Research PapersNo Access

Simple mass estimates for resonance(s) being 6 top + 6 antitop bound states and combinations thereof

H. B. Nielsen

The Niels Bohr Institute, Copenhagen, Denmark

E-mail Address: hbech@nbi.dk; hbechnbi@gmail.com

https://doi.org/10.1142/S0217751X16501682Cited by:1 (Source: Crossref)

Abstract

We have long speculated, $^{2, 12, 50 - 62}$ $^{2, 12, 50 - 62}$ that 6 top + 6 antitop quarks due to the relatively large size of the top-Yukawa coupling would bind exceptionally strongly by mainly Higgs exchange. Here we present a surprisingly simple “calculation” of the mass of this speculated bound state. Even a possible resonance in scattering of two such bound states is speculated. For the “calculation” of the masses it is crucial to assume, that our since long speculated principle “multiple point principle,” $^{5 - 18}$ $^{5 - 18}$ is true. This principle says: there are several vacua all having almost zero energy density. Further, we make an approximation of the Higgs Yukawa potential essentially replacing the exponential in it by a step-function. The new result means that there are now two independent calls for our bound state having the mass around 750 GeV required by our “new law of nature” the Multiple Point Principle. It should be remarked that in our picture there is no new physics in the sense of new fundamental particles, but the “multiple point principle” is new in the sense of being not yet accepted. Further, we get the same mass within uncertainties as earlier² but now from a completely different assumption, except for being from our “multiple point principle.” But the two masses are gotten from using different (speculative) vacua occurring in the pure Standard Model.

Keywords:

PACS: 11.15.Tk, 12.10.Kl, 12.15.Lk, 12.38.Lg, 12.60.Rc, 12.90.+b

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