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.