Difference between revisions of "High performance of gem-gum technology"
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m (→Related: added note on chemical energy densities already being near the theoretical ultimate limit) |
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* [[Mechanical energy transmission]] – [[Chemical energy transmission]] – [[Energy transmission]] | * [[Mechanical energy transmission]] – [[Chemical energy transmission]] – [[Energy transmission]] | ||
* [[Thermal energy transmission]] => [[Diamondoid heat pump system]] | * [[Thermal energy transmission]] => [[Diamondoid heat pump system]] | ||
| + | There won't be an orders of magnitude improve on chemical energy densities though. <br> | ||
| + | Today's (2021..) chemical energies are already near the [[ultimate limit]]. | ||
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[[Piezochemical mechanosynthesis#Surprising facts]]: <br> | [[Piezochemical mechanosynthesis#Surprising facts]]: <br> | ||
Revision as of 10:36, 9 July 2021
This page is about collecting and listing various
aspects and performance parameters where future gemstone metamaterial technology
will the potential to vastly outperform anything that we have today.
Related
- Scaling law: Higher throughput of smaller machinery
- Concrete consequence: Hyper high throughput microcomponent recomposition
- Superlubrication and dropping friction even further: stratified shear bearings
- Superelasticity
- Highly temperature resilient base materials: Refractory compounds (where appropriate)
- High strength base materials: Base materials with high potential (where appropriate)
- Highly (bio)degradable base materials (where appropriate). See: Recycling
Ludacrisly high potential power densities
- Electromechanical converter, Chemomechanical converter, ... Energy conversion
- Mechanical energy transmission – Chemical energy transmission – Energy transmission
- Thermal energy transmission => Diamondoid heat pump system
There won't be an orders of magnitude improve on chemical energy densities though.
Today's (2021..) chemical energies are already near the ultimate limit.
Piezochemical mechanosynthesis#Surprising facts:
Reactions do not need to be highly exothermic to have low error rates.
When heavily optimized and slowly operated astoundingly high efficiencies may be reachable.
