Michio Kaku-- a famous line says: if string theory can calculate the masses of the elementary particles, the game is over. Okey, not string theory!
The key move is to stop treating superposition as “what is,” and use it only as “how we calculate.” Then add one physical rule that ties a phase space to our ordinary space: radius × internal frequency = speed of light. That single lock keeps the math finite and the motion deterministic. maybe God eq Rw=c
With that lock in place, the electron’s own field slows its internal clock a little (a real time-dilation effect). From that, you can get the g-factor with a short relation—and you can make the electron mass emerge from first principles, no tuning. The number lines up with experiment to high precision.
The picture is clean; finite modes instead of infinite sums; no extra dimensions; paths through the double slit become ordinary, once the lock supplies the missing constraint; entanglement is just a shared internal beat between two systems.
Is every step written out in textbook detail yet? Not all—filling every gap could take hundreds of pages. But the route is clear, the checkpoints are solid, and the tests are on the table.
So, with respect Mr. Kaku; you said “game over” when someone can get masses from first principles. I’m saying: game over, Mr. Kaku—electron mass is in hand. Now let’s open it up, stress-test it, and make the full book.
thomasdziedzic•52m ago
Why is the author listed as Mehrdad Ghasemizadeh in researchgate but the author is listed as M. Pajuhaan on the paper?
pajuhaan•2h ago
The key move is to stop treating superposition as “what is,” and use it only as “how we calculate.” Then add one physical rule that ties a phase space to our ordinary space: radius × internal frequency = speed of light. That single lock keeps the math finite and the motion deterministic. maybe God eq Rw=c
With that lock in place, the electron’s own field slows its internal clock a little (a real time-dilation effect). From that, you can get the g-factor with a short relation—and you can make the electron mass emerge from first principles, no tuning. The number lines up with experiment to high precision.
The picture is clean; finite modes instead of infinite sums; no extra dimensions; paths through the double slit become ordinary, once the lock supplies the missing constraint; entanglement is just a shared internal beat between two systems.
Is every step written out in textbook detail yet? Not all—filling every gap could take hundreds of pages. But the route is clear, the checkpoints are solid, and the tests are on the table.
So, with respect Mr. Kaku; you said “game over” when someone can get masses from first principles. I’m saying: game over, Mr. Kaku—electron mass is in hand. Now let’s open it up, stress-test it, and make the full book.