CORE PHYSICS

a taxonomy






PREAMBLE

TAXONOMIC TABLE

GLOSSARY


Index

Taxa:
FUNDAMIDES

Taxon:
Teels

Taxon:
Teelons

Taxon
Teeloids


Taxa
PHOTIDES

Taxon:
Photons

Taxon:
Quarks


Taxa:
MORPHIDES

Taxon:
Electroids

Taxon:
Nucleons


Taxa:
NUCLIDES

Taxon:
Primalnuclides

Taxon:
Lithicnuclides

Taxon:
Ferricnuclides


Taxa:
STELLIDES

Taxon:
Protostars

Taxon:
Dwarfstars

Taxon:
Whitestars

Taxon:
Blackstars


Taxa:
GALACTIDES

Taxon:
Elliptogalaxies

Taxon:
Ellectrogalaxies

Taxon:
Nucleogalaxies


* * * * *

PREVIOUS ITERATIONS

The Blue Book (1996)

Principia Cosmologica
(2008)

Template
(2014)



 









































   





























































































































































































































































































































































Taxon
ELECTROGALAXIES


TAXA     Galactides     Objects with blackstars in their nuclei.

TAXON     Elliptogalaxies     Galactides with a one blackstar, standard, nucleus.
TAXON     Electrogalaxies     Galactides with a two blackstar, electroidal, nucleus.
TAXON     Nucleogalaxies     Galactides with a three blackstar, nucleonic, nucleus.

Revised:     4th May 2022




CONTENTS

NARRATIVE

The galaxy factbase is small. The enormous distances involved mean that empirical confirmations are almost wholly observational. The galaxy knowledgebase is more substantial, being underpinned by an impressive array of mathematical conjectures. These may soon be confirmed by observation but experimental confirmation will always be difficult.

DESCRIPTION


PARAMETER
  • This description is of a representative midlife twocoregalaxy.

TWOCOREGALAXY     A galaxy with a galaxycore that is two strongforced teelcores.

TWOCOREGALAXY STRUCTURE     A nucleus, inside a teelosphere, inside a gravitysheath.
  • Nucleus      A galaxycore, inside a blackhole, inside an aurasphere.
    • Galaxycore
      • A twocoregalaxy galaxycore consists of two teelcores.
        • A teelcore is a sphere/spheroid of solidbonded pairs of adjacent teels.
        • A teelcore is surrounded by a teelocean of liquidbonded pairs of adjacent teels.
      • A teelcore has mass and thus:
        • An extrinsic gravitypull.
        • A gravitysheath and a gravitysheath interface.
      • A galaxycore's teelcores are strongforced together.
        • They are held together by their mutual gravitypull.
        • They are held apart by the mutual repellence of their teeloceans.
      • A galaxycore is in its configuration of least stress.
        • One teelcore teelocean is axially structured.
        • One teelcore teelocean is centrifugally structure.
        • The equator of the centrifugal teelocean abuts the southpole of the axial teelocean.
      • A galaxycore is spinning and thus has a northpole, equator, and southpole.
        • The northpole of the axial teelocean is the northpole of the galaxycore.
        • The point on the equator of the centrifugal teelocean that is most distant from the galaxycore nothpole is the galaxycore southpole.
        • The galaxycore spin is polar.
      • A galaxycore absorbs teels from the aurasphere.
        • The teelcores absorb teels from the aurasphere.
      • A galaxycore's energy and mass is differentially increased by additional teels.
        • The teelcores are engorged by the differential increase in energy and mass.
        • Due to engorgement, the energyvelocity of the teelcores exceeds their massvelocity.
        • Due to its teelcore's energyvelocity exceeding their massvelocity, the galaxycore is understable.
        • Due to its understability, the galaxycore stabilises per the energy/mass differential mechanism.
      • A galaxycore stabilises by ejecting teels into the aurasphere.
        • The centrifugal teelcore ejects teels equatorially.
          • The northern segment of its equator ejects teels into the southpole downwell of the axial teelocean.
          • Most of the rest of the equatorial ejection is at or near the southernmost segment of the equator and is out into the aurasphere as a jet.
        • The axial teelcore ejects teels from its northphole into the aurausphere as a jet.
      • A galaxycore ejects teels until its teelcores achieve engorgement stasis.
        • With its teels at engorgement stasis, the galaxycore is stable.
      • When a galaxycore is stable:
        • Both teelcores are understable.
        • Both teelcores are engorged.
        • The mass of the axial teelcore is slightly less than that of the centrifugal teelcore.
        • The mass of the teelcores in a stable twocoregalaxy galaxycore is the same in all stable twocoregalaxy galaxycores.
        • The mass of a stable twocoregalaxy galaxycore is the same in all stable twocoregalaxy galaxycore.
      • A galaxycore northpole jet, depending on its massdensity and velocity, can punch through the aurasphere, bulge, halosphere, and across the gravitysheath interface.
        • The degree of the jet's massdensity and velocity increases with increases in the understability of the galaxycore.
        • The massdensity and velocity of the northpole jet is always greater than that of the southpole jet.
      • A galaxycore southpole jet, depending on its massdensity and velocity, can punch through the aurasphere, bulge, halosphere, and across the gravitysheath interface.
        • The degree of the jet's massdensity and velocity increases with increases in the understability of the galaxycore.
        • The massdensity and velocity of the southpole jet is always less than that of the northpole jet.
      • A midlife twocoregalaxy galaxycore is always understable to a greater or lesser degree.
    • Blackhole
      • A blackhole is a region inside which the escapevelocity is higher than lightspeed.
      • A twocoregalaxy blackhole is a consequence of the extrinsic gravitypull of the gravitycore.
      • A twocoregalaxy blackhole is outside the surface of the gravitycore and inside the surface of the aurasphere.
        • A blackhole's surface is its eventhorizon.
        • Photons and superphotonics cannot escape from a blackhole.
          • There are no photons or superphotonics inside a blackhole.
        • Subphotonics can escape from a blackhole if they exceed lightspheed.
          • There are subphotonics inside a blackhole.
      • A blackhole's volume increases with any increases in the massvolume of the galaxycore.
        • The massvolume of a twocoregalaxy galaxycore is always the same if it is stable.
        • The volume of the blackhole surrounding a stable twocoregalaxy galaxycore is always the same.
