NEUTRINOS

A. Gravitypull: an object's ability to attract other objects at a distance.
B. Neutrino gravitypull: a neutrino nucleus's ability to attract other objects at a distance.

Neutrino gravitypull: extant, absolute, potential.

Extant gravitypull: sum of nucleus teel gravitypulls (1) relative to nucleus volume (2) modified by teel disposition inside nucleus.

Absolute gravitypull: extant gravitypull extrapolated to be with teel nucleuses in contact.

Potential gravitypull: absolute gravitypull minus extant gravitypull.

Neutrino gravitypull: extrinsic, intrinsic.

extrinsic gravitypull

A. Extrinsic gravitypull: an object's gravitypull on another.
B. Neutrino extrinsic gravitypull: sum of nucleus teel gravitypulls on another object.

Neutrino extrinsic gravitypull:

decreases with distance from a neutrino nucleus per Inverse Square Law.

at any distance from a neutrino nucleus is a ratio of extant and potential extrinsic gravitypulls.

intrinsic gravitypull

A. Intrinsic gravitypull: an object's gravitypull on its own masscentre.
B. Neutrino intrinsic gravitypull: (default measurement) sum of nucleus teel gravitypulls on neutrino masscentre.

Neutrino intrinsic gravitypull:

decreases with decreasing nucleus teeldensity.
at any distance from nucleus masscentre a ratio of extant and potential intrinsic gravitypulls.

Masspush

A. Masspush: an object's resistance to deformation and/or penetration.
B. Neutrino masspush: a neutrino nucleus's ability to resist deformation and/or deformation.

Neutrino masspush: extant, absolute, potential.

Extant masspush: sum of teel nucleus volumes in neutrino nucleus (1) relative to neutrino nucleus volume (2) modified by teel nucleus disposition inside neutrino nucleus.

Neutrino absolute masspush: extant masspush extrapolated to be with teel nucleuses in contact.

Neutrino potential masspush: absolute masspush minus extant masspush.

Neutrino masspush: extrinsic, intrinsic.

extrinsic masspush

A. Extrinsic masspush: an object's resistance to deformation and/or penetration by another object.
B. Neutrino extrinsic masspush: sum of teel nucleus volumes in neutrino nucleus (1) relative to neutrino nucleus volume (2) modified by teel nucleus disposition inside neutrino nucleus.

Neutrino extrinsic masspush:

decreases with decreasing neutrino nucleus teeldensity.

decreases when increasing neutrino nucleus volume not countered by increasing teel numbers.

is a ratio of extant and potential masspushes.

intrinsic masspush

A. Intrinsic masspush: an object's resistance to deformation due to intrinsic teel collisions.
B. Neutrino intrinsic masspush: sum of teel nucleus volumes in neutrino nucleus (1) relative to neutrino nucleus volume (2) modified by teel nucleus orbits around neutrino masscentre.

Neutrino intrinsic masspush:

decreases with decreasing nucleus teeldensity.

decreasing teeldensity reduces collision frequency.

teel collisions result in teel speed/spin exchanges
teel collisions result in teel velocity changes.
teel collisions less deformative in teelcores than in teeloceans.

NEUTRINO SECONDARY INTERACTIONS

A: Secondary interaction: either of two interactions evolving directly from a primary interaction.
B: Neutrino secondary interactions: speed, spin.

Speed and spin: qualitative and quantitative nouns.
Speed and spin: different aspects of a neutrino's energy.
Energy: a qualitative and quantitative noun.
Speed and spin: equated per speed-spin equation law.
Speed and spin: transmute one to another per speed-spin transmutation law.

Speed and spin: default measured at neutrino nucleus surface.

Speed

A: Speed: linear movement caused by objects gravitypulling each other.
B: Neutrino speed: linear movement caused by mutual gravitypull of teel pairs.

Neutrino speed: extant, absolute, potential.

Extant speed: speed relative to a benchmark.

Absolute speed: extant speed extrapolated to be as with teel nucleuses in contact.

Potential speed: absolute speed minus extant speed.

