NOR computer logic form

Sensors

Transport mechanisms

Hamster balls ac like electret pulsing polarization, wind up clock with piezo hands strobes outer surface to repel and attract on U (actually O) segments, hamster ball can carry cargo

Bootstrap nanoassembler

SiO2 ic chip lithography isotopic electret paths, molecule sorting dot twister mats, mems or 3 nm vacuum huts, hamster ball transporters made with material that sublimes to leave an empty compartment, a Tetris piece maker, an annular vibrating circle
that vibra-plate and/or radial isotopic electret sorts Tetris pieces into separate piles, then

Audi/olympic circles with an inactive one (or several) that turns on after the Tetris piece sorter has grouped the Tetris pieces, at the overlapped part of the next Olympic circle a blend of two Tetris pieces occurs, and their compatible electretness or
mechanics sticks them together, piezoelectric or other motion jiggles them outward to another annulus, that annulus has electret surface patterns that favor a particular configuration and form to probabilistically attach and stay around even with
jiggling, the overlap with the next Olympic circle can have electret patterns on it that favor uniting two groups of two Tetris pieces, there is also a piezo pattern that vibrates things on the previous annuluses back to a stochastic distribution so the
Tetris pieces that have not successfully matched and travelled out of stochastic I at I on range have another go at combining

Another ic 3nm technology is to make a coil spring @, toss it on an electret alignment maker and cause it to change shape with piezo electricity, storing tension and mechanical energy (it is encircled or point-kept from expanding, then when the
piezoelectric energy is no longer supplied or the coil @ is moved it can supply continuous mechanical power

Quantum linked photon communication UV sticky tape/peel, parabolic dish 3nm ic size

Pinball bumpers that sort and decrease stochasticism imparting energy to things that bounce into them with vase/face contours, high up get energized, vase/face could be improved with flexi-shingles that dampen velocity rather than impart velocity and
reflect to be nearer the base electret surface, vase/face with shingles could be made with 3-7nm IC technology, a nanoassembler making nanoassemblers component could be making vase/face with shingles from Tetris pieces sorted with annuli

with piezo electricity makeable from storing tension and mechanical energy at the wound @, then when the piezoelectric energy is no longer supplied or the coil @ is moved it can supply continuous mechanical power

I think non-drexlarian nanoassembler are possible (notes), some drexlerian nanotechnology has possible new technologies and improvement

I saw a Drexlarian nanotechnology video and at it they had a bunch of what looked like AFM tips on the perimeter of a wheel, to have them do pick and place of single atoms or entire Tetris pieces actual AFMs modulate charge, that would at first seem to
go with e- conduction pathways to every AFM tipped wheel but another way to do it is to have a tall chunk of piezoelectric material, taller than the AFM tip that contacts a strike plate nest to the thing being built, that pulse of e- provides the energy
to glom or unglom the atom or Tetris piece at the tip, another possibility is to have the flat sides of the afm-tread wheel have a (circle of) little raised columns that are struck periodically (or programmatically) and then conductive pathways (or
possibly just electrostatic charge distributing ridges) cause e-changes at the AFM tips to vary their glommingness, this is kind of like a disk (rather than cylinder) music box

One Drexlerian nanotechnology uses C2H2 to make diamond, isotope and spin effects of deuterium could cause more maneuverability and responsiveness to varied kinds of electricity like exposure to spin polarized electrons, published material says that
oxidizing No with spin polarized O2 is 40% different

Doped diamond can be a p or n semiconductor, it is possible that diamond sponge could be nano manufactured, with the possible advantage that the edge of each hollow would have surface-like charge anisotropy, the surface charge anisotropy would make the
diamond more reactive, causing the 0°C or STP growth of diamond at the surface to be more chemical physics favored, perhaps even with Drexler's C2H2 acetylene feedstock, spintronics does varied things with crystal lattice anomalies (hollows, edges), and
different versions of acetylene (C2D2, or even C2DH) are likely to grow, or AFM tip place differently and with a wider latitude of engineering material characteristics

Sticky tape x ray diamond dust maker, the cover of Science had a light and X-ray emitting roll of unpeeling sticky tape, it is possible that the light came from a line of plasma produced from the minute area of "nothing there" (vacuum) making plasma,
there are are 273 kelvin plasma diamond CVD machines, so perhaps a sticky tape plasma nanotechnology could make diamond chunks at varied sizes