    • Aurasphere
      • An aurasphere is a stratum of liquidbonded teels surrounding the galaxycore.
      • A twocoregalaxy aurasphere is a consequence of the extrinsic gravitypull of the galaxycore.
      • An aurasphere is a liquidbonded teelstream system.
        • The teelstream system responds to the spin of the galaxycore.
        • The teelstream system of a twocoregalaxy's aurasphere is axial overall.
      • An aurasphere absorbs teels from the galaxycore.
        • The polar jets pass through the aurasphere, influencing the axiality of the aurasphere teelstream system.
      • An aurasphere absorbs objects from the bulge.
        • Subphotonics and photons emitted by bulge stars.
        • Subphotonics gravitypulled from the bulge.
        • Stripped neutrons, deuteriums, and heliums gravitypulled from the bulge.
      • An aurasphere dissipates the objects absorbed from the bulge into teels.
        • The absorptions differentially increase the energyvelocity and the massvelocity of the aurasphere.
      • An aurasphere is understabilised by a differential increase in energyvelocity and massvelocity.
        • Stabilisation is per the energy/mass differential mechanism.
          • Aurasphere stabilisation ejects teels into the galaxycore.
          • Aurasphere stabilisation ejects teels into the bulge.
          • Aurasphere stabilisation ejects teels by reinforcing the north polar jet.
  • Teelosphere
    • A twocoregalaxy teelosphere is the outermost part of the galaxy.
    • A twocoregalaxy teelosphere surrounds the nucleus.
      • The surface of the teelosphere is also the surface of the galaxy.
    • A teelosphere is a gasbonded teelstream system.
      • The teelstream system responds to the movement of the aurasphere.
      • The teelstream system is axial overall.
    • A teelosphere is darkmatter.
      • Darkmatter is primarily teels
      • Darkmatter is secondarily other subphotonics.
    • A twocoregalaxy teelosphere has an inner region and an outer region.
      • The regions are defined by their content.
      • The inner region is the bulge.
        • The significant bulge content is overengorged stars.
      • The outer region is the halosphere.
        • The significant halosphere content is gasbonded stars.
    • A teelstream system's heft affects the objects in it.
    • A teelstream has measures of energyvelocity and massvelocity and is thus overstable, stable, or understable.
      • Overstable:
        • The surface of the teelosphere is entirely inside the gravitysheath interface.
      • Stable:
        • The surface of the teelosphere and the gravitysheath interface coincide.
      • Understable:
        • The surface of the teelosphere extends partially or wholly across the gravitysheath interface.
    • An understable teelosphere is ejecting teels across the gravitysheath interface.
    • Bulge
      • A twocoregalaxy's bulge is the inner region of its teelosphere.
      • A bulge's significant content is overengorged stars.
          • Bulge stars are overengorged by the teelosphere teelstream system.
          • Bulge stars are overengorged by emission pressure.
        • Overengorgement inhibits fusion in the stars.
        • Overengorged stars break their isotopes to heliums, deuteriums, and neutrons.
        • Overengorged stars become metalpoor as their isotopes are broken.
        • Overengorged stars are dissipated over time.
      • A bulge's stars are in three stratums.
        • Inner stratum:
          • Stars are strongforced together.
          • Stars are subforced to the surface of the aurasphere.
        • Intermediate stratum:
          • Stars are strongforced together.
          • Stars are not subforced.
        • Outer stratum:
          • Stars are not strongforced.
          • Stars are not subforced.
      • A bulge's packing density decreases from the aurasphere surface outward.
        • Star numbers increase with star absorptions from the halosphere.
        • Star numbers decrease with star dissipations.
      • A bulge absorbs teels from the aurasphere.
        • Directly through the interface between them.
          • Absorption from the aurasphere is only significant when the aurasphere is strongly understable.
        • As byflow from the polar jets.
          • Absorption from the polar jets is only significant when the galaxycore is weakly understable and the heft of the jets is correspondingly weak.
      • A bulge absorbs objects from the halosphere.
        • Teels in the teelstream system passing through.
        • Gravitypulled subphotonics.
        • Photons emitted by halosphere stars.
        • Gravitypulled superphotonics.
        • Gravitypulled stars.
      • A bulge's energyvelocity and massvelocity is differentially increased by absorptions.
        • The energyvelocity and massvelocity of the teelstream system is increased.
        • The stars are further overengorged.
          • The higher the overengorgement, the quicker their dissipation.
      • A bulge's increase in energyvelocity and massvelocity may, or may not, make the bulge understable.
      • An understable bulge stabilises per the energy/mass differential mechanism and is by:
        • Photon emission into the aurasphere.
        • Photon emission into the halosphere.
        • Absorption of objects by the aurasphere.
        • Absorption of objects by the polar jets.
        • Ejection of subphotonics and superphotonics into the halosphere.
        • Removal of objects by the teelstream system.
      • A halosphere is the outer part of a galaxy teelosphere.
      • A teelosphere is a gasbonded teelstream system.
        • The teelstream system responds to the movement of the aurasphere.
        • The teelstream system responds to the movement of the polar jets.
        • The teelstream system is axial overal.
      • A halosphere is a region of gasbonded objects.
        • The gasbonded objects can be subphotonics, superphotonics, stars, star clusters and globular clusters.
      • A halosphere's mass and energy is reinforced by absorptions from the bulge and from the outer gravitysheath.
        • Subphotonics, photons, and superphotonics are absorbed from the bulge.
        • Teels are absorbed from the polar jets.
        • Subphotonics, photons, superphotonics , stars, star clusters, and lesser galaxies are absorbed from the outer gravitysheath.
      • A twocoregalaxy's halosphere stars are mostly in a polar disc.
        • The polar disc is reinforced by teels from the polar jets.
        • Arms of stars form in the polar disc.
        • Stars in the arms are understabilised by accretion from the disc.
        • Understabilised stars procede to fusion and fission depending on their peakmass.
      • A halosphere may contain star clusters and globular clusters.
        • Clusters can form from stars in the halosphere.
        • Halosphere formed cluster's ability to have a halosphere of their own is limited by dominance adjacency.
        • Clusters can be accreted from the outer gravitysheath.
        • Clusters accreted from the outer gravitysheath have their halosphere stripped from them by dominance adjacency.
        • Accreted globular clusters were previously lesser galaxies.
      • A midlife twocoregalaxy's halosphere is understable.
      • A halosphere's stabilisation is per the energy/mass differential mechanism and is by:
        • Photon emission into the bulge.
        • Photon emission into the outer gravitysheath.
        • Subphotonic, superphotonic, and star absorption into the bulge.
        • Subphotonic and superphotonic ejection into the outer gravitysheath.
        • Polar ejection of subphotonics and superphotonics into the outer gravitysheath.
    • A gravitysheath is a region inside which a galaxy's gravitypull is stronger than that of any other object.
    • A gravitysheath extends from the galaxy's masscentre to its gravitysheath interface.
      • The gravitysheath interface and teelosphere surface can coincide.
      • The gravitysheath interface and the teelosphere surface rarely coincide.
    • A gravitysheath has two regions:
      • The inner gravitysheath extends from the masscentre to the surface of the teelosphere.
      • The outer gravitysheath extends from the surface ofthe teelosphere to the gravitysheath interface.
    • The inner gravitysheath:
      • The galaxycore, aurasphere, bulge, and halosphere.
    • The outer gravitysheath:
      • May be empty.
      • May contain objects:
        • Subphotonics, superphotonics, stars, star clusters, and lesser galaxies.
        • The objects can be in open orbit or closed orbit.
        • The closed orbit objects may be absorbed into the inner gravitysheath over time.
    • A galaxy's stability is determined by the location of the gravitysheath interface relative to the location of the teelosphere surface.
      • Overstable:
        • The surface of the teelosphere is wholly inside the gravitysheath interface.
      • Stable:
        • The surface of the teelospher and the gravitysheath interface coincide.
      • Understable:
        • The surface of the teelosphere partly or wholly extends across the gravitysheath interface.
    • An understable galaxy stabilises per the energy/mass differential mechanism.
      • It ejects more energyvelocity than massvelocity over the gravitysheath interface.
      • An understable galaxy is not the same as an understable nucleus.
        • An understable nucleus ejects more energyvelocity than massvelocity in its polar jets.
TWOCOREGALAXY LIFECYCLE
  • A twocoregalaxy forms when a more massive onecoregalaxy successfully accretes a less massive onecoregalaxy.
  • A successful accretion is when the two teelcores are strongforced thus:
    • The teelcores are held together by their mutual gravitypull.
    • The teelcores are held apart by the repellence of their teeloceans.
  • As first joined:
    • Both teelcores are inside their own teeloceans.
    • Both teeloceans have centrifugal teelstream systems.
    • Both teelstream systems are engorged.
    • Both teelstream systems are chaotic.
      • The two teelcores are not in engorgement stasis.
      • The two teelcores are not in their configuration of least stress.
      • The two teelcores tumble about each other.
    • The aurasphere responds to the movement of its galaxycore and is a chaotic teelstream system.
  • As first joined:
    • The nucleus is understable.
      • Both teelcores are understable.
      • The galaxycore is understable.
      • The aurasphere is understable.
    • Stabilisation is per the energy/mass differential mechanism.
  • The nucleus automatically stabilises.
    • The galaxycore ejects teels chaotically into the aurasphere.
    • The aurasphere ejects teels chaotically into the teelosphere.
    • The ejections remove more energyvelocity than massvelocity.
    • The teelstream systems becomes less chaotic.
    • The teelocean teelstream system of the less massive teelcore becomes axial.
    • The teelocean teelstream system of the more massive teelcore becomes centrifugal.
    • A pole of the axial teelcore abuts the equator of the centrifugal teelcore.
    • The two teeloceans merge to become an axial teelstream system.
    • The axial teelstream ejects excess teels at its poles.
    • The axial teelstream continues to eject teels until engorgement stasis.
    • In engorgement stasis:
      • The two teelcores are understable and engorged.
      • The two teeloceans are understable and engorged.
      • The axial teelstream system is stable and not engorged.
    • The two teelcores are now an axial galaxycore.
    • The aurasphere responds to the movement of the galaxycore and becomes an axial teelstream system.
    • The nucleus is stable subject to stabilisation lag.
    • The nucleus is not engorged.
    • The nucleus is axial.
    • The spin of the nucleus is axial.
* * * * *
  • A midlife twocoregalaxy nucleus is surrounded by a teelosphere.
  • The nucleus has a substantial extrinsic gravitypull.
  • The nucleus gravitypulls objects from the teelosphere.
  • The gravitypulled objects differentially increase the energyvelocity and massvelocity of the nucleus.
  • The nucleus differentially ejects matching measures of energyvelocity and massvelocity and thus remains stable subject to stabilisation lag.
* * * * *
  • The inner teelosphere is the bulge star region.
  • During the twocoregalaxy formation, the two onecoregalaxy bulge stars coalesce around the nucleus.
  • The surface of the new bulge is the distance from the galaxy masscentre inside which all stars will be overengorged.
  • The voume of the bulge is commensurate to:
    • The extrinsic gravitypull of the nucleus.
    • The energy and mass of the teelosphere teelstreams.
  • Not all the original bulge stars are inside the new bulge surface.
    • As the newly formed nucleus sheds mass, the volume of the bulge decreases.
    • Those outside the surface are expelled into the halosphere.
  • Bulge stars are overengorged by the teelosphere teelstreams.
    • Teelosphere teelstreams in the bulge are dense and fast.
  • Bulge star overengorgement is reinforced by emission pressure
    • Overengorged stars prodigiously emit photons and subphotonics.
  • The combined extrinsic gravitypull of the nucleus and the bulge is significant.
  • Stars are gravitypulled from the halosphere into the bulge.
  • Stars gravitypulled from the halosphere are:
    • overengorged.
    • made metalpoor
    • dissipated.
  • The dissipated star matter is gravitypulled into the nucleus.
  • This cycle continues until objects can no longer be drawn from the halosphere.
    • When nothing is drawn from the halosphere the bulge stars continue to dissipate and be gravitypulled into the aurasphere until there is nothing more to be gravitypulled.
* * * * *
  • The outer teelosphere is the halosphere.
    • All types of object can be in the halosphere: subphotonics, photons, superphotonics, stars, star clusters, and globular clusters.
  • During the forming of the twocoregalaxy the halospheres of the two onecoregalaxies coalesce around the bulge.
    • All types of object can be inherited from the onecoregalaxy halosphere:  subphotonics, photons, superphotonics, stars, star clusters, and globular clusters.
  • Objects are held in the halosphere by:
    • The extrinsic gravitypull of the neucleus.
    • The intrinsic gravitypull of the galaxy.
  • New stars and new star clusters form in the halosphere.
  • The polar jets emitted from the nucleus enter the halosphere at the north and south poles.
    • The jets are the ends of the galaxy bars.
  • The polar jets dissipate into the spiral arms of the galaxy.
    • The spiral arms respond to the polar orbit of the galaxy.
      • The arms are initially fast moving.
      • The arms decelerate as they move away from the bulge.
      • The deceleration falls the arms behind the rotation of the nucleus.
    • The spiral arms respond to the gravitypull of the teelosphere.
      • The arms accelerate as they move away from the bulge.
      • The acceleration may or may not counter the deceleration.
      • The spiral arms may or may not counter the falling behind the rotation of the nucleus.
    • The spiral arms are dense.
      • The arms are a nursery for star and star cluster formation.
      • The volume of star and star cluster formation falls as the arms move outward.
      • The material available for star and star cluster formation is increasingly used up as the arms move outward.
* * * * *
  • All halosphere objects orbit the galaxy masscentre.
    • The orbits may be open or closed.
    • Most orbits are closed.
  • Stars beyond their peakmass differentially lose energy and mass as they stabilise.
    • As stars lose energy and mass, they are increasingly less abe to maintain their orbit.
    • The less they are able to maintain their orbit, the more they are gravitypulled toward the bulge.
    • Collisions and near-collisions also propel stars toward the bulge.
    • Over time, most stars are absorbed by the bulge.
  • Because the galaxycore is in engorgement stasis the nucleus is stable subject to stabilisation lag.
    • The nucleus ejects excess energyvelocity and massvelocity in its polar jets.
    • The polar jets "feed" the star nurseries in the arms.
    • The stars stabilise and fall back into the galaxycore.
    • The closed cycle continues until an event stops it.
* * * * *
  • The nucleus of a midlife twocoregalaxy nucleus is stable, subject to stabilisation lag.
  • The teelosphere of a midlife twocoregalaxy nucleus can be overstable, stable, or understable.
  • The stability of the teelsphere depends on its energyvelocity relative to its massvelocity.
    • Overstable:     the energyvelocity is less than the massvelocity.
    • Stable:     the energyvelocity is the same as the massvelocity.
    • Understable:     The energyvelocity is more than the massvelocity.
  • The physical consequences are:
    • Overstable:     The surface of the teelosphere is inside the gravitysheath interface.
      • The region between the teelosphere surface and the gravitysheath interface is the outer gravitysheath.
    • Stable:     The surface of the teelosphere, overall, coincides with the gravitysheath interface.
      • There is no outer gravitysheath.
    • Understable:     The surface of the teelosphere extends beyond the gravitysheath interface.
      • And/or if the polar jets extend beyond the gravitysheath interface.
      • There is no outer gravitysheath.
  • Objects of all kinds are absorbed from beyond the gravitysheath interface.
    • Subphotonics, photons, superphotonics, stars, and star clusters.
    • Star clusters are stripped of their halospheres (if any) by dominance adjacency.
  • Also, lesser galaxies can be absorbed from outer gravitysheaths on either side of the gravitysheath interface.
    • Lesser galaxies are stripped of their halospheres by dominance adjacency and become globular clusters.
  • Absorbed objects add differential measures of energyvelocity and massvelocity to the twocoregalaxy.
    • If the twocoregalaxy is stable or understable it ejects the same differential measures of energyvelocity and massvelocity.
    • If the twocoregalaxy is overstable it retains the added energyvelocity and massvelocity.
  • An overstable twocoregalaxy absorbs any available objects from its outer gravitysheath and from across its gravitysheath interface until it becomes stable.
  • A stable and isolated twocoregalaxy is eternal.
  • A stable and isolated twocoregalaxy is unlikely to be isolated eternally.
* * * * *
  • The fate of a twocoregalaxy is:
    • To be absorbed into a larger galaxy.
      • To be overengorged, broken, and absorbed into the nucleus as teels and become part of the larger galaxy's closed cycle.
    • To strongforce with a onecoregalaxy
      • To form a threecoregalaxy.
    • To strongforce with a twocoregalaxy.
      • To form a fourcoregalaxy.
      • Core Physics doesn't currently extend beyond threecoregalaxies. However, fourcoregalaxies are likely to exist, and may well be more common than threecoregalaxies.
    • To stabilise.
      • That twocoregalaxies can stabilise is possible but, with the universe as it currently is, may not happen often. It is probable that one of the other options will happen before stabilisation can. That said, a stable twocoregalaxy is less likely to be absorbed and more likely to be strongforced.


