2ne→ne+ne(photon)
one of the resultant the particles aψne is the photon emitted, from the post "Good Morning Big Particles Split" dated 24 Dec 2017,
aψπaψne=1.5
aψπ=1.5∗aψne
and from the post "No Experimental Proof" dated 29 Jul 2016,
aψπaψc=cosh−1(e)cosh−1(e1/4)=2.24921
we have,
aψc=1.52.24921∗aψne
and from the post "Sizing Them Up" dated 3 Dec 2014,
aψne (nm) | λne (nm) | fne (GHz) | aψπ (nm) | λπ (nm) | fπ (GHz) | aψc (nm) | λc (nm) | fc (GHz) |
19.35 | 121.57 | 2466067.5 | 29.02 | 182.35 | 1644045.0 | 12.90 | 81.07 | 3697802.5 |
16.32 | 102.57 | 2922728.6 | 24.49 | 153.86 | 1948485.7 | 10.89 | 68.41 | 4382553.6 |
15.48 | 97.25 | 3082568.8 | 23.22 | 145.88 | 2055045.9 | 10.32 | 64.86 | 4622229.7 |
14.77 | 92.79 | 3230699.3 | 22.15 | 139.19 | 2153799.5 | 9.85 | 61.88 | 4844347.4 |
The first row of the table gives the values of aψne, aψπ and, aψc for temperature particle. This particle is identified solely base on the value of fne=2466067.5GHz resemblance to microwave heat frequency a million times smaller at 2.4GHz.
The rest of the rows, if they are due to other particles and not part of a spectral series for temperature particles, gives the relevant values for the other particles, yet identified specifically.
It is likely that this is just the temperature particle and its spectral series.
Have a nice day.