Are there "endothermic" (cooling) physics "reactions", like throwing a tarp on a pile of dust, a dendritic tree with electret branches, inserting rebar into premade holes at a column that is swaying, these could contact another system to make it jiggle
less (cool it) that could benefit nanotechnology, an AFM tip with an annulus of dendritic tree electret material like an anti-wriggle wreath at the base of a AFM tip cone could wiggle less

There is a little more to this endothermic like physics, rather than just damping vib there is the p

Grapheme net with hexanes between cycles could be a cling to fit tarp over a pile of diamond nanodust or Tetris pieces

Little edge and chunk disturbances in electrets make them last longer, and putting 500 nm chunks has been published as doing this, so making Gaussian or other patterns of nanothings could benefit electret applications, electret sides at Tetris pieces
and at material and nanoobject paths could have these as internal

It is likely genetic algorithms to heighten the capability of nanoassembler is described online, a bootstrap IC wafer version makes millions or billions of nanoassemblers then the ones best at assembling things are found, studied, their capabilities
concatenated and genetic algorithm screened again

Analogous to a monopole-like Halbach array, electret square arrays could have a very electret side and a non electret, even electron ignoring side (without chemically being Teflon), if either or both of these is possible then super slippery non-sticktion
material and nanoobject transport paths as well as very-much-stay on it paths could be made with SiO2 electret (bootstrap IC technology uses lithography to make these enhanced paths) paths and Tetris piece sides

At an SiO2 surface perhaps a nano hamster ball or hamster cylinder big sphere full of power, eentsy line tread could make voltages sufficient to resurface, modify electretness of travel pathways

Carbon dioxide food maker and social companion robot maker

At nanoassemblers that eat rocks Aluminum hydroxide gel batteries chromotography at insulator then connect conductive pathways to different chromatography bands use separate chrmotography bands as battery chemicals, thermoelectric, photovoltaic TiO2,
sand dune collapse avalanche electricity, nernst battery arrays (chromatography and concentration) Fe3O2 ->Fe2O3 generates electricity, these occur in rocks, bacteria can live off an iron oxide cycle

With a Nernst battery evaporation can produce the separate values of ion concentration, if drexlerian acetylene to diamond makes warmth that could actually drive the Nernst battery, which uses water as a place to have the ions

At crystals phonons and plasmonics has to do with the.patterns and movements of holes in a crystal lattice, kind of reminds me of proton conductors, physicists could find out what the biggest plasmonic hole they can make in a crystal is, computer models
could then figure out how to stimulate plasmonic inputs (likely but not necessarily at the perimeter)

Possibly Sponge on the exterior, plasmonics then travelizes the missing nuclei to designed locations in the crystal, making Tetris pieces from novel cleavage (custom shards), or making detailed hollows as mold forms, pallet nest tool/object hollows,
Making the largest plasmonic hole could benefit thermal/jiggle management as well making shock absorbers and even dewar flask (thermos like) hollows,

Physics researchable, if you use just 1 or 10,000 photons at a detector can your optical path be much smaller than the wavelength of light, nanoparticle suspensions like Fe2O3 have color, are they reacting to wavelengths thousands of times bigger than
they are, or kind of amusingly, are 1000 of them just lining up in solution to make a big antenna, IR spectroscopy of water and conversion of AGNO3 into silver from light suggests triatomic sizes of photon detectors are possible, if these can detect
quantum entangled photons, causing another of them to identyize like New Scientist quantum camera then nanoassembler and nanotechnology could have data communication without light wave sized optical paths

A dense chunk, a beehive with frames, or calm worlds in a a feedstock refreshing fluidized bed, calm worlds at a fluidized bed might get continuous piezoelectric power from their exterior

Also, the antenna compared with Ag ion size difference, and the Fe2O3 nanoparticle solution having color even though i think the nanoparticles are smaller than a wavelength of light and quantum dots emitting at wavelengths hundreds of times their
diameter, all make me think em power transmission can be done with a nanoantenna thousands of times eentsier than a wavelength of the EM energy

read about coherent warmth (different than IR)

