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PARTICLE COUNTERPARTS

KNOWN PARTICLE	QUARK COMPOSITION	CHARGE (ELECTRON EQUIV.)	MASS GeV/c2	MAGNETIC FIELD ORIENTATION (SPIN)	COLOR	-------COMMENTS------	OBJECT COUNTERPART	CHARGE (ELECTRON EQUIV.)	---MASS--- GeV/c2	MAGNETIC FIELD ORIENTATION (SPIN)	COLOR
PHOTON	0	0	>0	1	NONE		SIMPLE WAVE GREATER THAN 3H	0	>0	1	NONE
NEUTRINO	0	0	>0	1	NONE	Theoretically required in beta decay and have been detected in small amounts.	SIMPLE WAVE SMALLER THAN 3H	0	>0	1	NONE
UP QUARK	-	+2/3	0.004	1/2	1 OF 6	Quarks are fundamental matter particles that are constituents of neutrons and protons  and other hadrons.	ISS	LESS THAN ONE	SOME	?	1 OF 6
DOWN QUARK	-	-1/3	0.008	1/2	1 OF 6	Quarks are fundamental matter particles that are constituents of neutrons and protons  and other hadrons.	ISS	LESS THAN ONE	SOME	?	1 OF 6
ELECTRON	0	-1	-	1/2	3 OF 6	RED, GREEN, BLUE	OSS TRION	NEAR ONE	SMALL	?	3 OF 6
POSITRON	0	+1	-	1/2	3 OF 6	CYAN,  MAGENTA, YELLOW	OSS TRION	NEAR ONE	SMALL	?	3 OF 6
NEUTRON	u, d, d	0	.940	1/2	3 OF 6	RED, GREEN, BLUE CYAN,  MAGENTA, YELLOW	DUAL-WAVE RADIAL TRION	0	MAX	?	3 OF 6
PROTON	u, u, d	+2/3 + 2/3 - 1/3 = 1	.938	1/2	3 OF 6	RED, GREEN, BLUE	ISS TRION	NEAR  ONE	NEAR MAX	?	3 OF 6
ANTI-PROTON	u, u, d	+1/3 - 2/3 - 2/3 = -1	.938	1/2	3 OF 6	CYAN,  MAGENTA, YELLOW	ISS TRION	NEAR  ONE	NEAR MAX	?	3 OF 6
PI MESON	u, d	+1	.140	0	-		ISS DION	-	-	?	2 OF 6

    Only a few of the more common particles are shown in this chart.  In the case of mesons, scientist suspect that there are more than 140 different types of mesons.   This corresponds very nicely in this thesis that there are numerous DION combinations, so far 75 presented, where DIONS and mesons are the same thing.
    Presumably, the formation of a DION from spiral configurations may more readily occur than the formation of a TRION, simply because only two spiral configurations are required, rather than three.
    It also seems that spiral configurations with similar shell radii will most likely combine than those with dissimilar radii.  This means that an ISS will more likely combine with another ISS, than an OSS, and that an OSS will more likely combine with another OSS, than an ISS.  Support for this come from the beta decay process, where three ISSs (a proton), once constituents of the now decaying neutron, retain their correspondence as such, and three OSSs form an electron through re-association.