A zoom in photo of Sparky (shown below) shows rapid star formation around the precursory galaxy core happens inside streaming spiral shaped filaments produced by supernovas in at least three layers of vortice rings.
|Sparky zoom in photo by The Spacereporter.com|
Sparky is the first discovery to have both a stellar structure and the gas dynamics of a galaxy core. It is a scaled down model of a tiny galaxy without a black hole, being composed of ~400 billion solar masses. It is also a scaled up model of a supernova remnant where stars form inside evaporating gaseous globules, that collectively align together around near the galaxy core where most new massive stars form at very fast rates.
Before the discovery of Sparky, the largest known similar type stellar objects were Herbig-Haro objects, composed of two counterflow jets of streaming stars into a primordial core forming center, lasting just a few thousand years. Sparky is a far larger stellar like structure than Herbig-Haro objects.
Sparky has an extremely low alpha lyman hydrogen redshift of only z=2.3 for what they describe as an early universe galaxy 11 billion light years away. The scientists believe there are hundreds to thousands more of similiar type "Sparky's" obscured by gas and dust that they haven't yet detected.
Redshifts are used to interpret cosmic distances, but only measure the single brightest emission of hydrogen atoms called alpha lyman hydrogen. In no way does this method produce accurate distance measurements, to be used exclusively to support the big-bang cosmology. Halton Arp is the real authority on these discordant redshift interpretations.