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The compton effect

The Compton effect    is the term used for an unusual result observed when X-rays are scattered on some materials. By classical theory, when an electromagnetic wave is scattered off atoms, the wavelength of the scattered radiation is expected to be the same as the wavelength of the incident radiation. Contrary to this prediction of classical physics, observations show that when X-rays are scattered off some materials, such as graphite, the scattered X-rays have different wavelengths from the wavelength of the incident X-rays. This classically unexplainable phenomenon was studied experimentally by Arthur H. Compton and his collaborators, and Compton gave its explanation in 1923.

To explain the shift in wavelengths measured in the experiment, Compton used Einstein’s idea of light as a particle. The Compton effect has a very important place in the history of physics because it shows that electromagnetic radiation cannot be explained as a purely wave phenomenon. The explanation of the Compton effect gave a convincing argument to the physics community that electromagnetic waves can indeed behave like a stream of photons, which placed the concept of a photon on firm ground.

The schematics of Compton’s experimental setup are shown in [link] . The idea of the experiment is straightforward: Monochromatic X-rays with wavelength λ are incident on a sample of graphite (the “target”), where they interact with atoms inside the sample; they later emerge as scattered X-rays with wavelength λ . A detector placed behind the target can measure the intensity of radiation scattered in any direction θ with respect to the direction of the incident X-ray beam. This scattering angle    , θ , is the angle between the direction of the scattered beam and the direction of the incident beam. In this experiment, we know the intensity and the wavelength λ of the incoming (incident) beam; and for a given scattering angle θ , we measure the intensity and the wavelength λ of the outgoing (scattered) beam. Typical results of these measurements are shown in [link] , where the x -axis is the wavelength of the scattered X-rays and the y -axis is the intensity of the scattered X-rays, measured for different scattering angles (indicated on the graphs). For all scattering angles (except for θ = 0 ° ), we measure two intensity peaks. One peak is located at the wavelength λ , which is the wavelength of the incident beam. The other peak is located at some other wavelength, λ . The two peaks are separated by Δ λ , which depends on the scattering angle θ of the outgoing beam (in the direction of observation). The separation Δ λ is called the Compton shift    .

Figure shows a schematic of the experimental setup for studying Compton scattering. X-rays exit a source, pass through the collimating slits and are incident on a sample of graphite. X-rays scattered by the target are detected by the detector.
Experimental setup for studying Compton scattering.
Three graphs show the variation of intensity of the scattered beam with wavelength. Left graph corresponds to data collected at the angle theta equal to zero. One sharp peak appears at the wavelength gamma. Middle graph corresponds to data collected at the angle theta equal to 45 degrees. Two overlapping peaks of similar intensity with separation of 0.0006 nanometers are evident. There is also a tail towards the long-wavelength side of the spectrum. Right graph corresponds to data collected at the angle theta equal to 90 degrees. Two overlapping peaks with separation of 0.0022 nanometers are evident. The peaks are broader and the peak at the longer wavelength is much more intense. Tail towards the long-wavelength side of the spectrum is also present.
Experimental data show the Compton effect for X-rays scattering off graphite at various angles: The intensity of the scattered beam has two peaks. One peak appears at the wavelength λ of the incident radiation and the second peak appears at wavelength λ . The separation Δ λ between the peaks depends on the scattering angle θ , which is the angular position of the detector in [link] . The experimental data in this figure are plotted in arbitrary units so that the height of the profile reflects the intensity of the scattered beam above background noise.
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Source:  OpenStax, University physics volume 3. OpenStax CNX. Nov 04, 2016 Download for free at http://cnx.org/content/col12067/1.4
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