Analysis of mass-ratio figures

Some of these ratios are extraordinarily close, and are close enough within the experimental +/- figures for some of them to be considered as exact ratios: the top to higgs figure and the charm to strange for example are close to the exact ratios by an accuracy of over 1 in 2,000. To understand the significance of these ratios however it is necessary to also take a comparative close look at the ratio of T and V composition of the particles.

Bear in mind that the hypothesis is that the mass of each family of particles is identical: we therefore expect there to be a direct relationship between the ratio of T composition of any given pair of particles and the mass ratio of the same pair.

Looking for example at the charm quark and the proton, the charm quark has six T particles. If the charm quark has a further three V particles which cannot in any way be influenced by electrical activity, we expect a ratio of 9/6 (1.5) to factor somewhere in the over-calculation of the charm quark's mass (relative to the proton). The 2/3s root comes out at 5/4 (1.25).

In each case, although there is a tantalising relationship clearly present, what can definitely be said is that the more T particles there are, the lighter the "apparent" mass of the particle. Put another way: the more V particles, the heavier the "apparent" mass of the particle. This even applies when comparing the strange quark to the charm. Numerical coincidences abound: the cubic root of the mass ratios of strange to charm is 17/7 to within 4 decimal places, and there are seven T particles in a strange quark.

    Name      T  V T-charge Mass         Mass * T-charge

    Electron 3T 0V    3/3     0.511 MeV      0.511 MeV
    Up       2T 1V    2/3     2.01  MeV      1.340 MeV
    Down     1T 2V    1/3     4.79  MeV      1.596 MeV

    Electron 3T 0V    3/3     0.511 MeV      0.511 MeV
    Muon     9T 0V    3/3     0.106 GeV      0.106 GeV
    Tau     15T 0V    3/3     1.777 GeV      1.777 GeV

    Strange  7T 2V    1/3     0.09  GeV      0.03  GeV
    Charm    6T 3V    2/3     1.29  GeV      0.86  GeV
    Proton   5T 4V    3/3     0.938 GeV      0.938 GeV
    Bottom   3T 6V    1/3     4.18  GeV      1.393 GeV
    Top      2T 7V    2/3   173.07  GeV    115.38  GeV

This table ranks the particles in order of mass times the electrical charge of the particle. In each group it can be clearly seen that the number of T particles is in descending order. (Note: the Muon, Tau and electron are separated out, being entirely comprised of one or more electrons and zero or more positrons. This is still under investigation).

Note: Here we see some striking coincidences as well:

Mass of proton divided by Strange quark is 10.42, which is close to 7 * 3 / 2
(10.5).  seven T particles, 2 V particles, 1/3 electrical charge on the strange
quark.

Mass of up quark divided by electron is 3.933 (close to 4).  three T
particles, 2 V particles, 2/3 electrical charge: 3 * 2 * 2/3 is 4.

Mass of down quark divided by mass of electron is 9.373 (close to 9).
down quark has a 1/3 electrical charge.

2/3 Mass of charm quark divided by proton is 11/12 to within 4 decimal places.
Charm's T-particle content plus Proton's T-particle content: 11.
Charm's V-particle content times Proton's V-particle content: 12.

TODO: examine these relationships further.