h2g2 The Hitchhiker's Guide to the Galaxy: Earth Edition

Since wave length l=2*pie*radius, could the Gravitational constant G contain units of (wavelength^3)/(mass*time^2)? Making G*m*l = G*h/c = l^4/t^2, m^4 s^-2?

A quantum particles spin being some kind of 4 dimensional time dependent continuous rotation of one real plus 3 different imaginary axis values, while the polarization of the same particle has one real plus two imaginary axis?

Is 4d spin similar to 3d circular polarization ?

Circular polarization being rotation about the E,volts per meter axis(where a rotation of "i" is equivalent to 90 degrees), while spin is some kind of 4d rotation(Dirac Spinors ) involving 4 quantum probability (psi) waves( where "i" is equivalent to a rotation of 180 degrees)? I`m still confounded by quantum stuff? Or is it as suggested in "Schrodinger`s Universe" by Milo Wolff, an in-going probability wave coupled by spin rotation to an out-going probability wave?

If two of the four probability waves join up by 4d spin rotation to form an electron, are the other two unused probability waves used to form neutrino? Are other particles made by different combinations of the four probability waves?

Leptons would suffer from Gimbal lock if they only had three degrees of freedom?

See: Doing physics with quaternions, at "world.std.com/~sweetser/quaternion/qindex".

See C.L.Herzenberg`s pdf. "The Quantum-classical transition and wave packet dispersion".

See p.d.f. "A new basis for interpretation of the Planck Length" by C.L.Herzenberg. If the Universe has critical density and mass, what are the mechanisms that maintain them at these values?

Quaternions( 4 by 4 matrices ) & gimbals rotate about straight lines( axis or metric ), but space time curves these straight lines in a very fractional( fractal ) way, are the two types of maths compatible?

See "www.greenspun.com/quaternions", the quantum realm is about real events in imaginary space(below the critical line length ), whereas space-time puts the emphasis on real space and imaginary time(above the critical time line)?

A particle starts as an event in time, hangs around as an expanding time bubble in all imaginary time directions, encountering other expanding time bubbles arriving from all imaginary time directions? Could time-space be a complex conjugate of space-time?

If position becomes indeterminate for lengths shorter than the Planck length, dividing by light speed "c" for time periods of less than Planck time, <(~0.5*10^-43 seconds) would also give indeterminate time periods?

A particles initial time bubble expands from, T=h/m*c^2, seconds. dependent upon its initial inertial mass?

The particles time period T=h/m*c^2, seconds, being a spherical like, oscillation of an underlying field of much smaller particles, that can travel at up to light speed between interactions. But then these particles could also be oscillations of a yet smaller faster particle field, and yet again(fractal foam)?

See "from quantum foam to general relativity" at "arxiv.org/abs/gr-qc/0203015".

"THE WAVE WATCHER`S COMPANION`, mentions that oil spreading out over a ponds surface, suppresses the formation of ripples, if matter wave particles have a range or distribution of sizes, would the more numerous smaller particles lubricate the middle in the range, while the fewer larger sized particles impede the middles motion?

Could the refractive index of space vary above and below one, if the distribution of matter wave particles sizes were found to vary with location?

In my previous message I asked if the the refractive index of the vacuum of space could vary above and below one, since the refractive index is the ratio of light velocity measured at a location in space and time, to another location in space and time. If light speed in a pure vacuum is constant everywhere and every when, then the ratio is one, but it would also be one, even if the maximum velocity were v>c, which might be the case if the matter wave medium came in a range of particle sizes?

If a vacuum is more than empty, full of matter waves, supported by a matter wave particle medium, an increase in the velocity of these waves beyond 299792458m/s could require a change to the makeup of the particle medium? How could the medium mixture be filtered or diluted?