Friction
Nanoscale friction
In gemstone metamaterial technology
Despite higher bearing surface area of smaller machinery
the friction in gem-gum technology stays manageable.
Friction not being a show-stopper is due to:
- (1) The extreme throughput density of nanomachinery. – See: Higher throughput of smaller machinery
- (2) The fact that friction of nanoscale bearing drops quadratically with slowdown. – See: Superlubricity
(1) How nanomachineries innate high throughput density reduces friction
Higher throughput of smaller machinery leads to very little amount of nanomachinery needed
and thus to reasonably low bearing surface area within that.
(2) How the dynamic character of nanobearing friction can be exploited to reduce friction
Given quadratic gains in efficiency one wants to do a deliberate slowdown at the lower assembly levels
where this type of friction is present.
Keeping throughput constant this means one needs to compensate for the loss of throughput with more nanomachinery.
More nanomachinery means a linear increase in losses. Quadratic gains times linear losses equals linear gains. Still good.
See: Increasing bearing area to decrease friction
- Q: But is there enough space for accomodating more nanomachinery?
- A: Yes, very much so. It's "Higher throughput of smaller machinery" again.
Recycle to reduce friction (not applicable to first time production)
Also a good design averts the need to disassemble things down to nanoscopic parts if
only larger scale reconfigurations are needed. – See: Convergent assembly
This kind of aversion of frictive losses only applies to recycling though.
Making recycling all the more desirable end economically viable. Nice!
Further reading
See main page: Friction in gem-gum technology This contains quantitaive estimations.
A bit more detailed but still brief exlanations to these effects/factors
can be found on the page How friction diminishes at the nanoscale.
In existing nanotechnologies
Stiff
- Pretty much the only case where the above can already be experimentally tested (as of 2021) is in nested nanotubes and sliding graphene sheets.
- At the microscale with MEMS there is the issue with stiction. Which may paint a misleading picture of how friction and wear scales when going down even further the sizescales.
Soft
It's hard to talk about friction is systems that are akin to biological cells.
It's obviously not that there are no energy dissipation losses.
There necessarily are other energy devaluating mechanisms that are not "friction".
While in thermally driven diffusion transport there is no "friction" the energy needs to be "expended" at the "pitstops" instead.
This is necessary in order to prevent reactions and diffusion transports to run backwards.
Stiff artificial nanosystems could be superior to nanosoft (natural and artificial)
because they may allow for more complete energy recuperation
using dissipation sharing. That is the "energetic change money" is not lost.
Macroscale friction
Classical friction
There is classical friction with the friction coefficient µ.
Present e.g. in dry sliding sleeve bearings.
- This type of friction is in first approximation independent of sliding (or rolling) speed
- This type of friction is in first approximation independent of contact area
- This type of friction is in dependent on normal force (load)
Dynamic drag
There is dynamic drag in liquids and gasses.
Present e.g. in hydrostatic and hydrodynamic bearings.
- This type of friction is dependent on speed
- This type of friction is dependent on contact area
- there is dependence on normal force (load) but it requires an extended model.
Macroscale bearings made form gemstone based nanomachinery
This is about the gemstone based metamaterial that is infinitesimal bearings.
Distributing the speed difference over many layers can give low friction per bearing area even for higher speeds.
The rising total bearing interface are is overcompensated by the drop in friction from dropping speed.
Overall doubling the thickness of the stack of bearing layers halves the friction.
A inverse proportional linear relationship.
Practical bearings can have quite thin stacks of bearing layers.
Thin from the human scale perspective.
Related
- Friction in gem-gum technology
- Superlubricity reducing friction
- How friction diminishes at the nanoscale
- Friction mechanisms
- Rising surface area causing more friction
- Macroscale style machinery at the nanoscale – Common misconceptions about atomically precise manufacturing
- Feynman path – A naive form of scaling down saw blades and drills to the nanoscale (infeasible)
- Pages with math
- Evaluating the Friction of Rotary Joints in Molecular Machines (paper)
External links
- Evidence of misconception: See section: "Fundamental Concepts" Wikipedia: Nanoelectronics (2017-04-12) (common false negatives).
- Nanomachines: How the Videos Lie to Scientists (Eric Drexlers metamodern blog (archive) 2009-02-10)