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QUASARS OBSERVATIONAL FACT-MODERN INTERPRETATION

1. Quasars have rapid light variations - Most quasars light come from a small source of solar system dimensions, even in quasars as big as giant galaxies. (Explosions of stellar and planetary-sized objects are often to the Super Giant Ultra Dense Nucleus (SGUDN) of quasar).

2. Even high-redshift quasars have long jets - Such jets are largest contiguous structures in the universe which forms thick proto-nebulas of dwarf and giant galaxies.

3. Quasars have little or no visible angular extent – SGUDN of quasar has little or no visible angular extent. Only the center SGUDN of the galaxy-like mass which produces the energy is visible.

4. Features in quasar jets are observed to move outward – Of course, for formation new galaxies.

5. The angular size of visible nebulas surrounding some quasars does not diminish, and may even increase, with increasing redshift – Because, only Super Giant High-Redshift Quasars (SGHRQ) are seen, with increasing redshifts. SGHRQ are more energetic.

6. Some high-redshift quasars are relatively bright - Because, they are SGHRQ. Huge nuclear energy mechanism around SGUDN produces equivalent of thousands of supernovas per year, enabling them to be bright at great distances.

7. Quasars do not exhibit the type of brightness-number relationship found for galaxies. The distribution is flat out to nearly redshift z = 2, then drops sharply – because quasars are not galaxies. Quasars are of any sizes from micro-quasars to galaxy-sized star-like bodies.

8. Small redshift and large-redshift quasars are found infrequently – because largest-redshift quasars we could not see still. Small-redshift quasars existence imposible, they can rapidly eat all surrounded galaxies and each other too.

9. Discrete X-ray sources are found in our own galaxy and in some quasars and related objects - X-ray sources are proof strongest interaction into ultra dense volume between huge amounts of particles. Huge source is proof of huge nuclear reactions around SGUDN inside galaxy-sized nuclear clouds.

10. An X-ray flare from a quasar with z = 0.14 was observed to increase its brightness by 67% in just three minutes - These X-rays must be relativistically directed toward us in a narrow, short-lived beam by hit and eaten star in thee minutes.

11. The calculated charged particle density is a function of inferred distance - The calculated charged particle density is a function of inferred distance and explosive force of a star or planet to the SGUDN of quasar.

12. Some low redshift galaxies have associated quasars. Some of those appear to be connected to the galaxies - because redshift is only exact evidence (denotation, length calibration) and function of inferred distance.

13. Quasars, even at high redshifts, are frequently accompanied by faint galaxies at small separations – Because quasars are forming galaxies.

14. The magnitudes and angular separations of quasar-galaxy pairs are correlated with the galaxy redshift - This is the parent-quasar galaxy relationship.

15. Where distant clusters of galaxies are observed, quasars are generally not found in them – in this distant voids merging galaxies are not still. If not so all a quasar could eat some of them and quasar would be seen there.

16. Quasars with redshifts greater than 1.5 show no tendency toward galaxy-like clustering or voids – Smaller than 1.5 quasars are nearby, and should therefore display clustering. Redshift is the distance indicator and we can see galaxy-like clustering (RECYCLING AND RENEWING PROCESSES OF GALAXIES) or voids.

17. Quasars do show strong, large-scale clustering around nearby galaxy groups, such as the Virgo and Sculptor clusters and M87 – because higher-redshift galaxies we could not see to the higher-red shift quasars.

18. Absorption lines in the spectra of quasar light are quite narrow – Huge radiations of exploded stellar and planetary chemical elements from SGUDN of quasar are absorbing by same chemical elements of huge a galaxy-sized nuclear and molecular clouds surrounded the quasar (SGUDN).

19. The number of absorption line systems seen in Lyman alpha does not monotonically increase with redshift. Low-z quasars such as 3C 273 (z = 0.16) have as many absorption systems as high-z quasars – Because each quasar has own absorption system, galaxy-sized nuclear clouds created by huge nuclear reactions around SGUDN feeding stellar and planetary systems.

20. Quasar jets have variable polarization due to a magnetic field – Quasars’ jets consistence is thick separated nebulas (huge nuclear and molecular clouds) of proto galaxies and are heavy-ionized. Interaction between particles creates variable polarization due to a magnetic field. Each cloud will creates parent star of galaxy or globular cluster later with variable polarization due to a magnetic field.

21. So-called "iron quasars" contain extremely strong emission lines from ionized iron – Iron as well as other metals is proof about huge planetary meal by quasar now. Huge radiations of exploded planetary chemical elements from SGUDN of quasar are absorbing by same chemical elements of huge a galaxy-sized nuclear and molecular clouds surrounded the SGUDN.

Posted

This is a science discussion forum. We bristle at bullet-point "lectures" from members with unknown training and education. We know where to go to get this kind of data. Is there something you'd like to discuss about quasars?

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