Like Gribov's proposal maybe ?arivero said:one could speculate that the explanation of Koide formula at the end could be not from higgs, but from colour condensates in some exotic way.
Hmm, in an alternate life, in a different Everett's path, I was in Peñiscola in 1997 just in time to hear Gribov's last talk (http://www.slac.stanford.edu/spires/find/hep/www?eprint=hep-ph/9708424 ) and other adventures. To my regret, in this worldline I preferred to stay in Zaragoza or elsewhere, and I have not read these works. Thanks for the reference, it seems that it could fit, or at least give some inspiration.humanino said:Like Gribov's proposal maybe ?
Bound states of massless fermions as a source for new physics
Gribov hep-ph/9708424 said:"The analysis leads to the following conclusion. The conditions for axial current conservation of flavour non-singlet currents (in the limit of zero bare quark
masses) require that eight Goldstone bosons (the pseudo-scalar octet) have to be
regarded as elementary objects with couplings defined by Ward identities"
As humanino said, the Higgs mechanism gives rise to mass but does not explain the values of the masses. The mass is the result of two parameters, the vacuum expectation value (VEV) of the Higgs field, and the strength of the coupling between the particle and the Higgs field. For a model with a single Higgs field, the Higgs VEV experienced by all particles is the same, but the coupling is different.roberto85 said:I was wondering if Higgs theory offers an explanation for why the Koide formula gives such precise masses for the leptons? I would assume that any theory of mass would be able to predict the masses of particles, especially for ones where precise relations have been found between them like the leptons.
The Higgs Theory is a fundamental theory in particle physics that explains how particles acquire mass. It proposes that there is a field, known as the Higgs field, that permeates the universe and gives particles their mass through interactions with the Higgs boson.
The Koide Formula, also known as the Koide Mass Relation, is a mathematical equation that predicts the masses of the three charged leptons (electron, muon, and tau). It is derived from the Higgs Theory and suggests that there is a fundamental relationship between the masses of these particles.
The Koide Formula predicts that the masses of the three charged leptons should be related to each other in a specific way, with the tau mass being approximately twice the muon mass and the electron mass being approximately one-third of the muon mass. This relationship has been confirmed by experimental data with a high level of accuracy.
The Higgs Theory and Koide Formula provide insights into the fundamental nature of particles and their interactions. They help us understand the origin of mass and the structure of the universe at the most basic level, and have implications for other areas of physics such as cosmology and string theory.
While the Higgs Theory and Koide Formula have been successful in predicting and explaining the masses of leptons, there are still some challenges and limitations. For example, they do not accurately predict the masses of other particles such as quarks, and there are discrepancies between predicted and observed values for some particles. Additionally, the Koide Formula is only applicable to charged leptons and does not account for the masses of neutrinos.