Yesterday I wrote: So, the light weight (125-127 GeV) Higgs is the smallest dark matter black hole. There should be Two Higgs mirror symmetric configurations, one for 125 and one for 127 GeV?.
see: http://bigbang-entanglement.blogspot.nl/2016/11/rigid-string-cosmology-with-massless.html
So I was looking for evidence and found this:
Dual signals emerging at the LHC of i) a 124-126 GeV Higgs boson mass.
https://arxiv.org/abs/1112.3024
A Higgs Mass Shift to 125 GeV and A Multi-Jet Supersymmetry Signal: Miracle of the Flippons at the \sqrt{s} = 7 TeV LHC
see the TWO Higgs Knot images below, of the mirror symmetrical light mass Higgs based on three interlocking "magnetic photons"or Gluons. AND:
Observed dual Higgs mass 124-126 GeV and the chirality of the vacuum lattice.
http://vixra.org/pdf/1611.0101v1.pdf
and also: https://www.researchgate.net/publication/377066296_6x9_2023-B-17-nieuw_Splitting-BH-BB-12
The chirality of our material universal vacuum lattice formed by the massless Axion/Higgs oscillating dark energy field, is supposed to be the origin of these different masses. According to Quantum FFF Theory.
Conclusion: Magnetic radiation can also form these Higgs particle black holes, as we found as evaporation channels inside silicon balls of 1 mm diameter.
see:
Evidence for Evaporating Dark Matter Particles in Silicon fireballs.
http://vixra.org/pdf/1407.0001v2.pdf
Nano Black Holes (dark matter) in Silicon globules made by Leo and Nico Vuyk
The Silicon globules are the product of ball lightning experiments in the Lab done by Leo and Nico Vuyk. see youtube "Leo Vuyk"
Left: internal Silicon globule structure made by CT nano scan at the University of Eindhoven (NL) Internal hollow channels are observed.
According to Quantum FFF theory these channels are postulated to be left behind by travelling and evaporating gluon/monopole magnetic based “Quantum Knots”. structure of the silicon globule, with two different measurements: by SEM imaging (grey Right: Details of the incolor) and EBSD imaging (colored inset) also by TU Eindhoven.