Abstract
Dark energy, accelerating the expansion of the universe, is fourteen times larger than the ordinary mass-energy in the universe. So much energy can be found only in the scenario of the creation of the universe. Quantum condensation of the Higgs condensate (HC), after the Big-Bang, when the temperature fell through 10 15 Kelvin, liberates hundreds of GeV/boson. The Higgs potential energy well has the form: U(ρ) = −n(ϕ ϕ) + m(ϕ ϕ) 2 , where n > m, ϕ is a complex order parameter and ρ = ϕ ϕ is the condensate density. The depth of this potential well is generic and uniform throughout the universe. If ρ > n/m, the HC can lower its energy by freely expanding its volume, which is related with the accelereted expansion of the universe. Recent experimental observations, achieved with the help of the tightly synchronized clocks in orbit, show that the Higgs Quantum Space (HQS), ruling the inertial motion of matter and propagating light, is circulating round earth, round the sun and round the galactic center according to velocity fields, consistent with the local main astronomical motions, thereby appropriately creating the observed gravitational dynamics. In these Keplerian velocity fields, earth is very closely stationary with respect to the HQS, which explains the isotropy of light with respect to earth. It also explains the absence of the gravitational slowing of the GPS clocks, predicted by General Relativity, but not observed. This HQS-dynamics however cannot explain why the recession between the galaxies causes no light anisotropy. The isotropy of light proves that this recession too lets earth, the sun and the Milky-Way galaxy stationary with respect to the HQS. Obviously, this becomes possible only if the expansion of the universe is expansion of the HQS itself, showing that the expansion of the universe follows perfectly the expansion of the HQS itself.
Highlights
Recent astrophysical observations have confirmed that the Universe shows an accelerated cosmic expansion. [1, 2] Evidence of this expansion has been shown independently from measurements of supernovae of type Ia and from microwave background radiation [3,4]
It has been proposed that this cosmological behavior is caused by a hypothetical dark energy (w), a cosmic fluid parameterized by an equation of state w = p/ρ, where p is the spatial homogeneous pressure and ρ is the dark energy density [3,4,5]
Estimates by cosmologists came to the astonishing conclusion that the amount of dark energy, necessary to explain this observed accelerated expansion, is fourteen times larger than the total visible mass-energy in the universe
Summary
Recent astrophysical observations have confirmed that the Universe shows an accelerated cosmic expansion. [1, 2] Evidence of this expansion has been shown independently from measurements of supernovae of type Ia and from microwave background radiation [3,4]. The reason is that the vector potential, associated with the magnetic field, causes local phase displacements of the superconducting order parameter, introducing phase disorder and thereby increasing the energy of the system, locally destroying superconductivity and recovering the U (1|) gauge symmetry Superconductors can lower their energy by confining the magnetic field into quantized microscopic fluxons or developing a macroscopic screening velocity field of the SCC and a Lorentz force field, expelling out the magnetic field. Confinement of ordinary mass-energy and global volumetric expansion of the HQS are mechanisms by which the HC can dissipate and lower its energy This provides strong evidence that the condensation process of the HC still is in course
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
