ShoXx said:
Until after about a billionth of a second after the Big Bang when ElectroWeak symmetry breaking (the Higgs mechanism) occurred particles had no mass, yet the start of The Big Bang was supposed to be a singularity. Singularities are points of infinite density, how could it be a singularity if no particles had mass?
Theory of Everything (TOE) symmetry breaking would have been the first symmetry breaking event between the strong nuclear force and quantum gravity, which would have resulted in the generation of a boson, however there is a theoretical disagreement on what kind of boson is generated, quantum gravity predicts a massless graviton and General Relativity predicts a massive Planck mass boson, both are considered to be in the hypothetical class of particles.
TOE scale Planck boson mass energy:
\Lambda_{TOE} = E_p = \sqrt{\frac{\hbar c^5}{G}} \approx 1.22 \cdot 10^{19} \; \text{GeV}
Grand Unification (GUT) symmetry breaking would have been the second symmetry breaking event between the strong nuclear force and the electroweak force, which would have resulted in the generation of an X boson:
GUT scale X boson mass energy:
\Lambda_{GUT} = E_X = \left(\frac{10^9 e \tau_p m_p^5 \alpha_s^2 (m_Z)}{\hbar} \right)^{\frac{1}{4}} = 4.320 \cdot 10^{16} \; \text{GeV}
X bosons definitely have a theoretical mass and are considered to be in the hypothetical class of particles.
Electroweak (EW) symmetry breaking would have been the third symmetry breaking event, in absentia of any Higgs mechanism, between the electromagnetic and weak nuclear force, which would have resulted in the generation of a W boson.
Electroweak scale W boson mass energy:
\Lambda_{EW} = E_W = 91.1876 \; \text{GeV}
The mass of a Higgs boson could occur anywhere between:
\Lambda_{EW} - \Lambda_{GUT}
Or:
91.1876 \; \text{GeV} - 4.320 \cdot 10^{16} \; \text{GeV}
Infinities are artifacts of mathematics and do not actually occur in nature. There is no such thing as an infinite anything. The magnitudes of physical quantities can be extremely large or small, but never infinite.
For example, according to Loop Quantum Gravity (LQG) for which Quantum Cosmology (QC) is a subset, all matter inside a black hole oscillates on the order of a Planck radius and does not collapse into an infinite point. The primary reason for this is because space-time itself becomes quantized.
According to Quantum Cosmology, the same is also true for a Universe collapsing into a singularity, the matter 'bounces' off the Planck singularity without ever actually achieving an infinite quantity.
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Reference:
Big Bang Expansion and the Fundamental Forces - Hyperphysics
Theory of everything - Wikipedia
Planck energy - Wikipedia
X and Y bosons - Wikipedia
Orion1 #68 - doublet-triplet problem
Grand Unified Theory - Wikipedia
Loop quantum gravity - Wikipedia