https://www.nobelprize.org/prizes/physics/1998/press-release/
That's really interesting....but the one small problem is it has nothing to do with subquarks.
Try again. If you are going to post a link try next time to post a relevant one that actually addresses the point at hand.
You don’t see it? Electrons changing in a strong magnetic field means they always change and cause gravity. Duh.
Im not sure if the Duh is directed at me but the 1998 Nobel prize has nothing to do with the discovery of subquarks. According to Scientific American:
https://www.scientificamerican.com/article/the-1998-nobel-prizes/According to the Nobel citation, the three researchers are receiving the award "for their discovery of a new form of quantum fluid with fractionally charged excitations." What they found was that electrons acting together in strong magnetic fields can form new types of "particles," with charges that are fractions of electron charges. "The contributions of the three laureates have thus led to yet another breakthrough in our understanding of quantum physics and to the development of new theoretical concepts of significance in many branches of modern physics," says The Royal Swedish Academy of Sciences.
Edwin Hall's initial finding was that when electrons moving along a metal strip are subjected to a magnetic field perpendicular to the plane of the strip, they are deflected toward the one side of the strip where they cause an excess electrical charge to build up. This Hall voltage is proportional to the strength of the magnetic field. The Hall effect can be used to determine the density of charge carriers (negative electrons or positive holes) in conductors and semi-conductors, and has become a standard tool in physics.
The Hall effect could easily be explained by the laws of classical physics until researchers started looking at it in two-dimensions. In 1980, Klaus von Klitzing of the Max-Planck-Institute for Solid State Research conducted experiments on the behavior of electrons confined to two dimensions at the interface between two semiconductors. These experiments took the Hall effect into the strange world of quantum mechanics where the electrons took on the properties of a fluid.
In this "quantum fluid," a plot of Hall resistance versus field strength was no longer linear: it had become a staircase. Klitzing's discovery of the "quantized Hall effect" won him the physics Nobel Prize in 1985; so precise were the steps, or quanta, that his experiment has been used to define the unit of electrical resistance.
Regardless of the 1998 Nobel Prize, Subquarks have never been detected. The fact that Sandokhan keeps refering to them as actually existing is a clear demonstration that he has a tendency to just makes things up to suit his own agenda.
If you or anyone else for that matter thinks they exist its a simple matter of pointing to, when, where and by whom they were discovered, along with a supporting paper.