Electromechanical converter

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As today (2022) electric motors and generators respectively (electomechanical and vice-versa mechanoelectrical energy conversion respectively) are one of the most important means for energy conversion at the macroscale, so will they be in the future in the nanoscale innards of advanced gem-gum nanosystems.

Unlike macroscale motors & generators which operate quasimagnetostatically scaling laws dictate that
at the naoscale quasielectrostativ motors & generators operate not just equally well but massively better.
With FAPP with certainty predictable lower limits for maximally achievable power densities are 😲🤯🤪🚀 high.

Unlike today at the macroscale with energy conversion based on nanoscale machinery
there will be more alternatives beside electromechanical energy conversion with similarly high efficiency like e.g.
dedicated chemomechanical converters that sidestep the fundamental Carnough efficiency limit by
not taking a detour across thermal energy.

General

Madly high power densities

In Nanosystems the maximal 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 that are predicted to be at least possible already are extremely high.
Exceeding no less than 1MW/mm³!! See quantitative section below for the math.

This should not come as a surprise since electrostatic machines scale favorably for the small scales.

The relevant scaling law to "blame" for these power densities

In Nanosystems Chapter 2.4. Scaling of classical elecrtomagnetic systems
in Sub-chapter 2.4.3. Magnitudes and scaling: steady-state system
the Formula (2.27) states:
[math] electrostatic–power–density \propto \frac{electrostatic–power}{volume} \propto L^{-1} [/math]
See the page about scaling laws for a derivation.

What does this mean? This means:
When scaling an electrostatic motor/generator

  • from say 100mm (10cm about 4inch) macroscale size down
  • to say 100nm nanoscale size (~500carbon atom diameters)

(which is a factor of a million) then the volumetric power density of this motor/generator
will also goes up from

  • one (unit of power density) to
  • a million of these units.

(also a factor of a million)

In fact even more so since at the macroscale imperfections lower dielectric strength and breakdown voltage
is limiting achievable electrical field strengths to much lower levels than what is possible at the nanoscale.

Why electrostatic? Because magnetostatic is weak at the nanoscale.

Note that in contrast to
power-densities of quasielectrostatic machines (i.e. motors based on electrostatic attraction),
power-densities of quasimagnetostatic machines (i.e. motors with coils making magnetic fields)
scale very poorly down to the nanoscale.
For details see page: Scaling laws

Practical everyday consequences of high power densities

In everyday practice that won't mean we'll have motorcycles more powerful than Saturn Five space rockets.

  • Mainly because that just won't be needed.
  • Secondarily because energy density does not scale that well.
    A carried along energy storage would be used up in no time.
  • Thirdly because even with very high efficiencies power losses will be very high in absolute terms and
    need extreme means of cooling if even possible steady state.

In everyday practice what rather will be the case is that motor metamaterial (say in motorcycles) will be:
very small in volume and thus likely directly integrated into the bearing metamaterial.
A small volume of muscle motors integrated in infinitesimal bearings make shearing drives.
All in terms of this wikis ad-hoc invented terminology.

There won't be a motor in the engine room of vehicles.
Instead the most voluminous things remaining are:

  • energy storage
  • structures for thermal waste heat cooling (bigger means the flow in convection cooling can be laminar and silent)
  • the structural frame

Quantitatively – Running some numbers

From Nanosystems 11.1.7 Charge carriers and charge density

  • Electrode length: l_electrode = 20nm
  • Electrode diameter: w_electrode = 3nm (electrode width)
  • Rim electrode separation: s_electrodegap = 3nm (inter electrode distance)
  • => Electrode area: A_electrode = l_electrode * w_electrode = 60nm²

  • Field strength: E_electrode = 0.2V/nm
    (wiki-TODO: Find origin of field strength assumption. Is it 10V and 50nm min motor radius mentioned in next section?)
    This is ~10% of the ultimate dielectric strength of diamond which is ~2V/nm.
  • Charge per area: Q_electrode/A_electrode = ε_0 * ε_r * E_electrode = ~0.0018C/m²
    (neglecting beneficial insulator polarization i.e. ε_r=1) (neglecting stray fields ∫ E·dA = Q/ε)
  • Charge per electrode Q_electrode = ~3.3*10-19C (about two electrons worth of charge)
  • Charge per rim-arclength: (Q/l) = Q_electrode/(s_electrode+s_electrodegap) = 5.5*10-11C/m

Note: The dielectric constant of diamond (ε_r) is ~5.5
This potential performance boosting factor (beneficial insulator polarization) is ignored (assumed =1).

