Origin of Cocoon Nebula.

Cocoon Nebula at end of filaments. Image credits: ESA/Herschel/SPIRE/PACS/D. Arzoumanian (CEA Saclay)

Star studded filaments join to Cocoon Nebula as a connection in evolution. This maybe part of matter transit through these filaments as conduits (though no known process can achieve this) is proved by the formation of stars along their length as a connection to massive matter transfer. The very centre of the Cocoon Nebula sits on top of a column of filaments as the termination point and suggests an entity or end point resides there. From that centre (probably something like a White Dwarf) matter expands almost symmetrically to form the Nebula as a growth system of that transfer. There is no question that a connection exists between those double filaments and the Nebula with associations, via unknown evolutionary processes, to accumulations of matter as new stars.
Other filaments and connection to 'ribbons' of stars may have termination points as types of nebula, and there is evidence of this, that poses the questions: How can matter pass inside filaments and what process of transfer? Where a whole other explanation may exist for their formation.

Eta Carinae. Symmetrical expansion of matter that forms nebula with two tube like structures, connected to central object, as termination point for transfer through double filaments.

Star forming and Filaments.

Star forming filament. Image credit: ESA/Herschel/SPIRE/M. Juvela (U. Helsinki, Finland).

Herschel's hunt for filaments in the Milky Way
One of the key aspects that emerged from these observations is the presence of a filamentary network nearly everywhere in our Galaxy's interstellar medium. The picture that is emerging is that these structures are closely linked to the formation of stars.
Prior to Herschel, astronomers had already identified several filaments in interstellar clouds and recognised their potential importance for star formation. However, only with the increased sensitivity and spatial resolution granted by this observatory, combined with its large-scale surveys, could they reveal the full extent of filamentary patterns in the Milky Way.

Filaments connect to star forming as a transfer system of matter. Which begs the question: What creates these filament structures and how is matter transferred?

Black Hole and gravitational connected partner theorized as White Hole.

Through space time via accretion. In accretion a large amount of matter vanishes before reaching the Black Hole and this passes through space time. Escaping and even repelled by gravity as negative antimatter.


IC5146. Filaments connect to nebula (top) and star forming in matter transfer.

IC5146. Nebular at end of filaments, to centre, produces symmetrical growth around White Hole.

Fractal morphology.

Fractal association in basic structure from separate evolution.

Odd correlation between structures of different morphology:
   All symmetrical and often perfectly circular in shape.
   Powerful, energetic process in the centre.
   A central object (not in clusters)
   That central entity, when found, is often semi-compact.
   All have powerful 'outflow' from or around the centre.
   Hard to calculate rotation of the often enigmatic central object (some super fast, some v. slow).
   Bright, active zone may form around central object in bigger structures that may connect to star forming.
   Grading from the centre to the extremities as a steady decline in matter densities.
   The further from centre, the slower the movement of matter.

If the same entity is found in the centre of clusters and the fast rotation of the super massive objects in the centre of galaxies was in doubt (that is calculated from the speed of gasses and not directly from rotation) then these structures would have a striking correlation in evolution and driven by the same fundamental process just very different in scale.
We get used to viewing these structures without seeing how bizarre they are to produce with the current evolution process.