Postscript, dated 26-4-1996.

SYSTEMATIC SKETCHES of the relation between Galaxy types and the responsible Black Holes (1) with the

resulting White Holes (2) in between. (Not included.)

 

The axis direction (14) of the central Bar of Barred Spirals seems to rotate under influence of the amount of angular momentum (11) of the Galaxy. The positions given by (15: secundary white holes) are expected to originate mini-Galaxies due to the secondary interaction of the multiple Black Holes on each side of the Galaxy.

Most lower picture to the left: Radio Picture of the Quasar 3C273 (Single Black Hole propelled by a pushing tail searching for one or more partners, to become a system with two or more Black Holes (1) and one or more White Holes (2) in between see app.p. 41)

Short explanation for the Systematic Sketches (at page 26) or the relation between Galaxy types and the responsible Black Holes (1) with the resulting White Holes (2). To do this we need some more detail information given by Figure A. and B. (on this page)

Figure A and B are both representing a cross section over the symmetry axis (4) of a Black Hole system existing out of two Black Holes (1) and one White Hole (2), comparable with the cross section given for Lenticular Galaxies on page; 26.

Figure A, is an adjusted representation of Figure; C.(see page; 20), which explained the Higgs-virgin gravity forces originated by the peculiar Higgs-virgin quantum space represented by the curved Higgs-virgin flow lines (5) forming the Higgs-virgin flow pattern (see pages; 8 and 20). Six position dependant Higgs-virgin quantum curves (6) acting on mass carrying particles (7) are sketched, with the resulting forces (see arrows). (and 16 other resulting arrows, sketched without the Higgs-virgin quantum curves).

Note; at the central symmetry axis (4), the forces are opposite directed away from the middle position (2: a white hole). There is no resulting force on the White Hole (2) itself. As discussed on page; 9, there must be a Higgs-virgin repelling zone (8) around each Black Hole. If two Black Holes are forming a dumbbell system, this Higgs-virgin repelling effect has its influence on the space between the Black Holes, by forming two Density wave cones (9), in the middle represented by a common density wave circle (10).

If more than two Black Holes are acting together, the resulting density wave circles (10) are represented at page; 26. If the Galaxy mass has enough angular momentum (11) a gas ring (12) will form for Lenticular Galaxies. Spiral arms (13) will form for Spiral Galaxies due to interference .of the desity wave circles . No spiral arms are supposed to form in Elliptical Galaxies due to the lack of interference of the density wave circles and the 3dimensional complexity of the system.

Conclusion:

The differences between Spiral- Lenticular- and Elliptical galaxies is originated by the amount and topology of the formgiving Anchor black holes situated outside these systems

Figure B. is representing the Higgs-virgin gravity forces (arrows) described at figure A, in more detail and spread over the whole system.

Figure A:

Figure B.

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Postscript, dd 28-05-1996.

Description in more detail of the former figures, A and B represented at page 27. Figure A, is representing the Higgs-virgin gravity forces , based on Higgs-virgin quantum curves (6) for different locations around two Black Holes (1) and one white hole (2) in between (see also pages 6-10). The Higgs-virgin flow lines (5) are representing the trajectories of the Higgs-virgin particles with velocity (c) running into- and around the black holes (1). The Higgs-virgin quantum curves (6) are the cross sections of the local Higgs-virgin particle 3-dimensional impuls profile (see below fig. E: 7) which has to be taken into account to explain the peculiar behaviour of Mass carrying or M particles in relation to black holes.

This Higgs-virgin impuls profile is not on each moment active as a whole, but will be composed in sequence at random due to the Higgs-virgin vacuum properties (page: l). The Higgs-virgin impulses given each Planck-time on a M-particle will push the particle into an apparent Chaotic sequence up to a defined time: (in Quantum physics called the Quantum break time ), after which the particle will repeat its movement, and become organized . This is called axial- and spin rotation . (see appendix page 6). The rotation axis of axial and spin rotation can have a more or less fixed position in relation to the vacuum, called polarization . To understand the Higgs-virgin repelling zone (8), Density wave cones (9) and synchrotron radiation around two black holes (fig: A and B), one has to take these polarization's into account in relation with the local . Higgs-virgin impulse profile . (fig.E:7)

Additional figures: Figure: C. Page: 29, is representing a side view of a M- particle having a cone axis (11), a nose (12), two propeller arms on the backside (13), (see also page 4). Higgs-virgin-virgin particles are colliding with the M-particle by which they transform into photons, which leave the M-particle in certain directions (cones), which are related to the central axis (fig. C,11) of the M-particle .

There is a graviton radiation cone (14) a magnetic radiation cone (16), with the respective cone angles: ( 17 and 18) and an electric radiation cone (15).(appendix page 6)

Due to the cone/propeller form of each M- particle, the effective Higgs-virgin impulse forces on the M-particle, are dependant of the angle of Higgs-virgin collision with the particle cone axis (11). Higgs-virgin impulses on the nose (12) are less effective (minor energetic impulses) than the (major impulses) at the back side of the particle (13). (see: page 7: Lorentz polarization).

We suggest the following rules of Higgs-virgin particle interaction with M-particles: 1: The efficiency of photon production (all photons except for gravitons) is dependant of the grade of the M-particles polarization and the screening effect which can be originated by close by quarks. The producing roduction is dependant of the grade of mutual screening for Higgs-virgin particle impulses (in the atom nucleus the screening is originating a one- and two third radiation value compared to the free electron).