From Nanosystems 11.7.3. Motor power and power density

  • Motor rim speed: v = 1000m/s
  • Current: I = 2*v*(Q/l) = 110nA (factor 2 for "including contributions from both sides of the rotor")
  • Voltage: U = 10V
  • Absolute power: P = U*I = ~1.1µW

  • Motor radius: r = 195nm
  • Motor thickness: t = 25nm
  • Motor volume: V = pi*r²*h = ~2*10^-22

  • Motor volumetric power density: epsilon = P/V > 1015W/m³
    This is means >1MW/mm³!!

Citations:

  • "The power density is large compared to that of macroscale motors: >1015W/m³." ...
  • "(Cooling constraints presumably preclude the steady-state operation of a cubic meter of these devices at this power density.)"

Following is Nanosystems 11.7.4 Energy dissipation an efficiency

All numbers or chosen model design

  • e. Summary: It seems possible to make bearing losses dominant (a few nW)
    and with that get efficiencies >99% at these extreme power densities. Even more efficient at lower power densities.
    Especially with roller contacts instead of sliding tunneling contacts.

  • a. Ohmic: Losses under conservative assumption of the conductivity of bulk macroscale aluminum: ~0.1pW
  • b. Tunnelwiderstand: Losses <3pW
  • c. Bearing losses: From ~1.3pW up to a few nW
  • d. Contact drag:
    — jumping leakage electrons: minimizable by (details ...)
    — thermoelastic damping & phonon drag: still to evaluate potentially dominant! But massively reducible roller contacts rather than tunneling contacts.

(wiki-TODO: Add retracing of math here)

Motor startup

(wiki-TODO: Present in more detail suggestions from Nanosystems for motor startup here)

Basically the issue is that one wants to give motors a clearly defined startup direction.
One proposal is to use electrodes with differing work functions to create a charge asymmetry.

Contacting options

Geometry options:

  • tunneling contacts
  • roller contacts
  • flexing connections for reciprocating drives
    flex must be low enough to not disturb the electric properties (conductivity) of conducting material too much.

Material options:

  • graphite ribbons
  • conductive nanotubes
  • conventional metals like aluminum
  • ...

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

Designs that might need not much changes:

  • pelletron
  • Wimshurst machine
  • The Gläser machine (or Lewandowski machine) [1] – cylindric Wimshurst machine
  • A small cylindric simplified Voss machine [2]
  • Lord Kelvin Replenisher [3]
  • Bennet's doubler

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)

What when really pushing the limits hard?

When for whatever reasons really pushing for the limits of possible, that is going simultaneously for:

  • steady state operation
  • high power density
  • high densely filled volume

then one needs to go absolutely BEEP crazy with active cooling. The volume of the cooling system may need to become orders of magnitude more voluminous than the actual electromechanical energy conversion system. Important to note here: We are not counting the volume of the cooling system to the volume of the energy conversion system for the calculation of the power density.

Potential bottlenecks

One potential bottleneck is the maximal power density that a cooling systems can handle. Super high power cooling systems may cause additional heat too. Given the high performance of diamondoid heat pipe systems and diamondoid heat pump systems combined with the waste heat being only a tiny fraction of the total power due to high efficiency of the electromechanical conversion, this looks good though.

One potential bottleneck are the radiators to natural the pre-given environment. Especially in outer space with no convective cooling as an option. When the waste heat needs to be pushed out of the machine phase. They'd need to be build big and out of refractory gemstone-like compounds since they might get white hot. In Earths atmosphere one would want to add an impressively strong air stream by blowing in cold air with medium movers. That would look quite impressive actually. In vacuum the radiated waste hear power scales with the fourth power of temperature (Stefan–Boltzmann law) . That's quite good but physical materials have an ultimate limit in temperature. That is there is a temperature above which no material can exist in the solid state (without pressurization to technologically impossible levels).

References

In the book "Nanosystems"

Treatment of electromechanical energy conversion
and electrostatics in general in Nanosystems (taken from it's glossary):


  • Electrostatic actuators, 335, 336
  • Electrostatic motors, 336-341, 370
  • Electrostatic generators (DC), 336-341

  • Electrostatic energy, scaling of, 30
  • Electrostatic force, scaling of, 29

  • Elecrostatic fields, 29, 200
  • Elecrostatic interactions in MM2, 48, 200

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: