On Apr 29, 12:42Â*pm, wrote:
Â* Â* Â* Â* The simple equation "( n/2 )^5 . n= 1 to 11"
Â* Â* Â* Â* has 11 values that map in a simple mathematical fashion
Â* Â* Â* Â* to the entire range of Elementary Particle mass QED.
Â* Â* Â* Â* n Â* Â* Â* Name Â* Â*e mass Â*error% Â*Energy
--------------------------------------------------------------------------- ---------------
Â* Â* Â* Â* 11 Â* Â* Â*MAX Â* Â* 5033 Â* Â*1 Â* Â* Â* 2.6 Bev ; Observation set limit Â* Â* Â* Â* table maximum
Â* Â* Â* Â* 10 Â* Â* Â*Om Â* Â* Â*3124 Â* Â*4.6 Â* Â* 1.6 Bev as Tau and Omega range
Â* Â* Â* Â* 9 Â* Â* Â* Proton Â*1845.3 Â*-0.5 Â* Â*943 Mev Â*Proton
Â* Â* Â* Â* 8 Â* Â* Â* K' Â* Â* Â*1024 Â* Â*-0.4 Â* Â*523 Mev Â*---- K' as Half of Kaon and Eta sum.
Â* Â* Â* Â* 7' Â* Â* Â*Pion Â* Â* Â*275 Â* -0.7 Â* Â*(243+32 ) as 7'=6 plus UNIT /CMF
Â*upper half
----- Â* 6 Â* Â* Â* Empty mid zone at n=(6*2)/2
Â*lower half
Â* Â* Â* Â* 5' Â* Â* Â*Muon Â* Â*211 Â* Â* -2.1 Â* Â*(243-32 ) as 5'=6 minus UNIT/CMF
Â* Â* Â* Â* 4 Â* Â* Â* CMF Â* Â* 32 Â* Â* Â*7 Â* Â* Â* Common Mass Factor at ~16Mev to 18Mev ; a 3D UNIT.
Â* Â* Â* Â* 3 Â* Â* Â* ? Â* Â* Â* 7.6 Â* Â* ? Â* Â* Â* 3.88Mev ; an unknown zone; perhaps Dark matters?
Â* Â* Â* Â* 2 Â* Â* Â* e Â* Â* Â* 1 Â* Â* Â* 0 Â* Â* Â* NEGATIVE electron; reference mass; 0.511 Mev !
Â* Â* Â* Â* 1 Â* Â* Â* eN Â* Â* Â*1/32 Â* Â*0.1 Â* Â* Smallest Neutrino in Tritium Beta decay at 16 Kev; Â* a MIN
7 - 525 - 268 MeV
6 - 243 - 124 MeV
5 - 98 - 50 MeV
4 - 32 - 16.5 MeV
Be honest and say 5 and 7 fail; you got 5.8 and 6.15.
-------------------------- Neutrino Match found at ( 1/2 )^5
Finally, consider the enigmatic (1/2)^5 value
at e/32 masses or 16 Kev.
It is an excellent fit to the observed minimum Energy
of (eN) the anti-Neutrino measured in Tritium beta decay (0.1%) Â*
This doesn't mean anything; there are a world of keV-leptonic decays,
and 16 keV isn't the rest mass of anything.
ν/e: 2 eV
ν/μ: 190 keV
ν/τ: 18.2 MeV
--------------------------- Â*Hypothesis for the zone at ( 3/2 )^5
Â* Â* A new 3.88 Mev mass/energy zone is predicted; It might offer insight into Dark
matters!
u: 1.5–3 MeV
d: 3–7 MeV
s: 95 MeV
μ: 106 MeV
π: 135–140 MeV
K: 494–498 MeV
η: 548 MeV
c: 1.25 GeV
Ï„: 1.777 GeV
b: 4.2–4.7 GeV
t: 174.2 GeV
It's weird how 8 sits exactly between K and η. But there's no order
for your other integers: - e d ν/τ - μπ - Kη p * Ξ/c. 10 at 1.6 GeV
fits too many mesòns and barýòns..
Ever ask yourself "What is MASS and where is it?"
This theory asserts MASS exists in a tiny volume,
a near-nuclear scaled region that has its own laws.
I have loosely titled the theory :
"subSPACE ; The fifth dimensional domain of 3D volume
where the MASS of a Particle resides/exists".
No, the mass is where the field is, so it's not in a tiny room for
most of each mote; however, it's the tiny room thas makes most of each
mass.
================== Â* The Fifth Dimensional nature of MASS is conclusively revealed.
1 Â* Â* Â* Â* Â* n/2 to the Fifth power law maps the entire range of Elementary Particle Masses!
Your scale somewhat works for 2, 4, 6, 8, and 9. 4 may not pan out.
But you start with a tiny mass, and many powers, so you can always
claim they hit other motes with small error. The vast greaterhood of
so-called hadròns are the same two or three quarks in isomeric orbits,
even thouh they bear different names. Each of those hav near-infinite
excited states, which make the PDG's book even fatter. So it's not
hard to hit any of them. The ratio between two masses at exponend 5
is between 2 and 3; as many of these motes are composite of two with
some leftover potential--mesòns and neutrinos--you can fit u-d and c-b
on the scale, but this match breaks up after two generations as the
heavier hadròns must cram in manier bosons for stability. And the
motes on your scale are random; there should not be one formula
between elèctròn and protòn, and the formula within a family would be
better gèometric than exponential.
The muòn's original family was mesòn wherefrom its weiht--as is the
piòn's later--but as it behaved lik the elèctròn they switchd their
mind for leptòn. Also, motes in a family fain decadore within:
barýòns to barýòns, mesòns to mesòns, leptòns to leptòns. Fundamental
motes are already midweiht however and are fermions; so thas the piòn
has integral "spin" (trend) should hintan it's composite of such
motes. As the neutrino isn't midweiht but is a fermion led me to my
discovery of its compositude of fermion and boson:
http://google.com/groups?q=supergenium.
muòn- - elèctròn- piòn- elèctròn+ kaòn+ elèctròn-
piòn- - muòn- kaòn- elèctròn+
kaòn- - piòn- piòn - 'u'd 'u'u, 'u'd 'd'd = s - d'u'u, d'd'd
= piòn- - elèctròn- piòn- elèctròn+ piòn+ piòn+piòn- elèctròn- piòn-
piòn+piòn- elèctròn+
If the muòn is a fat elèctròn, then the piòn is a lean kaòn. But in
the above explication one can see the muòn is merely a common factor
in the piòn-elèctròn series, where the muòn hosts pionium-elèctronium
condensva. No wonder why the piòn spills so shortly. I wonder if
calcium-48 makes a good muonic pith. As the piòn is a fundamental
hadròn, one should redefin a leptòn as such a mote at the bottom--then
the protòn, piòn, quark, elèctròn, plasmòn, iòn, wimpòn, warpòn, and
dilatòn are all leptòns. Their energèts such as hýperòn, kaòn/D/B, s/
c/b/t, muòn/tauòn, radiòn, and whatever elles then are barýòns. Weak
ashhy stabil atoms such as heliòn, nucleonium (degenerate), neutrino,
epsilòn (K elèctròn-nucleòn), and geogen (whatever makes geòns), and
other dark (clear) matter are lastly býssòns.
2 Â* Â* Â* Â* Â* Since "Elementary Particle mass values" Â*are predicted via Â*(n/2)^5
Â* Â* Â* Â* Â* Â* it can not be disputed, given this definitive 5D power law! QED!
-------- 2nd assumption satisfied
They're not elementary, so no.
3 Â* Â* Â* Â* Â* It's Physics and Mathematics in a one to one identity.
Â* Â* Â* Â* Â* Â* subSPACE is real and the observed domain of Particle Mass!
-------- 3rd assumption satisfied
mathematic artefact
Well, that's it; Â*comments are welcome
as well as any ideas about the 3.88 Mev zone ,
as it's the only unknown index in the 1 to 11 range.
If anything is found around 3.88 Mev or its multiples.
it would be an additional validation for ...
The Planck charge solitòn is a better goal.
-Aut