afa utilize at coinduction a different view, a finite plural view, a nonfinite plural view, just n set elements of viewing heads,


making microparticles, and nanoparticles, is there such a thing as a picoparticle?

Genetic algoithms used to grind finer particles: https://www.sciencedirect.com/science/article/abs/pii/S0032591006005250

a .5nm - quantum dot is published, so they could make picoparticles.


so milling powders, solvent; from zero to 21 waters of hydration; GA

Deuterium, is gooey water; and can be reuesed is 68c/gm online; does it grind powders differently?

if powders are ground with ice crystals, do the come out smaller; microcomminutors,

grinding powdres n liquid metal; reuse eutectic, gallium,

grinding powders in hydrocarbons like gasoline compared with oil, e-thixotropic could make oil variable viscosity/ 10W 40, genetic algorithm finds temperature optima for sequential microfine to microfiner particles at grinding oil, honing an edge on
oilstone suggests smaller particle scrape size for oil milling of things like battery ingredients, other nanoproducts

if a solvent is 20% microparticles can you use, at some fancy application, flow cytometry to get down to smallest flow cytometry feature particle size where microfluidics then sorts things to microfinest, microfiner, and others, which delivers microfiner
to grinding apparatus

plasma deposition on oil surface like conductive PEDOT 60% oil, that is stirred makes super eentsy nanoparticles;

rinsable zeolite; stir microapeture forms that are cheap to make like zeolites, or “hard zeolites” with ground up powder; the zeolite pores fill with the finest of microfines (nanopowders) the dissolve zeolite to get powder or acoutically wiggle
zeolite to get powdre and reutilize the zeolite.

the internet syas, “The process conditions were milling speed, milling time, and ball to powder weight ratio.” milling speed; relative to neighbors, entrained groups of particles compared with maximum degrees of dperical coordinate motion “milling
speed” sort of like pressing the shock-pulse button on a blender, is highest disorder millinging, compared with a milling that has more linearity faster way to grind particles, use a genetic algorithm to make the optimal thing, at the preferred
particle size and what its made out of of. That stirred stuff in a blender looks linear; fluidized bed is perhpas non grinding but highest stochasiticity; fluidized bed next to milling balls could make eentsier particles faster. ThZ fluidized bed,
comparing linear swirl in a blender to pulse stachaticisms, at ball milling, could stachasticizing the balls more make for finer powders faster; if ic could then the middle of each ball at at balll mill could have a magnet in it, and an EMP field could
thump the balls at the ball milling process at any frequency that optimized ball milling stochasticism. The ball mill balls could, rather than have actual magnets in them, have electric path windings (coils) in them that could be induced by an EM field
to be magnets that then interact with another pulsed EM power field (maybe), via hysteresis and ferrite bead cores.

also grinding things like battery chemicals one way of grinding might make little spheroids, but another way of grinding might make plates, sort of rice krispie lookinng micro-shingles; magnetic moduclation might caue it to be possible to bear down on a
thing being milled, causing more of the squished looking microshingles.
it might be art: physics simulator deoes prince ruperts beads, genetc algothms traverse a variety of form of PRB, including ones where the tail is tucked back into either the still molten main “blobhead”, or something like a PRB that is a dounut or
cylinder bead, and the tail tucks back into the hollow od the dount or tail

elevating a GA with stochastics like adding snow to a picture breagings out the features; there’s a GA, and you add feature brinking out snow to it at three areas i’ve heard of, beginning, local minima, local maxima, to see if it either does a
better job jostles of “localnes” or even at a maxima, makes the the you are maximizing more maximal, that is more of what you want tis present; this could be translated into math and computer programs

zeolite grab, causes diminisment to omit occuring from happening; ball mill powder sequesterment and subsequent result of particle size;
or you could just rinse it out;


Islands of sand, and the islands respond to ultrasound with jumping around to make maximum disorder;

is acoustically enhanced milling, if it makes sense, enhanced by using a monoatomic gas of of a particular pressure to most effectively transmit wiggleness to micro/nana/picopowders;

Is milling in liquid hydrogen a smallest picoparticle maker; as previously described likid Kr or Ar is much cheaper, easier, but what about the even cheaper milling with ch4, LNG, as a lubricant? The peltier effect gets to -70, and ethane liquifies at -
88, so a slight betterment or cascade of peltier effect could make liquid ethane, as could of course a gas-cycle refrigeration device;

.5b Thinking of a blender with powder in it, then thinking of a blender with balls in is to crush things more effectively:

The blender stirs and it looks like kind of orderly from the top, “perhaps”, you think, “There is a way to send a sudden reversing shock into the blender-stuff to crush it finer, crush more of it, and even crush it with greater efficiency”

Then you notice the blender has a “Pulse” button, when you press it the blades reverse causing a moment of reversal and posssibly stochasticism in what looks like regularly swirled ice cream in the blender. It works pretty well too.

Now, applying the pulse button to indudustrial milling, rock grinding, and making hyperfine nanopapowders (or even picopowders) for bettter battery ingredients.)

At the mill or blender that is a stirred, tubled, or press-rollerered way of making powders or microchunks have beads or balls in the mixture.

Each ball of bead has a little loop of wire and a magnetic (ferrite) core it it; the inductor is connected to another loop of wire (and likely ferrite core). If you put the bead in an alternating magnetic field it will make a new very powerful field
right next to it.

Mix the beads with what you want to grind, then, at whatever frequency of making the beads Pull together, push apart, or hop away from the machine sides (magnetic sided machine and option) causes the mathematically modelled finest materials, or fasted
generated materials.

So, this is a way to install the “pulse” button on a variety of industrial mills (rock crushers to battery chemical makers)

what if the peanuts in flat peanut brittle started jumping around? at a roller mill —-8== the flat stuff getting ground could have reusable jump around beads in it.


20-40% more efficient than a rock tumbler *ball mill*

laser refresh grinding surface \/; thz interferometry reads crushed rock, flexifies the plaes of the v to toptimize forces for milling materials; a little convex or concave heere or there ups efficiency slightly; em windings, acoustic transducers, mixing
of pusling of between \./ crusher plates is also possible.

99% electric motor suggests 99% linear actuator suggests 99% acoustic energy efficiency if run at various higher Hz; attach to crusher plate \./ for optimal crusher plate shape;

henetic algorith all shapes between ——8=== rollet mill and \./ crusher plate to find most efficient; at some materials is it nested )) vibrating funhouse mirrors; genetic algorith makes library of top 100,000 inustiral substances, including battery
materials (2020: nanoparticle picoparticle lithium molecules)

3D printed linear actuator overlay for exterior sied of (.( or \./ reminds me of printing motors menioned on .5b

you could increase efficiency of a ).) or (.( crusher that has linear actuator sound raster scanning it to optimize crusher plate flex by putting the entire thing in a tank of water, or pressurizing the room it is in to multiple atmospheres of pressure
for better sound transmission.

foam, compare with bendy lace polymer atom-to-atom linked doilies, acoustic flexion (holes all over the graphene. boron polymer, si polymer, zeolite tennis net), or other kind of (n)Hz frequency response material ; among other uses this dry powder could
be placed in squishy foam earplugs to filter out any frequencies squishy foam earplugs are less good at; cheap car mufflers (zeolites),

“quiet” graphene additive to oils dampens vibrations which might cause surface-surface contact and wear, making the oil cause machines to last longer;

Could a noise dampening oil additive actually work? Could it reduce nonfan vacuum cleaner screech?

doily graphene oil doliy garphene polumer, doily anechoic mattress wiggle stuff polymer, cushiony seats at cars and motorbikes,

genetic algorith could develop a better car muffler; psychology of lest preferred vehicle noises from traffic, and mufflers that minimize those (accelleration noises) Putting an ICE in a polymer dewar sack, like literally, a coulple big mylar bags with
either (very fewest that will do the job) little nubs molded into the mylar or hollow core bead spacers and vacuum between them; applications at road trcuk engines to make them quieter. duomylar vacuum dewar around vacuum cleaner motors, boat engines (
quieter pleasure boats) HVAC motor mylar bags, dwelling refrigerator motors, genetic algorithm finds nub spacing and patterns at fun software that makes a custom bag geometry for anything you want to put in the dewar bag.

The delux version the mylar bag is made of a moise reduction doily polymer, or a still supports a vacuum, mylar foam film;
stuff a noise reduction mylar bag around the interior workings of power tools like electric drills, circular saw motors,


genetic algorith quietness producing acoustic ceiling tiles, floor tiles from a math space of 10 dewar bead polymer materials, various heights, different frequencies, different apeture patterns, say 10 inds of sounds sources (classrooms, offices,
factories, restaurants, retail, concert halls, public transit (I’ve never seen acoustic tile on a Light rail train or city bus, but you can hear people and vehicle during the 20th century), possibly something like acoustic tiles are placed in driving
vehicle panels, an acoustic tile sticker could be placed next to a PC fan, although that seems kind of 20th century, the backs of frisges is a novel new application of acoustic noise reduction dewar paint or genetic algoithm optimized acoustic tile. The
radiator seems to hum a little, but I could be imagining it, and right next tothe motor would make fridges quieter.

