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Introducing the ion tower
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The ion tower in planet orbits, to zooballs. Orbits of earth, venus, and half way in between, convert via compton wavelengths and unique KKK ratios, to ion tower mev terms.
KKK ratios (King Kong Konstants) multiplex between alert xion mass and energy states in 5, 6, 7 times, and 5, 6, 7 divided, whole number combinations. KKK multiplexes yield the octuplet, and decuplet, su3 particle sets.
Brief summary tables for su3 octuplet and decuplet can be found mingled among pages of Set 21 which includes the KKK first discovery page.
ZOOBALLS IN THE ION TOWER
Each Zooball has an mev energy of (.08778079044 mev).
The ion tower main segment is 8 zooballs increments, between two stations determined from KKK results of the orbit of venus (lower), and the mev KKK result of the in between orbit of (1/2 earth + venus) = (top of the ion tower).
In this interval are the binding energy of the Lambda (1/2+ Lamba - 1/2+ Proton) = 177.410971 mevs, term 4, and the binding energy of the Neutron, term 2.
The binding energy of the Neutron (1/2+ Neutron - 1/2+ Proton) = 1.2933318 mev, times the (fsc) = 177.233016129, term 2. The two term's energy difference is (2 x .088974355 mev).
Exact zooball matches can be chisled in, in that the ion tower has strategic hiccups according to excited electrons and is not lineally smooth throughout. The chisles are akin to chisles in atom spectrums according to isotopes beyond single standards for all of an element's spectrums.
ZOOBALLS ARE EVERYWHERE
Zooball mass energy (.08778079044 mev) occurs throughout, determined from 1/2 the proton mass divided by the (fsc), the result divided by 3 = .08778079044 mev. So far, no answer has been found for why (1/2 proton divided by fsc) is divided by 3 to yield a zooball energy particle. Zooball energies, singly, and in unit whole number multiples, turn up all over the place. Zooballs are missing links which bind together particle resonant masses.
Particle masses bound in the ion tower's absolutes include Psi (1s), Psi (2s), and bosons (W+-) (Zo), and all three stable kaons (K+-) (Ko). There can be no deviation in the exact calculated masses of these specific particles. The masses go to 12 significant digits.
There are hints that the ion tower derivations, accurate beyond 10 significant digits, deviate at the trailing end, due to input uncertainties from known particle masses in the PDG particle mass data tables, the uncertainty effecting the ion tower ultimate determination of the Kaon masses.
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