High volume Rydberg atoms have vast areas of volumetric space which functions as addressable data locations. Quantum linked photons could read these, similar to quantum camera technology. Published Casimir effect technology could provide photons or energy, concentratable with an etalon to provide regular program advancing energy.

Rydberg atoms are high volume atoms. Think of the volume of an atom. It is possible Cs has a diameter of .53 angstrom, while a Rydberg atom could be centimeters of radius (or possibly larger). If you think of all the locations that an electron could be at then that volumetric area it is much larger at a Rydberg atom.

Compare coating a Christmas ornament with honeycomb, then compare coating a planet like Jupiter with honeycomb, the actual number of little area blobs is vastly larger, thus when you think about the location of an electron as a volumetric thing a Rydberg atom has ultra vast data location enumerability.

One possible calculation is that there are about 1.3 1000 moles of data locations per atom at interstellar areas (6.02 * 10^23) (1.3 *10^3)

(Pleasantly, the original notes are on the next page, then it is back to presentation mode.)if you like you could go bigscreen then pause, or view the presentation as Powerpoint.

computronium forms that are new to me thifield average could locate cenimeters away from the nucleus now think of the way that volume represets numerous more computational spaces that

are actually different than quantum levels noting the radius of a Cs atom at .53 nanometers each cm of electron

spheric radial locationality represents 1/1000th of 4/3piR^3 * 2 *1 billion nanometers 4/3pi((1billion)^3)*2 kind f like 8*10^30 different areas the electron could be at spatially, absent thoughts about quantum levels so there are about 1.3 1000 moles of data locations per atom at interstellar areas each of which also has an available quantum number multiplier or better (use two nuclei customize or multiplt the number of emissions lines that molecule as compared to

atom, could produce) along with being readable with quantum linked photons possibly quatum linked neutrinos it is possible that the peer reviewed published casimir effect could describe a new thing that optimal volume of space where the likiliness of spontaneously generating an

electron or photon or other computational particle has the regiospecificity of a circuit to participate at remotioning an electron at any of the 1.2 thousand moles of possible nuclear diameter spaces this ratio could be tuned to be above the amount of power to advance a

computation (like automata or analog or turing or another approach) or a just the preferred amount to advance a computation so these eentsy little shapes of near vacuum nterstellar space could be tuned as memory registers that also produce sufficient nergy to compute there is also

the perspective, well what is the optimal actual atomic nuclei distance to optimize available memory equivalent? Is it possible to make meter or kilometer radius atoms? Describe a way to cuase the electron to actually prefer just a part of the electron cloud distribution think on the

phospherescent nonemittive quantum levels that cause minutes of photon electron nteractionso that’s a new to me kind of computronium

With the Rydberg atom, the data volume is then multiplied with the available electron quantum levels of the electron. Volume locations multiply with emissions spectra possibilities to contribute to data storage space.

Are there Rydberg molecules?Contemplate using two nuclei this customizes or multiplies the number of emissions lines that a Rydberg molecule as compared to one atom, could produce.

How would you read this data?Quantum linked photons or possibly quantum linked neutrinos. New Scientist has an article describing the quantum camera where a laser produces quantum linked photons. One of the quantum linked photons meets a figurine, the other quantum linked photon meets an image sensor. The computer image sensor makes an image of

the figurine although there is an absence of any optical path from the figurine.

Thus a photon or other quantum linked thing directed at the Rydberg atom causes an effect linked to the electron location; then at a distance that which the quantum linked photon is linked to communicates with a computer sensor. Although I am absent data, I think it is possible that a photon could be quantum linked to a particle like a neutrino rather than just (or possibly with) another photon. So the eentsy photon activates the quantum linked mass bearing particle at a distance once the photon meets the Rydberg atom.

An energy source that goes with a Rydberg atom computronium is the Casimir effect. The Casimir effect is published at peer reviewed literature as

measurable.

I think Wikipedia describes the Casimir effect as the spontaneous generation of energy as well as matter from vacuum.

Notably the Casimir effect apparatus looks slightly like a capacitor symbol -||- where the nearness of the side matter effects the frequency of vacuum

generation of energy or particles. So thinking of things like USB flash drives where each mere GB has about 8 billion eentsy | | mass produced reliablyit is possible to create a Casimir effect generator with a trillion | | areas.

(Note the 512 GB usb flash drive actually has 8*512 billion4 trillion | | now)

So the thing is, is there a way to arrange matter at a vacuum such as interstellar space where the Casimir effect produces more electrons than reading the data uses? That way the Rydberg computronium computer is autopowering based

on the observed physics of the universe.

it is possible that the peer reviewed published casimir effect could describe a new thing that optimal volume of space where the likiliness of spontaneously

generating an electron or photon or other computational particle has the regiospecificity of a circuit to participate at remotioning an electron at any of

the 1.2 thousand moles of possible nuclear diameter spaces

Think of an etalon. This is slightly like a resonance tube with adjustable geometry. Tune the geometry to produce the preferred frequency.

Now think of placing a bunch of Casimir effect producing || at one area of the etalon the vacuum produced energy or particles then etalonizes (or if you prefer resonates) to cause a higher energy concentration at a particular area of the tubular geometry

That higher energy concentration area is where the Rydberg atoms could be at, with an ultraregularized energy effect that provides energy to do the computations, notably possibly even the photons that produce the quantum linked reading of the Rydberg atoms.

The energy produced at the etalon could be tuned to be above the amount of power to advance a computation (like automata computation or analog or Turing or another approach).

The geometricization of computer program form as a volume suggests high parallelism of computation. Also there is the possibility of creating aperiodic volumetric computation, possibly making some kind of Penrose tiling completely automatic as a result of the shape of the etalon, with possible MWI functionality.

so that is a kind of computronium