Isotherms clustering in cosmic microwave background

The gravitational hydrodynamics of the primordial plasma with neutrino hot dark matter is considered as a challenge to the bottom-up cold dark matter paradigm. Viscosity and turbulence induce a top-down fragmentation scenario before and at decoupling. The first step is the creation of voids in the plasma, which expand to 37 Mpc on the average now. The remaining matter clumps turn into galaxy clusters. Turbulence produced at expanding void boundaries causes a linear morphology of 3 kpc fragmenting protogalaxies along vortex lines. At decoupling galaxies and proto-globular star clusters arise; the latter constitute the galactic dark matter halos and consist themselves of earth-mass H-He planets. Frozen planets are observed in microlensing and white-dwarf-heated ones in planetary nebulae. The approach explains the Tully-Fisher and Faber-Jackson relations, and cosmic microwave temperature fluctuations of micro-Kelvins.

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“…In ref. [20] it is deduced that the data for the first CMB peak involve R e ∼ 100, in striking agreement with our estimate ∼ 158.…”

supporting

confidence: 91%

Gravitational hydrodynamics of large-scale structure formation

2009

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“…Hydrogravitational dynamics HGD cosmology explains the big bang as a Planck scale turbulent combustion event terminated by anti-gravity gluon-viscousstresses that drive exponential inflation of mass-energy to length scales ~10 15 larger than our present horizon L H = ct. Fluid mechanical negative stresses (anti-gravity dark energies) of the big bang are frictional and temporary, suggesting a closed universe and a series of big-bang big-crunch events. Fossil turbulence CMB patterns of big bang turbulence and turbulence produced by structure formation in the plasma epoch agree precisely with those of terrestrial turbulence both measured and simulated [16][17][18] in Fig. 5.…”

Section: Discussionsupporting

confidence: 75%

“…Phys., Aug. 3, 8:30-9am, Astrophys.gravitationally expanding supervoids concentrating remnant big bang vorticity of the surrounding protosupercluster plasma. Bershadskii and Sreenivasan[16,17,18] compare statistical parameters of turbulence flows with those of CMB temperature anisotropies near the sonic peak where the signal to noise ratio is high. The correlation is very high, and suggests a small turbulence Taylor microscale Reynolds number Re λ of 40, much smaller than the Re λ of 100 predicted by big bang turbulence theory but significantly above transition values of 5-10.…”

mentioning

confidence: 99%

Turbulence and turbulent mixing in natural fluids

Gibson¹

2010

Phys. Scr.

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Turbulence and turbulent mixing in natural fluids begins with big bang turbulence powered by spinning combustible combinations of Planck particles and Planck antiparticles. Particle prograde accretions on a spinning pair releases 42% of the particle rest mass energy to produce more fuel for turbulent combustion. Negative viscous stresses and negative turbulence stresses work against gravity, extracting mass-energy and space-time from the vacuum. Turbulence mixes cooling temperatures until strongforce viscous stresses freeze out turbulent mixing patterns as the first fossil turbulence.Cosmic microwave background temperature anisotropies show big bang turbulence fossils along with fossils of weak plasma turbulence triggered as plasma photon-viscous forces permit gravitational fragmentation on supercluster to galaxy mass scales.Turbulent morphologies and viscous-turbulent lengths appear as linear gas-proto-galaxyclusters in the Hubble ultra-deep-field at z~7. Proto-galaxies fragment into Jeans-massclumps of primordial-gas-planets at decoupling: the dark matter of galaxies. Shortly after the plasma to gas transition, planet-mergers produce stars that explode on overfeeding to fertilize and distribute the first life.

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“…Turbulence motions of the big bang have produced unambiguous fossil turbulence fingerprints in the temperature anisotropy patterns observed by cosmic microwave background (CMB) space telescopes (Bershadskii & Sreenivasan 2002, 2003; Bershadskii 2006; Gibson 2010).…”

Section: Hydro-gravitational Dynamics Versus the Standard Cosmologicamentioning

confidence: 99%

The origin of life from primordial planets

Gibson

Schild

Wickramasinghe

2010

International Journal of Astrobiology

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Abstract:The origin of life and the origin of the universe are among the most important problems of science and they might be inextricably linked. Hydro-gravitational-dynamics (HGD) cosmology predicts hydrogen-helium gas planets in clumps as the dark matter of galaxies, with millions of planets per star. This unexpected prediction is supported by quasar microlensing of a galaxy and a flood of new data from space telescopes. Supernovae from stellar over-accretion of planets produce the chemicals (C, N, O, P etc.) and abundant liquid water domains required for first life and the means for wide scattering of life prototypes. The first life likely occurred promptly following the plasma to gas transition 300,000 years after the big bang while the planets were still warm, and interchanges of material between planets constituted essentially a cosmological primordial soup. Images from optical, radio, and infrared space telescopes suggest life on Earth was neither first nor inevitable.

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Isotherms clustering in cosmic microwave background

Cited by 13 publications

References 30 publications

Gravitational hydrodynamics of large-scale structure formation

Gravitational hydrodynamics of large-scale structure formation

Turbulence and turbulent mixing in natural fluids

The origin of life from primordial planets

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