Aharonov-Bohm, electron interferometry, CMOS detectors and memory devices as electron interferometers and detectors for dynamic gravitational signals

Aharonov-Bohm, electron interferometry, CMOS detectors and memory devices as electron interferometers and detectors for dynamic gravitational signals

mod05lec14 – Aharonov-Bohm Effect at https://www.youtube.com/watch?v=NbOegkxWJ3A

Madhu Thalakulam,

You might enjoy “Interference between two independent electrons: observation of two-particle Aharonov-Bohm interference” by I. Neder, N. Ofek, Y. Chung, M. Heiblum, D. Mahalu, V. Umansky who show there is strong cross-correlation between current fluctuations in electron interferometer. I was looking to use electron interferometer, intermediate between the LIGO style photons and the atom interferometer.

The electron is much easier to control in massively parallel detectors like imaging arrays, and can be used for electron interferometry. See this Hitachi note on double slit experiments with electron microscope. Search for “Hitachi” “Double-slit experiment” “quantum measurement” Single electron 100% efficiency and good interference control.

Richard Collins, The Internet Foundation

https://www.hitachi.com/rd/research/materials/quantum/doubleslit/index.html

Interference between two independent electrons: observation of two-particle Aharonov-Bohm interference at https://arxiv.org/abs/0705.0173

Madhu Thalakulam, You might enjoy “Interference between two independent electrons: observation of two-particle Aharonov-Bohm interference” by I. Neder, N. Ofek, Y. Chung, M. Heiblum, D. Mahalu, V. Umansky who show there is strong cross-correlation between current fluctuations in electron interferometer. Widely separated very sensitive electron detectors will show correlations for distant gravitational sources on earth, moon and sun. Based on gravitational time of flight electron interferometric correlation imaging detector arrays.

I was looking to use electron interferometer, intermediate between the LIGO style photons and the atom interferometer. The electron is much easier to control in massively parallel detectors like imaging arrays or memory devices, and can be used for electron interferometry. See this Hitachi note on double slit experiments with electron microscope. Search for “Hitachi” “Double-slit experiment” “quantum measurement” Single electron 100% efficiency and good interference control. Richard Collins, The Internet Foundation

14 Jun 2023: Are electron pairs magnetically invisible? They have twice the electron charge, twice (or more mass) and no external magnetic field.  If they have large rotational and vibrational energy, their binding energy can be as large as their mass energy, so they would be gravitationally invisible as well, since the binding energy does not contribute to mass.  Magnetic dipole bound, Coulomb repulsion, quantized rotational and vibrational states, very narrow linewidths and precise directional constraints.  Nonlinear Schrodinger solitons at very high energies.  Also likely to cluster or chain.  There can be lots of binding energy that is invisible. Modes can oscillate. Are neutrinos simply magnetically bound Fermion pairs?