Neutrino speed: extrinsic, intrinsic.

extrinsic speed

A: Extrinsic speed: an object's speed relative to another object.
B: Neutrino extrinsic speed: neutrino nucleus average teel velocity relative to another object's nucleus.

Neutrino extrinsic speed:

increases with convergence on nucleus of another object.

decreases with divergence from nucleus of another object.

at any distance from another object's nucleus is a ratio of extant and potential extrinsic speeds.

intrinsic speed

A: Intrinsic speed: sum of speeds of an object's teels relative to object's masscentre.
B: Neutrino intrinsic speed: sum of speeds of a neutrino's teels relative to neutrino masscentre.

Neutrino intrinsic speed:

increases with teel convergence on neutrino masscentre.

decreases with teel divergence from neutrino masscentre.

is a ratio of extant and potential speeds.

Spin

A: Spin: rotational movement caused by objects colliding.
B: Neutrino spin: rotational movement caused by neutrino nucleus teel collisions.

Neutrino spin: extant, absolute, potential.

Extant spin: spin relative to a benchmark.

Absolute spin: extant spin extrapolated to be with teel nucleuses in contact.

Potential spin: absolute spin minus extant spin.

Neutrino spin: extrinsic, intrinsic.

extrinsic spin

A. Extrinsic spin: an object's spin relative to another object.
B. Neutrino extrinsic spin: nucleus equatorial teel orbital velocities relative to another object's nucleus.

Neutrino extrinsic spin:

alters with teel convergence or divergence re neutrino masscentre.

may alter if nucleus teels collide.

may alter if nucleus collides with another object.

intrinsic spin

A. Intrinsic spin: an object's spin relative to its masscentre.
B. Neutrino intrinsic spin: sum of nucleus teel spins relative to nucleus masscentre.

Neutrino intrinsic spin:

may alter during nucleus teel collisions.

may alter during nucleus collision with another object.

Caveat: on absolute teel convergence all intrinsic spin is transmuted to intrinsic speed (strictly: teel at exact centre still spins).

NEUTRINO STRUCTURE

A: Structure: an arrangement of parts that endures for a measurable time.
B: Neutrino structure: dimensions, mechanisms, points, stratums.

Dimensions

A: Dimension: a measurement of an extent.
B: Neutrino dimensions: depth, duration, height, volume, and width.

Neutrino nucleus:

Neutrino nucleus: has a centre.
Neutrino nucleus: has an axis.
Neutrino nucleus: has a surface.
Neutrino nucleus: consists of numbers of teels.

Teel: a nucleus inside a gravitysheath.

Teel gravitysheath: region inside which teel nucleus gravitypull is stronger than gravitypull of any other object.

Neutrino nucleus: volume is sum of teel gravitysheath volumes.

Neutrino nucleus dimensions:

Depth: length of straight line from surface to surface passing through axis that is 90° to height and width.
Duration: length of time between neutrino nucleus events.
Height: length of straight line from surface to surface that is nucleus axis and 90° vertical to depth and width.
Volume: three dimensional measure of region inside nucleus surface.
Width: length of straight line from surface to surface passing through axis that is 90° to depth and height.

Mechanisms

A: Mechanism: an arrangement of parts that interact in a preordained manner to deliver an expected result or product.
B: Neutrino mechanisms: gravitymass differential mechanism, gravitypull attunement mechanism, teelstream attunement mechanism.

gravitymass differential mechanism

A: Gravitymass differential mechanism: a mechanism that semistabilises a monocore teelcomposite and stabilises a multicore teelcomposite.
B: Neutrino gravitymass differential mechanism: a mechanism that semistabilises a neutrino.

Gravitymass differential: gravityvelocity gained when a teel is absorbed by a teelcomposite always exceeds massvelocity gained.
Gravitymass differential: gravityvelocity lost when a teel is ejected by a teelcomposite always exceeds massvelocity lost.

Gravityvelocity: sum of vergencevelocities of a neutrino's teels.

Vergencevelocity: velocity at which a teel is freefalling toward or away from neutrino gravitysheath interface.

Massvelocity: sum of escapevelocities of a neutrino's teels.

Escapevelocity: minimum velocity needed for teel to freefall from current position to beyond neutrino gravitysheath interface.

Semistable neutrino: when neutrino gravityvelocity and neutrino massvelocity are same.

gravitymassvelocity: ejection counters absorption so neutrino semistability continues.

Understable neutrino: when neutrino gravityvelocity exceeds neutrino massvelocity.

gravitymassvelocity: ejection exceeds absorption so neutrino semistabilises or dissipates.

Overstable neutrino: when neutrino massvelocity exceeds gravityvelocity.

gravitymassvelocity: absorption exceeds ejection so neutrino semistabilises.

Semistabilisation: modified by stabilisation lag.

stabilisation lag: time taken for absorbed understabilising gravitymassvelocity to be ejected.

Semistabilisation: modified by doppler attunement.

doppler attunement (1): semistabilisation acceleration due to convergence on another object.
doppler attunement (2): semistabilisation deceleration due to divergence from another object.

Caveat: a neutrino moving through a teelstream cannot help but absorb teels from it triggering gravitymass differential mechanism and stabilisation lag.

gravitypull attunement

A: Gravitypull attunement: a neutrino's gravitypull and that of an adjacent object are made equal and opposite at their mutual gravitysheath interface by gravitymass differential mechanism.

Gravitypull attunement: unattuned neutrinos are overstable or understable.

Overstable neutrinos: eject more gravitymassvelocity than they absorb until they are attuned.

Understable neutrinos: absorb more gravitymassvelocity than they eject until they are attuned.

Gravitypull attunement: modified by stabilisation lag.

Gravitypull attunement: is modified by doppler attunement.

Gravitypull attunement: can occur simultaneously with teelstream attunement.

teelstream attunement

A: Teelstream attunement: neutrino teelosphere heft is equalised with that of surrounding teelstream at their mutual gravitysheath interface by gravitymass differential mechanism.

Teelstream attunement: unattuned neutrinos are overstable or understable.

Overstable neutrinos: eject more gravitymassvelocity than they absorb until they are attuned.

Understable neutrinos: absorb more gravitymassvelocity than they eject until they are attuned.

Teelstream attunement: modified by stabilisation lag.

Teelstream attunement: modified by doppler attunement.

Teelstream attunement: can occur simultaneously with gravitypull attunement.

Points

A: Point: a place in space and time without magnitude.
B: Neutrino points: gravitycentre, masscentre, pole.

gravitycentre

A: Gravitycentre: point on straight line between objects where their gravitypulls are equal and opposite.
B: Neutrino gravitycentres: extrinsic gravitycentre, intrinsic gravitycentre.

Extrinsic gravitycentre: point on straight line between neutrino intrinsic gravitycentre and intrinsic gravitycentre of another object where their gravitypulls are equal and opposite.

Intrinsic gravitycentre: point inside neutrino nucleus where neutrino teel mutual gravitypulls are most nearly all equal and opposite.

masscentre

A: Masscentre: point around which objects orbit due to mutual gravitypull.
B: Neutrino masscentres: extrinsic masscentre, intrinsic masscentre.

Extrinsic masscentre: point on straight line between neutrino intrinsic masscentre and intrinsic masscentre of another object around which they orbit.

Intrinsic masscentre: point inside neutrino nucleus around which neutrino teels most nearly orbit.

pole

A: Pole: two points where object's axis crosses nucleus surface.
B: Neutrino poles: northpole, southpole.

Northpole: axis point on neutrino nucleus surface nominated to be north.

Southpole: axis point on neutrino nucleus surface nominated to be south.

Stratum

A: Stratum: a distinct layer within a structure.
B: Neutrino stratums: teelcore, teelocean, teelosphere.

Neutrino stratums: typified by bonding type.

Neutrino stratification: solidbonded teelcore inside a liquidbonded teelocean inside a gasbonded teelosphere.

teelcore

A: Teelcore: a stratum of solidbonded teels.

Solidbonding:

when average teel speeds are low enough for teels to lattice.
teelcore lattice is three dimensional arrangement of teels in rows and columns.
teels in a semistable lattice may speed and spin but cannot escape their position.
increases in teel speed increase volume of teelcore lattice and reduce its teeldensity.
absolute solidbond is all teels drawn to the limits of their masspush and unable to speed or spin.

Teelcores: overstable, semistable, understable.

Overstable: gravityvelocity less than massvelocity.

absorbs teels (gravitymassvelocity) from teelocean until semistable.

Semistable: gravityvelocity same as massvelocity.

absorbs and ejects teels (gravitymassvelocity) from and to teelocean equally and endures as semistable.

Understable: gravityvelocity more than massvelocity.

ejects teels (gravitymassvelocity) into the teelocean until semistable.

Caveat: lower gravitymass neutrinos may have a teelocean without a teelcore.

Caveat: neutrino teelcores, teeloceans, and teelospheres may not be simultaneously overstable, semistable, or understable.

teelocean

A: Teelocean: a stratum of liquidbonded teels.

Liquidbonding:

when average teel speeds are too high for solidbonding and too low for gasbonding.
adjacent teels are a mix of open orbits and closed orbits about their mutual extrinsic masscentres (Brownian motion).
given sufficient neutrino spin teels form into teelstreams within centrifugal teelstream systems.

Teeloceans: overstable, semistable, understable.

Overstable: gravityvelocity less than massvelocity.

absorbs teels (gravitymassvelocity) from teelcore and teelosphere until semistable.

Semistable: gravityvelocity same as massvelocity.

absorbs and ejects teels (gravitymassvelocity) from and to teelcore and teelosphere and endures as semistable.

Understable: gravityvelocity more than massvelocity.

ejects teels (gravitymassvelocity) into teelcore and teelosphere until semistable.

Caveat: neutrino teeloceans, teelcores, and teelospheres may not be overstable, semistable, or understable simultaneously.

teelosphere

Teelosphere: a stratum of gasbonded teels.

Gasbonding:

when average teel speeds are too high for liquidbonding.
adjacent teels are in open orbits about their mutual extrinsic masscentres (Brownian motion).
given sufficient neutrino spin teels form into teelstreams within centrifugal teelstream systems.

Teelospheres: overstable, semistable, understable.

Overstable: gravityvelocity less than massvelocity.

absorbs teels (gravitymassvelocity) from teelocean and from outside gravitysheath interface until semistable.

Semistable: gravityvelocity same as massvelocity.

absorbs and ejects teels (gravitymassvelocity) from and to teelocean and from outside gravitysheath interface and endures as semistable.

Understable: gravityvelocity more than massvelocity.

ejects teels (gravitymassvelocity) into teelocean and over gravitysheath interface until semistable.

Caveat: neutrino teelospheres, teelcores, and teeloceans may not be overstable, semistable, or understable simultaneously.

NEUTRINO MANUFACTURE

Manufacture: creating objects from lesser objects by a mechanism or process.
Neutrino manufacture: objects created in the toruses of appropriately understable protons and tralphiums.

Neutrino manufacture: a proton and tralphium stabilisation process.

Torus

Torus: a stabilisation mechanism in stableable three core multicores.
Protons and tralphiums: the only known stableable three core multicores.

Torus: two spinning and co-orbiting axial objects.

Proton torus: two axiquarks.

Tralphium torus: two protons.

Torus: a compressor, choke, and exhaust.

Compressor: where teelstream is compressed, bonded, accelerated, and spun.

Choke: where compression, bondment, acceleration, and spin is torus maximum.

Exhaust: where teelstream partially decompresses and droplets into neutrinos.

Torus teelstream: driven though torus by a centrifugal object.

Proton teelstream: driven by a centriquark.

Tralphium teelstream: driven by a neutron.

torus structure (1)

Structure: an arrangement of substructures that endures for a measurable time.
Torus substructures: two axially structured objects that spin while orbiting their extrinsic masscentre.

Proton substructures: two axiquarks, one centriquark.

proton axiquark: an engorged photide.

axiquark nucleus: a teelcore inside an axial teelocean.

axiquark teelosphere: axial but vestigial because axiquark is inside proton teelocean.

axiquark engorgement: continuous teel absorption from proton teelocean teelstream system at northpole with corresponding teel ejection at southpole.

axiquark bondment: held in place by strongforce.

axiquark strongforce: repelling heft of each teelocean teelstream system counters attracting mutual gravitypull.

axiquark orbits: axiquarks orbit their mutual extrinsic masscentre.

axiquark spin: axiquarks spin counter to each other.

axiquark orientation: axiquark axes aligned to proton axis, axiquark northpole to proton northpole.

proton centriquark: an engorged photide.

centriquark nucleus: a teelcore inside a centrifugal teelocean.

centriquark teelosphere: centrifugal.

centriquark engorgement: by continuous teel absorption from proton teelstream system at both poles with corresponding teel ejection at equator.

centriquark bondment: held in place against torus compressor by strongforce.

centriquark strongforce: repelling heft of centriquark teelosphere teelstream system counters axiquark gravitypulls, reinforced by interceding proton teelstream system.

centriquark spin: intrinsically and extrinsically spinning.

centriquark orientation: equator aligned to proton axis.

torus teelstream: driven by proton centriquark spin.

torus teelstream: moves between orbiting proton axiquarks.

torus teelstream: heft increases as proton understability increases.

torus teelstream: increasing heft diverges axiquarks commensurately.

Tralphium substructures: two protons, one neutron.

Tralphium proton: an engorged nucleon.

proton nucleus: a multicore inside an axial teelocean.

proton teelosphere: axial but vestigial because proton is within tralphium teelocean.

proton engorgement: continuous teel absorption from tralphium teelocean teelstream system at northpole with corresponding teel ejection at southpole.

proton bondment: held in place by strongforce.

proton strongforce: repelling heft of each proton's teelocean teelstream system counters attracting mutual gravitypull.

proton orbits: protons orbit their mutual extrinsic masscentre.

proton spin: protons spin counter to each other.

proton orientation: proton axes aligned to tralphium axis, proton northpole to tralphium northpole.

tralphium neutron: an engorged nucleon.

neutron nucleus: a multicore inside a centrifugal teelocean.

neutron teelosphere: centrifugal.

neutron engorgement: continuous teel absorption from tralphium teelstream system at both poles with corresponding teel ejection at equator.

neutron bondment: held in place against torus compressor by strongforce.

neutron strongforce: repelling heft of neutron teelosphere teelstream system counters proton gravitypulls reinforced by interceding tralphium teelstream system.

neutron spin: intrinsically and extrinsically spinning.

Neutron orientation: equator aligned to tralphium axis.

torus teelstream: driven by tralphium neutron spin.

torus teelstream: moves between orbiting protons.

torus teelstream: heft increases as tralphium understability increases.

torus teelstream: increasing heft diverges protons commensurately.

torus structure (2)

Structure: an arrangement of substructures that endures for a measurable time.
Torus substructures: compressor, choke, exhaust.

Torus: a stabilisation mechanism in protons and tralphiums.

torus (proton): two axiquarks.
torus (tralphium): two protons.
torus (axiquarks/protons): spin counter to each other.
torus (axiquarks/protons): spin equator to equator.
torus (axiquarks/protons): co-orbit their mutual extrinsic masscentre.

Compressor: a proton or tralphium torus substructure.

compressor extent: torus entry to torus choke.
compressor inner diameter: decreases from entry to choke.
compressor teelstream: moves continuously from compressor entry to choke.
compressor teelstream: has linear masscentre and linear surface.

teelstream density: increases as compressor inner diameter decreases and teels converge.

teelstream bonds: strength increases as compressor inner diameter decreases and teels converge.

teelstream speed: increases as decreasing compressor inner diameter transmutes potential speed to extant speed by converging teels.

teelstream spin: increases as compressor inner diameter decreases and increasing axiquark/proton spin equalises with teelstream spin.

Choke: a proton or tralphium torus substructure.

choke extent: constriction between compressor and exhaust.
choke point: transition from compression to decompression, convergence to divergence, contraction to expansion.
choke teelstream: moving continuously through choke from compressor to exhaust.
choke teelstream: has linear masscentre and linear surface.

teelstream density: at greatest within torus.
teelstream bonds: at strongest within torus.
teelstream speed: at fastest within torus.
teelstream spin: at its fastest within torus.

choke teelstream: teel speeds are orbital as teelstream spins.
choke teelstream: teel speeds are linear as teelstream moves through choke.
Choke teelstream: per gravity law teels are most strongly attracted toward masscentre.

teel orbital speeds:

highest at teelstream surface - lowest at teelstream masscentre.

teel linear speeds:

lowest at teelstream surface - highest at teelstream masscentre.

teel density:

lowest at teelstream surface - highest at teelstream masscentre.

choke teelstream: compression degree at compressor entry dictates compression degree at choke.

lowest compression:

teelstream at choke is a linear teelosphere.

higher compression:

teelstream at choke is a linear teelocean inside a linear teelosphere.

highest compression:

teelstream at choke is a linear teelcore inside a linear teelocean inside a linear teelosphere.

Exhaust: a proton or tralphium torus substructure. that partly or wholly decompresses teelstream.

exhaust extent: choke to exhaust exit.
exhaust inner diameter: increases from choke to exit.
exhaust teelstream: moves continuously from choke to exhaust exit.
exhaust teelstream: has linear masscentre and linear surface.

teelstream density: decreases as compressor inner diameter increases and teels are able to diverge.
teelstream bonds: strength decreases as compressor inner diameter increases and teels are able to diverge.
teelstream speed: decreases as increasing exhaust inner diameter transmutes extant speed to potential speed by diverging teels.
teelstream spin: decreases as exhaust inner diameter increases and decreasing axiquark/proton spin equalises with teelstream spin.

Caveat: teel divergence is subject to (1) ability of teels to overcome teel pair mutual gravitypull, and (2) teelstream's intrinsic gravitypull, as per gravitymass differential mechanism.

exhaust teelstream: compression degree at choke dictates compression degree at exhaust exit.

lowest compression:

teelstream at exhaust exit is an expanding linear teelosphere:

after exit may or may not wholly dissipate.

higher compression:

teelstream at exhaust exit is an unexpanded linear nucleus (a teelocean) inside an expanding linear teelosphere:

after exit (1): outer teelosphere dissipates.
after exit (2): inner teelosphere and linear nucleus droplet into a "string" of neutrinos.

highest compression:

teelstream at exhaust exit is an unexpanded linear nucleus (a teelcore inside teelocean) inside an expanding linear teelosphere.

after exit (1): outer teelosphere dissipates.
after exit (2): inner teelosphere and linear nucleus droplet into a "string" of neutrinos.

emission

Emission: ejection of fundamides, photides, and morphides by understable protons and tralphiums.
Neutrino emission: a neutrino exiting the gravitysheath interface of its manufacturing proton or tralphium.

Emission:

prior to emission neutrinos move from torus exhaust to gravitysheath interface through a region which may or may not be wholly filled with teelosphere.

neutrinos exiting torus exhaust may or may not be superluminal.

neutrinos after emission may or may not be superluminal.

neutrinos exiting torus exhaust are understable or overstable.

neutrinos may or may not semistabilise before emission.

neutrinos understable or overstable prior to emission semistabilise after emission.

Caveat: when protons and tralphiums are substructures inside nuclides or molecules, neutron emission may or may not be followed by neutron emission across the nuclide or molecule.

semistabilisation

Semistabilisation: when an overstable or understable monocore's absorbing or ejecting of gravitymassvelocity is bringing it toward being semistable.
Neutrino semistabilisation: a neutrino attuning to an adjacent object's gravitypull and an adjacent teelstream's heft.

Neutrino semistabilisation: to above or below photonband.

Photonband:

above or below photonic masses.

above or below lightspeed.

Rules of thumb:

semistabilisation below photonic masses is initially above lightspeed.

semistabilisation above photonic masses is initially below lightspeed.

Neutrino semistabilisation:

achieved per gravitymass differential mechanism.

achieved by gravitypull attunement.

achieved by teelstream attunement.

modified by stabilisation lag.

modified by doppler attunement.

NEUTRINO LAWS

Laws: statements concerning phenomenal equivalences, orders, sequences, relationships, etc, for which no ambiguities, deviations, exceptions, etc, are currently known.

Energy Law

Energy is not created or destroyed.

Gravitational Inverse Square Law

The mutual gravitypull of a neutrino and another object is directly proportional to the product of their gravitymasses and inversely proportional to the square of their separation distance. The mutual gravitypull is always attractive and acts along the straight line between their masscentres.

Gravity Law

A neutrino moves toward the object gravitypulling it most strongly.

Gravitypull Law

Gravitypull is not created or destroyed.

Inverse Square Law

The gravitypull of a neutrino is inversely proportional to the square of the distance from the surface of its nucleus.

Mass Law

A neutrino cannot occupy a place in space and time already occupied by another neutrino.

Masspush Law

Masspush is not created or destroyed.

Relativity Law

All measurements are relative to a benchmark.

Speed-Spin Equation Law

One unit of speed equates to one unit of spin.

Speed-Spin Transmutation Law

One unit of speed or spin can transmute to any ratio of speed or spin but the sum of that speed or spin is always one unit.

Weight Law

A neutrino's gravitypull and masspush is equal and opposite at the surface of its nucleus modified by nucleus teeldensity.

PHOTIDES | TOP | PHOTONS

SUPERSEDED MATTER

QUARKS Empirical confirmation: partial. Composite objects. A simple nucleus inside a teelosphere inside a gravitysheath. The nucleus is a teelcore inside a teelocean. Two morphs: axiquarks and centriquarks. Both morphs are understable and only endure when strongforced and engorged.

Axiquarks Axiquark teelospheres have axially structured teelstream systems. Axiquarks endure when in the nuclei of electroids or nucleons. Free axiquarks transmute to centriquarks. Electroid axiquarks are less massive than nucleon axiquarks. Electroid axiquarks are manufactured in the stabilisation turbines of understable protons. The origin of nucleon axiquarks is unknown.

Centriquarks Centriquark teelospheres have centrifugally structured teelstream systems. Centriquarks endure when in the nuclei of electroids or nucleons. Free centriquarks transmute to photons. Electroid centriquarks are less massive than nucleon centriquarks. Electroid centriquarks are manufactured in the stabilisation turbines of understable protons. The origin of nucleon centriquarks is unknown.

AXIQUARKS

MORPHIDES A taxa of three taxons: quarks, electroids, and nucleons: each of which transmutes between two differently structured morphs.
QUARKS A morphide taxon with two morphs: axiquarks and centriquarks.

AXIQUARKS Empirical confirmation: partial.

AXIQUARK STRUCTURE A simple nucleus inside a teelosphere inside a gravitysheath. The nucleus is a teelcore inside a teelocean. The teelosphere is axial.

A XIQUARK TYPES Free axiquarks. Electroid axiquarks. Nucleon axiquarks. Nucleon axiquarks are structurally the same as electroid axiquarks but more mass ive.

AXIQUARK BEHAVIOUR Free axiquarks are understable and stabilise as photons. Electroid axiquarks are understable but endure because they are bound into electroids and engorged. Nucleon axiquarks are understable but endure because they are bound into nucleons and engorged.

AXIQUARK ORIGINS The origin of electroid axiquarks is manufacture in the stabilisation turbines of understable protons. The origin of nucleon axiquarks is unknown.

CENTRIQUARKS

CENTRIQUARK STRUCTURE A simple nucleus inside a teelosphere inside a gravitysheath. The nucleus is a teelcore inside a teelocean. The teelosphere is centrifugal.

CENTRIQUARK TYPES Free centriquarks. Electroid centriquarks. Nucleon centriquarks. Nucleon centriquarks are structurally the same as electroid centriquarks but more massive.

CENTRIQUARK BEHAVIOUR Free centriquarks are understable and stabilise as photons. Electroid centriquarks are understable but endure because they are bound into electroids and engorged. Nucleon centriquarks are understable but endure because they are bound into nucleons and engorged.

CENTRIQUARK ORIGINS The origin of electroid centriquarks is manufacture in the stabilisation turbines of understable protons. The origin of nucleon centriquarks is unknown.