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Principle
A beam of potassium atoms generated in a hot furnace travels along a specific path in a magnetic two-wire field. Because of the magnetic moment of the potassium atoms, the non-homogeneity of the field applies a force at right angles to the direction of their motion. The potassium atoms are thereby deflected from their path. By measuring the density of the beam of particles in a plane of detection lying behind the magnetic field, it is possible to draw conclusions as to the magnitude and direction of the magnetic moment of the potassium atoms.
Benefits
- Experience the essence of the Nobel Prize: Gerlach (1943)
- First proof of the quantization of the spatial orientation of the angular momentum
- A beam of neutral potassium atoms are deflected in a non homogeneous magnetic field and can even be measured precisely
Tasks
- Recording the distribution of the particle beam density in the detection plane in the absence of the effective magnetic field.
- Fitting a curve consisting of a straight line, a parabola, and another straight line, to the experimentally determined special distribution of the particle beam density.
- Determining the dependence of the particle beam density in the detection plane with different values of the non-homogeneity of the effective magnetic field.
- Investigating the positions of the maxima of the particle beam density as a function of the non-homogeneity of the magnetic field.
Learning objectives
- Magnetic moment
- Bohr magneton
- Directional quantization
- g-factor
- Electron spin
- Atomic beam
- Maxwellian velocity distribution
- Two-wire field
Device name
Article no.
Quantity
Article no. 12902-01
2
Cobra SMARTsense Wide-Range Temperature - Sensor for measuring temperature -20 ... 330°C (Bluetooth)
Article no. 12910-00
1
Article no. 12901-01
2
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Digital learning
(en) Versuchsbeschreibung
p2511101_en .pdf
File size 3.80 Mb
pdf
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Stern-Gerlach experiment
- .H5P
File size -
.H5P
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