Difference between revisions of "High performance of gem-gum technology"

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This page is about collecting and listing various  
 
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.
+
aspects and performance parameters where future [[gemstone metamaterial technology]] <br>
 +
will have the potential to vastly outperform anything that we have today <small>(time of writing 2021)</small>.
  
== Related ==
+
== High performance from geometric scaling laws ==
  
 
* Scaling law: [[Higher throughput of smaller machinery]]
 
* Scaling law: [[Higher throughput of smaller machinery]]
 
* Concrete consequence: [[Hyper high throughput microcomponent recomposition]]
 
* Concrete consequence: [[Hyper high throughput microcomponent recomposition]]
-----
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* [[Power density]]
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The scaling law of [[higher throughput of smaller machinery]], combined with other effects listed further below,  <br>
 +
effectively overcompensates the scaling law of [[higher total bearing surface area of smaller machinery]] <br>
 +
that would, on its own, degrade performance by causing huge friction losses. <br>
 +
Related: [[Scaling law]]s
 +
 
 +
== High performance from nanoscale specific properties ==
 +
 
 +
* [[Superlubrication]] and dropping friction even further: [[stratified shear bearings]] <br> Actually superlubrication is only zero for static friction. Dynamic friction is significant for higher speeds. <br>But the in [[Nanosystems]] proposed nanomachinery operation speeds speeds are low (around 5mm/s). <br> Opting for low speeds is possible mainly due to the scaling law of [[higher throughput of smaller machinery]].
 +
* [[Superelasticity]]
 +
 
 +
== High performance of metamaterials ==
 +
 
 +
'''Ludacrisly high potential [[power densities]]:'''
 +
* [[Electromechanical converter]], [[Chemomechanical converter]], ... [[Energy conversion]]  
 
* [[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]]
-----
+
 
* [[Superlubrication]] and dropping friction even further: [[stratified shear bearings]]
+
'''Unfortunately this does not apply to [[energy densities]]:'''<br>
* [[Superelasticity]]
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Unlike with [[power densities]], [[energy densities]] won't see an in improvement of orders of magnitude. <br>
 +
Today's (2021..) chemical energies are already near the [[ultimate limit]].
 +
 
 +
That is unless some very very surprising physics gets to be very unexpectedly discovered. <br>
 +
We absolutely won't make such fantastic assumptions on this wiki. <br>
 +
The baseline for assumptions on this wiki is the complete polar opposite. <br>
 +
The baseline is [[exploratory engineering]].
 +
 
 +
== High performance of base materials ==
 +
 
 +
* Highly temperature resilient base materials: [[Refractory compounds]] (where appropriate)
 +
* High strength base materials: [[Base materials with high potential]] (where appropriate)
 +
* [[High ultimate strength]] – [[Superhard materials]] / [[Refractory materials]] (these two often coincide)
 +
Related: [[The three stabilities]] – chemical, thermal, mechanical
 +
----
 +
* Highly (bio)degradable base materials (where appropriate). '''See: [[Recycling]]'''
 +
 
 +
== Related ==
 +
 
 +
* [[How macroscale style machinery at the nanoscale outperforms its native scale]]
 +
 
 +
=== Performance of piezochemical mechanosynthesis ===
 +
 
 +
[[Piezochemical mechanosynthesis#Surprising facts]]: <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.
  
 
=== Fundamental limits ===
 
=== Fundamental limits ===
  
 
* [[Unsupported rotating ring speed limit]]
 
* [[Unsupported rotating ring speed limit]]
* [[Fractal growth speedup limit]]
+
* [[Fractal growth speedup limit]] and related [[macroscale slowness bottleneck]]
 +
* [[Low speed efficiency limit]]
 +
* [[Ultimate limits]]

Latest revision as of 09:58, 19 September 2023

This article is a stub. It needs to be expanded.

This page is about collecting and listing various aspects and performance parameters where future gemstone metamaterial technology
will have the potential to vastly outperform anything that we have today (time of writing 2021).

High performance from geometric scaling laws

The scaling law of higher throughput of smaller machinery, combined with other effects listed further below,
effectively overcompensates the scaling law of higher total bearing surface area of smaller machinery
that would, on its own, degrade performance by causing huge friction losses.
Related: Scaling laws

High performance from nanoscale specific properties

High performance of metamaterials

Ludacrisly high potential power densities:

Unfortunately this does not apply to energy densities:
Unlike with power densities, energy densities won't see an in improvement of orders of magnitude.
Today's (2021..) chemical energies are already near the ultimate limit.

That is unless some very very surprising physics gets to be very unexpectedly discovered.
We absolutely won't make such fantastic assumptions on this wiki.
The baseline for assumptions on this wiki is the complete polar opposite.
The baseline is exploratory engineering.

High performance of base materials

Related: The three stabilities – chemical, thermal, mechanical


  • Highly (bio)degradable base materials (where appropriate). See: Recycling

Related

Performance of piezochemical mechanosynthesis

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.

Fundamental limits