This Is Also True For Stars, Galaxies, etc.
This piece seems to argue that variation around average masses is a unique feature of the quantum world. Actually, this is also seen in macroscopic objects like stars and galaxies. Accretion commonly adds mass to these objects and excess mass/energy is ejected via oscillations, rotation and powerful jets. Systems like pulsars, white dwarf stars, globular clusters and classes of galaxies have reasonably well-defined mass ranges.
If we could classify these astrophysical objects as accurately as we can in the case of quantum systems, then then Discrete Scale Relativity predicts that their physics would be equivalent to that of quantum systems. This classification is hampered by our inability to bring astrophysical objects into the lab and do precisely controlled measurements on them.
DSR argues that the dark matter is primarily in the form of stellar-mass black holes and that these Kerr-Newman Ultracompacts behave exactly the same as “fundamental” subatomic particles.
For an example of approximate mass discreteness in white dwarf stars, see the “Stellar Scale Discreteness?” page at: