficult than vacuum lockout.) | * The many [[crystolecule]]s in microcomponents <br> (Note: After assembly microcomponents often can't be disassembled to their constituting crystolecules because of irreversible fusion of dense [[surface interface]]s. Also the possibly necessary vacuum lock in is much more difficult than vacuum lockout.) | ||
* The many atoms / [[molecule fragment]]s in crystolecules <br> (Note: [[atomically precise disassembly|mechanosynthetic disassembly]] is more difficult than mere normal forward [[mechanosynthesis]]) | * The many atoms / [[molecule fragment]]s in crystolecules <br> (Note: [[atomically precise disassembly|mechanosynthetic disassembly]] is more difficult than mere normal forward [[mechanosynthesis]]) | ||
| − | As a consequence (unlike full nanofactories) everything that microcomponent recomposers can build they can take apart to the building | + | As a consequence (unlike full nanofactories) everything that on-chip microcomponent recomposers can build they can take apart to the building blocks they made them out. Thus '''on-chip microcomponent recomposers are excellent recycling machines'''. |
They shuffle existing that is prefabricated [[microcomponents]] into new configurations to create new different products from old ones (or from virgin microcomponents of an macroscopically ''external'' nanofactory). | They shuffle existing that is prefabricated [[microcomponents]] into new configurations to create new different products from old ones (or from virgin microcomponents of an macroscopically ''external'' nanofactory). | ||
== Misc == | == Misc == | ||
| − | More general purpouse [[ | + | More general purpouse [[microcomponent maintenance microbot]]s may do the same job as an on-chip microcomponent recomposer but less efficient. |
= Global microcomponent redistribiution network = | = Global microcomponent redistribiution network = | ||
| − | + | Ob-chip microcomponent recomposers become especially effective when connected to a ''global microcomponent redistribution system''. <br> | |
| − | Main article: [[Global microcomponent | + | Main article: [[Global microcomponent redistribution system]] |
== Mobile == | == Mobile == | ||
| − | + | When in locations without access to a [[global microcomponent redistribution system]] then <br> | |
| + | one could lug around around a cartridge of the most often used [[microcomponent]]s. <br> | ||
| + | This is somehow comparable to a computer cache with the most often used dater nearest to the ALU. | ||
= Integration into normal everyday experience = | = Integration into normal everyday experience = | ||
| Line 29: | Line 32: | ||
== Thing source and thing drain == | == Thing source and thing drain == | ||
| − | Instead of packing microcomponent recomposer functionality into each and every surface of our environment it is probably more sensible to put them where we expect them. Physical locations are usually associated with functions. | + | Instead of packing on-chip microcomponent recomposer functionality into each and every surface of our environment it is probably more sensible to put them where we expect them. Physical locations are usually associated with functions. |
No one wants the ''immediate delete'' button right next to the ''save'' button. | No one wants the ''immediate delete'' button right next to the ''save'' button. | ||
| Line 39: | Line 42: | ||
== The fridge and the freezer == | == The fridge and the freezer == | ||
| − | The fridge and the freezer are further physical locations associated with a special use. | + | The fridge and the freezer are further physical locations associated with a special use. <br> |
| − | Especially at those locations full nanofactories are needed instead of just microcomponent recomposers. | + | Especially at those locations full on-chip nanofactories are needed instead of just on-chip microcomponent recomposers. |
What one usually expects to be in a freezer is food and medicine. | What one usually expects to be in a freezer is food and medicine. | ||
| Line 56: | Line 59: | ||
The point of paying the cost of transport for microcomponents is: not to create even more non degrading waste which is more costly to get rid of. | The point of paying the cost of transport for microcomponents is: not to create even more non degrading waste which is more costly to get rid of. | ||
Critical drugs will very probably be subject to intense regulations - thus no local synthesis. | Critical drugs will very probably be subject to intense regulations - thus no local synthesis. | ||
| + | |||
| + | Related: [[Synthesis of food]] | ||
= Thermal bunching = | = Thermal bunching = | ||
| − | {{ | + | {{wikitodo|Write about this very important aspect}} <br> |
| + | See page: [[Thermal bunching]] | ||
= Related = | = Related = | ||
| − | A compact microscopic version of | + | * '''[[Global microcomponent redistribution system]]''' |
| + | ---- | ||
| + | * Disambiguation page: [[Microcomponent recomposer]] | ||
| + | |||
| + | A compact microscopic version of an on-chip microcomponent recomposer is a [[microcomponent maintenance microbot]]. <br> | ||
It would have some similarities with a [[molecular assembler]]. Main difference being the lack of [[mechanosynthesis|mechanosynthetic capabilities]] | It would have some similarities with a [[molecular assembler]]. Main difference being the lack of [[mechanosynthesis|mechanosynthetic capabilities]] | ||
| Line 69: | Line 79: | ||
* [[Recycling]] | * [[Recycling]] | ||
* [[Thermal bunching]] | * [[Thermal bunching]] | ||
| + | * [[Second assembly level self replication]] | ||
| + | * [[RepRec pick and place robots]] | ||
| + | * [[Reasons for APM]] – There's a section about "Fast recycling" and how it leads to problem solving opportunities. | ||
= External links = | = External links = | ||
Latest revision as of 09:23, 19 March 2024
An on-chip microcomponent recomposer is a production device that constitutes a standalone sub part of a nanofactory.
