Tuesday, March 3, 2020
Orbifold Eigenstate Pulsation And Rate Of Transference
The quicker that any given arbitrary orbifold eigenstate is transferred in its delineation through space over time, the quicker that its rate of pulsation will consequently tend to be. Next; let's consider two different orbifold eigenstates, that are both to be pulsating at the same covariant rate. Next; let's theoretically consider, in this particular case, that both of the here stated orbifold eigensets, are to be effected by the same scalar amplitude of substringular pressurized vacuum. Let's next say, that the individually taken superstrings of discrete energy permittivity, that work to comprise one of these two said orbifold eigensets, are to be vibrating at a quicker rate, -- than the individually taken superstrings of discrete energy permittivity, that work to comprise the other of the two said orbifold eigensets. Let's next say, that both of these here stated orbifold eigensets, are to work to bear both the same number of superstrings of discrete energy permittivity, over the course of their spatial transference of delineation. Both of such here mentioned orbifold eigensets, are also to work to bear the same density. The orbifold eigenset of this particular case, that is here to work to bear the proximal local presence of those inferred superstrings of discrete energy permittivity, that are here to be vibrating at a quicker rate, -- will consequently tend to bear a greater fractal modulus -- than the other of the two mentioned orbifold eigensets. Sam Roach.
Posted by
samsphysicsworld
at
2:02 PM
Labels:
eigenstate,
pressurized vacuum,
pulsating,
rate,
strings,
vibrating
Subscribe to:
Post Comments (Atom)
No comments:
Post a Comment