Difference between revisions of "High performance of gem-gum technology"
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Reactions do not need to be highly exothermic to have low error rates. <br> | Reactions do not need to be highly exothermic to have low error rates. <br> | ||
When heavily optimized and slowly operated astoundingly high efficiencies may be reachable. | When heavily optimized and slowly operated astoundingly high efficiencies may be reachable. | ||
| + | ----- | ||
| + | * Highly temperature resilient base materials: [[Refractory compounds]] | ||
| + | * High strength base materials: [[Base materials with high potential]] | ||
| + | * Highly (bio)degradable base materials (where appropriate). See: [[Recycling]] | ||
=== Fundamental limits === | === Fundamental limits === | ||
Revision as of 13:41, 21 June 2021
This page is about collecting and listing various aspects and performance parameters where gem-gum technology has 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
- Power density
- Mechanical energy transmission – Chemical energy transmission – Energy transmission
- Thermal energy transmission => Diamondoid heat pump system
- Superlubrication and dropping friction even further: stratified shear bearings
- Superelasticity
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.
- Highly temperature resilient base materials: Refractory compounds
- High strength base materials: Base materials with high potential
- Highly (bio)degradable base materials (where appropriate). See: Recycling
