1 / 5

Stern Gerlach Experiment

Stern Gerlach Experiment. how spins behave in magnetic fields. Thanks to Sam McKagan, Kathy Perkins, Carl Wieman, and Noah Finkelstein  . Spin is quantized. For electrons (& other fermions), spin can only take on two values: up ↑ or down ↓ . What’s so special about the z-axis?

virgo
Download Presentation

Stern Gerlach Experiment

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Stern Gerlach Experiment how spins behave in magnetic fields Thanks to Sam McKagan, Kathy Perkins, Carl Wieman, and Noah Finkelstein  

  2. Spin is quantized • For electrons (& other fermions), spin can only take on two values: up ↑ or down ↓. • What’s so special about the z-axis? • Answer: nothing. • Can measure spin along any axis, will always find spin either aligned or anti-aligned with the axis you measure along. • Just like position and momentum, spin along orthogonal axes obeys Heisenberg uncertainty principle: sxsz≥/2; sysz≥/2; sxsy≥/2 • State of definite spin in x-direction --> 50/50 superposition of up and down in z-direction.

  3. How do we know? Stern-Gerlach Experiment Put atoms in inhomogeneous magnetic field pointing in z direction – split in two groups – spin up and spin down z What if I take just atoms that went up, and send them through another, identical magnetic field – What happens? z • Half go up (+z), half go down (–z) • All go up (+z) • All go down (–z) • Range of paths all smeared out Magnetic field measures spin of atoms. All atoms that end up on top are in definite state of spin up.

  4. Second Experiment: What if I take just atoms that went up, and send them through a magnetic field pointed in the x direction – perpendicular to first field (pointing into the screen)? z x • Half go into the screen (+x), half go out of the screen (–x) • All go into the screen (+x) • All go straight (no deflection) • Range of paths all smeared out • All go up (+z) Spin in x direction and z direction are “incompatible observables” – like position and momentum. Obey uncertainty relation sxsz≥/2. Can’t know both at same time!

  5. Third Experiment: Take just the atoms that went in +x direction in second experiment, and send them through a third magnetic field, pointed in the z direction? z x z • Half go up (+z), half go down (–z). • All go up (+z) • All go down (–z) • Range of paths all smeared out. Even though all atoms going into final field started out in state +sz, they are now in state +sx, spin x measurement destroyed spin z info.

More Related