It is something like an incomplete nanofactory.
An on-chip microcomponent recomposer only contains the upper assembly levels beginning with microcomponent assembly (level III or IIb).
An on-chip microcomponent recomposer can handle bigger parts that can be taken apart again - that is:
- Product fragments out of many microcomponents
And in contrast to a full nanofactory an on-chip microcomponent recomposer can't handle smaller parts that often can't be taken apart again - these are:
- The many crystolecules in microcomponents
(Note: After assembly microcomponents often can't be disassembled to their constituting crystolecules because of irreversible fusion of dense surface interfaces. Also the possibly necessary vacuum lock in is much more difficult than vacuum lockout.) - The many atoms / molecule fragments in crystolecules
(Note: mechanosynthetic disassembly is more difficult than mere normal forward mechanosynthesis)
As a consequence (unlike full nanofactories) everything that on-chip microcomponent recomposers can build they can take apart to the building blocks they made them out. Thus on-chip microcomponent recomposers are excellent recycling machines. They shuffle existing that is prefabricated microcomponents into new configurations to create new different products from old ones (or from virgin microcomponents of an macroscopically external nanofactory).
Contents
Misc
More general purpouse microcomponent maintenance microbots may do the same job as an on-chip microcomponent recomposer but less efficient.
Global microcomponent redistribiution network
Ob-chip microcomponent recomposers become especially effective when connected to a global microcomponent redistribution system.
Main article: Global microcomponent redistribution system
Mobile
When in locations without access to a global microcomponent redistribution system then
one could lug around around a cartridge of the most often used microcomponents.
This is somehow comparable to a computer cache with the most often used dater nearest to the ALU.
Integration into normal everyday experience
Thing source and thing drain
Instead of packing on-chip microcomponent recomposer functionality into each and every surface of our environment it is probably more sensible to put them where we expect them. Physical locations are usually associated with functions.
No one wants the immediate delete button right next to the save button.
E.g. The good old dustbin. It may be replaced with a microcomponent recomposer that is set to disassemble its contents when "a button is pushed".
Note: The other direction - general purpose production devices (e.g. the size of a laserprinter are probably more likely to integrate the full nanofactory functionality. (Regulations?...)
The fridge and the freezer
The fridge and the freezer are further physical locations associated with a special use.
Especially at those locations full on-chip nanofactories are needed instead of just on-chip microcomponent recomposers.
What one usually expects to be in a freezer is food and medicine. Since they Food and medical drugs (at least the non serious ones) absolutely need to be synthesizable locally. Otherwise they need to be be carried in from afar which makes little sense - see below.
Food (made directly in the fridge) may contain nonpoisonous digestible microcomponents (made exclusively from e.g. periclase, calicte, appatite, DNA-meshworks, de novo proteins ...) but certainly not as a main component. Food is not made to be disassembled - its made to be eaten by humans or other forms of life.
The same holds for medical drugs (that may be temperature sensitive)
Medicine will often come in the form of advanced medical nanodevices. those nanodevices may be standalone microcomponents (slowly degrading or nonderading but well egestable) - there's no need for a recomposer.
Why microcomponent recycling involving transport: (Main article: Recycling)
It boils down to that everything that biodegradates quickly is not worth the effort of transporting in from afar.
The point of paying the cost of transport for microcomponents is: not to create even more non degrading waste which is more costly to get rid of.
Critical drugs will very probably be subject to intense regulations - thus no local synthesis.
Related: Synthesis of food
Thermal bunching
(wiki-TODO: Write about this very important aspect)
See page: Thermal bunching
Related
- Disambiguation page: Microcomponent recomposer
A compact microscopic version of an on-chip microcomponent recomposer is a microcomponent maintenance microbot.
It would have some similarities with a molecular assembler. Main difference being the lack of mechanosynthetic capabilities
- Technology level III
- Recycling
- Thermal bunching
- Second assembly level self replication
- RepRec pick and place robots
- Reasons for APM – There's a section about "Fast recycling" and how it leads to problem solving opportunities.
