Self gravitational fluid mechanical methods termed hydro-gravitational-dynamics (HGD) predict plasma fragmentation 0.03 Myr after the turbulent big bang to form protosuperclustervoids, turbulent protosuperclusters, and protogalaxies at the 0.3 Myr transition from plasma to gas. Linear protogalaxyclusters fragment at 0.003 Mpc viscous-inertial scales along turbulent vortex lines or in spirals, as observed. The plasma protogalaxies fragment on transition into white-hot planet-mass gas clouds (PFPs) in million-solar-mass clumps (PGCs) that become globular-star-clusters (GCs) from tidal forces or dark matter (PGCs) by freezing and diffusion into 0.3 Mpc halos with 97% of the galaxy mass. The weakly collisional non-baryonic dark matter diffuses to > Mpc scales and fragments to form galaxy cluster halos. Stars and larger planets form by binary mergers of the trillion PFPs per PGC, mostly on 0.03 Mpc galaxy accretion disks. Stars deaths depend on rates of planet accretion and internal star mixing. Moderate accretion rates pro-duce white dwarfs that evaporate surrounding gas planets by spin-radiation to form planetary nebulae before Supernova Ia events, dimming some events to give systematic distance errors, the dark energy hypothesis, and overestimates of the universe age.
Gibson, C. H., & Schild, R. E. (2012). Hydro-Gravitational Dynamics of Planets and Dark Energy. Journal of Applied Fluid Mechanics, 2(2), 35-41. doi: 10.36884/jafm.2.02.11867
MLA
C. H. Gibson; R. E. Schild. "Hydro-Gravitational Dynamics of Planets and Dark Energy", Journal of Applied Fluid Mechanics, 2, 2, 2012, 35-41. doi: 10.36884/jafm.2.02.11867
HARVARD
Gibson, C. H., Schild, R. E. (2012). 'Hydro-Gravitational Dynamics of Planets and Dark Energy', Journal of Applied Fluid Mechanics, 2(2), pp. 35-41. doi: 10.36884/jafm.2.02.11867
VANCOUVER
Gibson, C. H., Schild, R. E. Hydro-Gravitational Dynamics of Planets and Dark Energy. Journal of Applied Fluid Mechanics, 2012; 2(2): 35-41. doi: 10.36884/jafm.2.02.11867