What might work is a big area capacitor with electricalal connectors hanging down from it at part of the nanoassembler, also these are macro enough IC tech 7 nm conduction pathways, I am reminded of compressed air tanks with hang down places to connect
pneumatic tools

Quantum dots on stalks as local energy harvesters, perhaps even though there is a huge wavelength mismatch they can absorb "coherent heat" that I read about or IR from it

Electrets last multiple decades or I think longer, it is apparently possible to recharge electrets without melting them

It is possible a nanostructures electret could

A flying (travels independently through gas) inkjet printer from human visible drone to nanotechnology, nanoassembler size

Quantum camera lens could scan a bigger thing at 3d then the other optical path could go through a shrinkifying lens to make a miniaturized image, like making a miniature figurine at AgNO3 gel, different than nanotechnology, at nanotechnology possibly a
larger IC technology object could be quantum camera shrinkifying lensed into changing a nano material to make a shape, circles, curves, and things beyond Tetris pieces, that this can be done non-aqueously is suggested from the existence of solid phase
batteries and solid catalysts, these suggest the write medium could be a crystal, or an orderly heap of nanodust, or a roll of bubble wrap

Trampolines of frequency change, along with vase/face with optional damping shingles that adjust the 3D form of a velocity and angle distribution I think it is possible to increase or reduce the frequency at which something jiggles, moves or rotates,
these could be used at nanotechnology, a merry go round could use centripedal effects to make all the things at its perimeter wiggle ( linear translate, but also stochasticize differently) less, I do not know why a rotating penny at an angle to a plane
makes a higher and higher frequency sound but that is one way to heighten a frequency, perhaps it still works without gravity if you have the nanopenny spinning on an attractive gravity replacing electret or an orders of magnitude higher attraction
electrostatic voltage clamp, also if you put a pole or tube on just the upper side of a rotating penny-at-an-angle then the pole sswoops out a cone and is sort of like a continuously varying gear, with the top of the pole the widest radius gear, and all
of the pole or tube where the diameter of the trace out (spline) is less than the diameter of the penny is like a gear smaller than the penny, this is kind of like a gear with one tooth, but if you like you can put a circle of tubes on the penny and make
a variable multitooth/peg radius, and gear-for-ratio gear this could have value as an adjustable frequency (higher with option of less frequency amount) rotating motive power source at nanotechnology and nanoassemblers, after it winds down to lay flat a
nanoactuator could lift the penny with tube back up to about 89° for it to rotate again

i have seen images of nanotechnology gears, which with gear ratios is another way to do something multiple times faster like flinging bismuth diamagnetic mold releaser onto tetris piece molds, predictably rotating a drexlerian AFM tip nubs on wheel as a
perimeterized atom or nanoobject placer or at more gradual velocities using an AFM tip to actually break apart a molecule for materials

some systems automatically geometrize (the shape causes the effect) to have a fast and a slow region, computers could do something with Milliken oil drop levitating nanopowder reynolds numbers, a fluid travels faster in the middle of a pipe than the
sides, if a nanoassembler wants to get a feed of some kind of atoms or nanoobjects at some velocity it could tap different areas of a pipe, this might or might hyperbolic paraboloids

Big chair/boat conformation molecules, optimally inorganic (Boron, Silicon, sulfur) benzene, not actually a gear but has possibilities, shift between a 3D crinkle boat and chair shapecrown ethers

At a travelling nanohampsterball

Inorganic Silicon polymer liquid crystals might be possible, twist and untwist, lengthening, also stiffen for better levers, it approaches being chemistry but one distal tip could have lots of charge or a dielectric paddle on it so it sticks to something
it is levering, alternating current-like thermoelectric electrostatic things are previously described so it could glom when it wants to push or pull and go neutral or repel when it wanted to move away

Also Si liquid crystal Shock absorbers

Network theory have process at an intermediate value that you can velocitize or slow, so if you are nano assembling on a turning merry go round you can slow the merry go round, which uncompresses and causes things to spread out more when they jiggle, or
speed it up to reduce stochastics and reduce the spontaneous travel length of material



As a human visible and hearable thing, Rotating Penny with acoustic pitch raising at each of a group of disks of sizes that make compatible notes together as their sound moves upward, a new to me thing

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