The Aharonov-Bohm effect demonstrates that a charged particle moving through a region of zero magnetic field still acquires a quantum phase shift when the vector potential A is non-zero, as the phase difference between two paths equals the enclosed magnetic flux divided by the flux quantum (φ₀ = h/e), with Tonomura's 1986 experiment confirming that A is physically real, not merely a mathematical convenience.
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Aharonov-Bohm Effect — Quantum Mechanics in 60 Seconds #ShortsIndexado:
A charged particle moving through a region of zero magnetic field still picks up a phase shift if the vector potential A is non-zero. The 1959 Aharonov-Bohm prediction was confirmed by Tonomura in 1986 and shows A is physical, not just a bookkeeping device. Subject: Quantum Mechanics --- Unseel Physics — Free visual learning https://unseel.com Watch more Unseel Physics: https://unseel.com/physics.html All subjects: https://youtube.com/@unseel --- AI Disclosure --- This video was entirely generated by artificial intelligence, including the 3D animation, narration script, and voiceover. Content is for educational and illustrative purposes only. It may contain factual errors, inaccuracies, or oversimplifications. Do not rely on this video as your sole source of information — always verify with authoritative, peer-reviewed sources. Unseel Physics is a product of Bitake LLC. Terms of Service: https://unseel.com/terms Privacy Policy: https://unseel.com/privacy #Shorts #QuantumMechanics #Aharonov-BohmEffect #VisualLearning #Education #AIGenerated
An electron beam splits and travels two paths around an obstacle. On the right, a detector. Standard interferometer.
Standard fringes.
Now, place a tiny solenoid between the paths. Inside it sits a strong magnetic field, trapped flux phi pointing along the axis. The electrons travel only outside the solenoid where the magnetic field is exactly zero. They feel no Lorentz force. Classically, nothing should happen. Launch the beam. The two paths recombine and form an interference pattern on the detector. The textbook double path fringes. But, the vector potential A is not zero outside the solenoid. It circulates around the flux like a whirlpool. And the electrons swim right through it. Each path picks up a phase from the integral of A along it.
The difference between the two paths equals E times the enclosed flux divided by N, a topological signature of the trapped field. Turn up the flux to half a flux quantum. The fringes slide by exactly half a period. Maxima land where minima used to be. Crank phi to one full flux quantum, and the pattern returns shifted by an entire fringe. The number of fringes shifted counts the quanta of flux trapped inside. Tonomura proved this in 1986 with a superconducting torus that shielded the field perfectly.
The electrons saw zero B everywhere.
And the shift was still there. A is physical. B is its curvature.
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