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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?

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Stern Gerlach Experiment

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  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.

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