2: The efficiency of graviton production (the mass) is dependant of the grade of internal complexity of the M-particle, combined with the mutual screening of quarks in a nucleus (see page 5, masses of muon and tau).

3: The Higgs virgin collision with M-particles originates impulses of different energy, which is dependent of the angle of collision. This results in different kinds of photons:

A, minor impulses are originated if the Higgs-virgin particle collide on the nose side (12) of the M-particle, producing gravitons (14), B, major impulses are originated if the Higgs-virgin particle collide on the back side (13) of the M-particle, producing electric and magnetic particles.

 

4: Full axial polarization of M-particles (single rotation around the central axis Fig. C, 11) is producing synchrotron radiation which is originated by Higgs-virgin impuls profiles with a symmetrical butterfly form. This is the case on the central connection line (4) between two black holes (fig. E: 20,30,40,).

5: Spin polarization of M-particles (rotation around the axis perpendicular to axis (11) fig. C, is producing dipole radiation . This is originated by Higgs-virgin impuls profiles with complex butterfly symmetry (fig. E: 50,60).

Figure: D, In usual space, far from any mass influence, or black holes, a M-particle will be in constant interaction with the impulses of a so called globular Higgs-virgin-impuls profile (7). In the section (fig. D) this is represented by circular Higgs-virgin curve (6) with a fixed standard radius (see also pages: 6 and 7).

In Figure: E, Higgs-virgin-impuls profiles (7) based on the impuls curves(6) are represented for different locations around the two black holes (1). Black holes are assumed to eat and collect Higgs-virgin particles in their nulclei (Page 8). The length of the impuls vectors is decreasing and minimal at the . white hole location (20) exactly in the middle between the two black holes (1). The decreasing length of the impuls vectors is indicating that the amount of Higgs-virgin impulses per time unit is decreasing.

Due to the peculiar local impuls profiles (7), a M-particle can be polarized, as described before. For axial polarizations: the nose side (fig. C,12) will be average pointed in one direction with a specific amount of polarization, originating: magnetic radiation into the direction of the electric cone (fig.C,15). This phenomenon will originate the H-particle to accelerate in the direction of the cone (15).

Full Axial polarization is supposed to be the origin of all synchrotron jets and relativistic movement, observed in the Cosmos. All Higgs-virgin impuls profiles at the locations: (20,30,40) with a symmetric form over one rotation axis (symmetrical butterfly) will originate this Full axial polarization effect.

Spin polarization is supposed to be originating dipole (north and South) magnetic radiation. Spin polarization is supposed to be originated only inside the Higgs-virgin-repelling cones of interacting black holes.(fig. B,9)and is dependant of the angle of sight (52,62) between the two black hole directions (1) in which the two black holes are seen from the M-particles position. According to our study this angle (52,62) must range between 150 and slightly less than 180 degrees. (see also appendix page 6)

If this angle of sight (see page 29: 52,62) is less than about 150 degrees (for position 60A) the spin polarization will stop and originate a different acceleration direction of the M-particle (see arrow: 63A) which is pointing more into the direction of the nearest black hole. The M-particle is then supposed to be outside the Higgs-virgin-relusion cone

The location: 20, (called white hole) is positioned in the gravitational center at the middle of the axis in between the two black holes. The corresponding Higgs-virgin impuls profile (7) has circular symmetry over the axis (4) and has one symmetry plane (21) perpendicular to the axis (4). A M-particle on this location (20) can choose for two axial polarization directions, each directed to one of the black holes (1). Especially single M-particles (like electrons and positrons, contrary to nucleon bounded Quarks) will be able to become this axial polarization and will be highly accelerated from the middle position to one of the black holes due to the Higgs-virgin impuls differences described under: (5).

If the M-particle reaches position (30) the particle will slightly slow down due to the widening of the angle (31) and the narrowing of angle (32). Before the position of location (40) (at the light horizon 41) is reached the M-particle polarization will flip polarization direction over 180 degrees, due to the increased cone angle (42), and after a while change its velocity direction. (Globular Higgs-virgin repelling zone around a black hole page: 9).

If in special cases, location (40) is reached, the cone angle (42) of 180 degrees, makes it impossible to maintain the Higgs-virgin repelling forces on the M-particle, and the M-particle will disappear into the black hole.

The Higgs-virgin impuls profiles of (70,80,90) are also representative for combinations with only one black hole,(not only situated at one symmetry axis, but all around the black hole.) In the position of (70) no polarization of the M-particle will occur if the cone angle (72) has a not reached a (non-established) minimal value, consequently, M-particles will be pushed into the direction of the black hole (outside the Higgs-virgin repelling zone, page: 9).

If the cone angle (72) has reached a (not established) minimal value, the M-particle will become axial polarized, and tend to turn the nose away from the black hole. As a result the M-particles are supposed to become an acceleration (81) away from the black hole: called Higgs-virgin repelling . If the M-particle (90) should reach the Light horizon (91), The Higgs-virgin repelling effect has stopped, and the particle will disappear into the black hole. (see page 13, figure H) The phenomenon of Higgs-virgin repelling not only should be responsible for the different Galaxy types, but also for other Cosmological structuresm as there are:

A: Bigger structures than Standard Galaxies: galaxy clusters (see page: 16: Dumbbell structures in Galaxy clusters). B: Smaller structures than Standard Galaxies: all inter galactic (synchrotron)jets, Herbig and Haro (HH-)systems, L.B.V.'s ( Luminous Blue Variables : e.g. Eta Carina see figure: F.), Planetary Nebulae and even the formation of planetary systems around stars like our Sun!

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