A person with even the slightest sense of the future could see replacing all the metal ductwork in an internal combustion vehicle with dewar peanut brittle sound absorbing polymer ductwork; whether that is the exhaust system, saving weight, increasing
mileage.

genetic algorithm of vehicle tire construction finds optimal performance with new materials; Dewar microbeads could make tires quieter,or maye just mildly better as perhaps tire noise is really 50% of the noise coming from the road meeting the tire, not
the tire.

Previously described doily graphene or other polymer oil


as a new and extreme material, a dewar microbead could be made of something wettable with steel, like ceramic, so make a new “peanut brittle” steel that is less thermally conductive, with different coefficients of thermal expansion, and

Also, I keep mentioning dewar beads, what of other MEMs shapes? At steel or otherwise, MEMs guitar boxes, MEMs octopus/dendrite multiarm big center bubble jacks (big bubble reduces weights, octopus arms might actually traverse distance beentween grain @
grainsize in steel, causing the thing to be strnth-neutral to strength increasing. MEMs jacks that are so small they have their octopus/dendrite arms between, perhaps 2-3 shells of metal grain distance; this strengthens the steel, changes its
flexibility; (kind of reminds me of central neurons and axons and dendrites); at the 1000 most used steel alloys, do genetic algorithms on the MEMs dendrites and octopuses that are easiest to make, to find the cheapest new extended capabilities of steel,
like Octopus 10,000 at grainfrom steel 555-A is, according tothe model, then the actual manufactured test material, 100% more rigid, 3% less likely to rust, and melts 500 degrees higher.

MEMs dendrites could of course also be used on high performance alloys like airplane part engine metals. Economics May be highly favorable as dingle crystal tungsten metal blades have been seriously considered at these applications so making MEMs
intergrain octopuses and dendrites looks alot cheaper than that.

Actually genetic algothms to see if MEMs dendrites and octopuses can reduce rust and corrosion at any metal is beneficial. Something cheaper than stainless is great. One possibility is that MEMs octopuses are charge-doped, so then tend to be plussy or
minussy next to grains far along the arms, “ampihilic”, “zwitterionic”, “highly polar”, “nonpolar” analogous MEMs octoupuses could be made and tested, with of course some modelling and computr simulation, for corrosion reistance chnages.
One kind of exciting possibility is that metal with self limting corrosion like aluminum forming an aluminum oxide (sapphire) film on it, is that outside or at another application the MEMs octopus containing alloy would oxidize/corrode/react down to the
geometry area the MEMs was directing, where things like “highly nonpolar” or “like the eentsy metal conductive traces on the surface of a photocoltaic that carry caurrrent away”-> e- charge distributing across multiple grains simultaneously, 0r
whatever happens when a MEMs electret meets a charged surface.

Making MEMs octopuses and dendrites as cheaply as possible; just grow them, dendridritic polymers are widely studied already; 2) using a diffraction grating, send lasers into condensing ceramic fog; at 3D, quadrillions, petillions, zeptillions, of litlle
laser condensation shapes canbe made; or, rather, perhaps their negatives made; if I make a laser thing that looks like a grid, and I wiggle the temperature and prssure to cause condensatin, perhaps there’s an absence of any condensation where
thelaser is, and nine little squares [] condenseout of the 3D mist.

So tomake a dendrite, the light shape is just a plate with a hole in it, everything outside the hole stays uncondensed, and the atoms condensing are cool and agglmerating (building upfrom fog) in the hole in the plate.
diffraction grating laser light spaces canbe 3D so you can make a dendritic jack as well as anoctopus.

Depending on the condensation

at a tangentially related technology .1/10 1nm (100 picometer) vertical coating are constructed with publised IC technology, so regular and eentsy items forming with extreme regularity from condensation is published, Ijust don’t know about at 3D
volumes, kilogram quantities, from the cheapest molecule or metal vapor that can be produced

If the dendritic cotpus is made of metal-wetting cermaic a Cr alloy is supported by high Cr having much better glass-metal bonds; Notably an alloy that is 1%Ni or 1%Cr or 1% W or 1% V or much more than 1% on any of these is well known at the steel
industry, so a dendritic octoupus made out of Cr,W, etc.
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All technologies, ideas, and inventions of Treon Sebastian Verdery are public domain at JUly 8,2023AD and previously, as well as after that date

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