Difference between revisions of "Electromechanical converter"

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(Porting macroscale electrostatic machines to the nanoscale: note on voltages and currents)
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== Porting macroscale electrostatic machines to the nanoscale ==
 
== Porting macroscale electrostatic machines to the nanoscale ==
  
The [[scaling law]] for electrostatic performance is very favorable for such niniaturization.
+
The [[scaling law]] for electrostatic performance is very favorable for such miniaturization.
 +
* Voltages become much lower (down to ~1V like in computer chips) – this still gives massive electric fields over nanoscale distances.
 +
* Currents become much higher due to massive device parallelity
  
 
* [https://en.wikipedia.org/wiki/Pelletron pelletron]  
 
* [https://en.wikipedia.org/wiki/Pelletron pelletron]  

Revision as of 22:22, 14 June 2021

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

General

In Nanosystems the power densities that are to expect to be (at least) possible with
electrostatics based electromechanical conversion at the nanoscale are conservatively estimated.
The power densities predicted to be at least possible already are unbelievably high.

Porting macroscale electrostatic machines to the nanoscale

The scaling law for electrostatic performance is very favorable for such miniaturization.

  • Voltages become much lower (down to ~1V like in computer chips) – this still gives massive electric fields over nanoscale distances.
  • Currents become much higher due to massive device parallelity

Machines needing obvious modifications for the nanoscale:

  • Kelvin water dropper
    Could that be done in a nanoscale version with shooting solid-state charged pellets?
  • Van de Graaff generator:
    Charge seperation would be done in rather different way.
    Well, avoiding rubber (since not a gemstone-like compound), it would essentially become a similar to a pelletron. (replicate nanoscale charge separation mechanism)

Alternative contacting

To avoid the need for graphite tunneling contacts which need quite some surface and dissipate some power a reziprocating drive could be electrically connected with flexing nanotube connections. The flex must be low enough to not disturb the electric properties (conductivity) of the nabotube too much.

References

Related

External links

Here is a website with an extreme detailed collection of information regarding the history of electrostatic machines:
Electrostatic Machines written by by Antonio Carlos M. de Queiroz.
Especially interresting seem

On wikipedia:

Videos: