Two New Worlds!

If our Sun, a fusion nuclear reactor full of $p^{+}$, sends off $p^{+}$ particles.  Does a black hole full of $g^{+}$ particles radiates $g^{+}$ particles.

The question leading to this, was the nucleic set

($g^{+}$, $T^{+}$, $p^{+}$)

Why is $p^{+}$ at the outer shell complemented by $e^{-}$ particle?  Equally probable is,

($p^{+}$, $g^{+}$, $T^{+}$)

where at the outer shell, $T^{-}$ fills the orbit at the opposite end of the weak $T$ field that holds the $T^{+}$ particles.  And the case in point,

($T^{+}$, $p^{+}$, $g^{+}$)

where at the outer shell, $g^{-}$ fills the orbit at the opposite end of the weak $g$ field that holds the $g^{+}$ particles.

So we have a new kind of matter of a different type of nucleus, ($T^{+}$, $p^{+}$, $g^{+}$), whose chemical reactions center around the exchange and sharing of $g^{-}$ particles.  Planets of this new matter orbit around a black hole.  And life forms of this new matter on such planets thinking about the possibility of total extinction.

Two new worlds!

What is a dense concentration of $T^{+}$ particles.  A  White Dwarfs?  A white dwarf nucleus; white dwarf matter; white dwarf planets; white dwarf alien life forms.

Note: Why is $p^{+}$ at the outer shell complemented by $e^{-}$ particle?  Our Sun made us so.