CAVEAT 2
  • Current Paradigm
    • Blackhole:   "A gravitationally domineering celestial body with an event horizon from which even light cannot escape; the most dense material in the universe, condensed into a singularity" (Wiktionary 22.07.2021).
    • Singularity:   "A point or region in spacetime in which gravitational forces cause matter to have an infinite density, associated with black holes" (Wiktionary 22.07.2021).
CAVEAT 3
  • Current Paradigm:
    • "Population II, or metal-poor, stars are those with relatively little of the elements heavier than helium. These objects were formed during an earlier time of the universe." (Wikipedia 22.07.2021)
CAVEAT 4
    • "Hawking radiation reduces the mass and rotational energy of black holes and is therefore also theorised to cause black hole evaporation. Because of this, blackholes that do not gain mass through other means are expected to shrink and ultimately vanish." (Wikipedia 22.07.2021).
    • A galactic blackhole is a galaxycore of sufficient mass that it is inside a blackhole.
    • A blackhole is a region, not an object.
    • An understable galaxycore differentially ejects energyvelocity and massvelocity and thus reduce its volume and consequently the volume of its blackhole.
    • A stable galaxycore matches its absorption of energyvelocity and massvelocity with its ejection of energyvelocity and massvelocity and thus neither volume alters.
    • An overstable galaxycore differentially absorbs energyvelocity and massvelocity and thus increases its volume and consequently the volume of its blackhole.
CAVEAT 5
    • "A barred spiral galaxy is a spiral galaxy with a central bar-shaped structure composed of stars. Bars are found in about half of all spiral galaxies." (Wikipedia 22.07.2021).
    • A barred spiral galaxy is a twocoregalaxy.
    • The nucleus of a twocoregalaxy is structurally the same, on a larger scale, as the nucleus of an electron.
    • The structure of a twocoregalaxy nucleus and the structure of an electron nucleus are as they are for the same reasons.
    • A twocoregalaxy nucleus is:
      • The teelocean of one galaxycore is axial.
      • The teelocean of the other galaxycore is centrifugal.
      • The aurasphere surrounding the galaxycore pair axial overall.
      • The axiality of the aurasphere makes it an oblate spheroid.
      • Each pole of the oblate spheroid emits a polar jet.
      • The bulge surrounding the aurasphere responds to the oblate spheroid shape and the polar jets to be an even more oblate spheroid.
      • Thus a twocoregalaxy has the shape of a barred spiral galaxy.
CAVEAT 6MORNING
  • Current Paradigm:
    • "An astrophysical jet is an astronomical phenomenon where outflows of ionised matter are emitted as an extended beam along the axis of rotation." "Most of the largest and most active jets are created by supermassive black holes in the centre of active galaxies such as quasars and radio galaxies or within galaxy clusters" (Wikipedia 22.07.2101).
CAVEAT 7
  • Current Paradigm:
    • "Big Bang nucleosynthesis occurred within the first three minutes of the beginning of the universe and is responsible for much of the abundance of 1H, 2H, 3He, and 4He. Although 4He continues to be produced by stellar fusion and alpha decays and trace amounts of 1H continue to be produced by spallation and certain types of radioactive decay, most of the mass of the isotopes in the universe are thought to have been produced in the Big Bang." (Wikipedia 24.07.2021)
    • Precedent:     Protons, on a smaller scale, have the above structure.
      • Proton stabilisation turbines emit subphotonics, photons, and electrons.
      • Galaxy stabilisation turbines are larger than proton stabilisation turbines.
      • Thus galaxy stabilisation turbines emit subphotonics, photons, electrons, and protons.
















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Copyright 2022 - Sian Luise Winchester








Comments and suggestions:  peter.ed.winchester@gmail.comCopyright 2021 - Sian Luise Winchester