Compton scattering

In physics, Compton scattering or the Compton effect, is the decrease in energy (increase in wavelength) of an X-ray or gamma ray photon, when it interacts with matter. Inverse Compton scattering also exists, where the photon gains energy (decreasing in wavelength) upon interaction with matter. The amount the wavelength increases by is called the Compton shift. Although nuclear compton scattering exists, Compton scattering usually refers to the interaction involving only the electrons of an atom. The Compton effect was observed by Arthur Holly Compton in 1923 and further verified by his graduate student Y. H. Woo in the years following. Arthur Compton earned the 1927 Nobel Prize in Physics for the discovery.

The effect is important because it demonstrates that light cannot be explained purely as a wave phenomenon. Thomson scattering, the classical theory of an electromagnetic wave scattered by charged particles, cannot explain any shift in wavelength. Light must behave as if it consists of particles in order to explain the Compton scattering. Compton's experiment convinced physicists that light can behave as a stream of particles whose energy is proportional to the frequency.

The interaction between electrons and high energy photons results in the electron being given part of the energy (making it recoil), and a photon containing the remaining energy being emitted in a different direction from the original, so that the overall momentum of the system is conserved. If the photon still has enough energy left, the process may be repeated. If the photon has sufficient energy (in general a few eV, right around the energy of visible light), it can even eject an electron from its host atom entirely (a process known as the Photoelectric effect).

The Compton shift formula

For differential cross section of Compton scattering, see Klein-Nishina formula.

Compton used a combination of three fundamental formulas representing the various aspects of classical and modern physics, combining them to describe the quantum behavior of light.

• Light as a particle, as noted previously in the photoelectric effect.
• Relativistic dynamics Special Theory of Relativity
• Trigonometry - Law of cosines

The final result gives us the Compton scattering equation:

<math>\lambda' - \lambda = \frac{h}{m_e c}(1-\cos{\theta})</math>

where

<math>\lambda </math> is the wavelength of the photon before scattering,

<math>\lambda' </math> is the wavelength of the photon after scattering,

m_e is the mass of the electron,

θ is the angle by which the photon's heading changes,

h is Planck's constant, and

c is the speed of light.

h/(m_ec)=2.43×10^-12 meters, is known as the Compton wavelength.

Derivation

Begin with energy and momentum conservation:

<math>E_\gamma + E_e = E_{\gamma^\prime} + E_{e^\prime} \quad \quad (1) \,</math>

<math>\vec p_\gamma = \vec{p}_{\gamma^\prime} + \vec{p}_{e^\prime} \quad \quad \quad \quad \quad (2) \,</math>

where

<math>E_\gamma \,</math> and <math>p_\gamma \,</math> are the energy and momentum of the photon and

<math>E_e \,</math> and <math>p_e \,</math> are the energy and momentum of the electron.

Solving (1)

Now we fill in for the energy part:

<math>E_{\gamma} + E_{e} = E_{\gamma'} + E_{e'}\,</math>

<math>hf + mc^2 = hf' + \sqrt{(p_{e'}c)^2 + (mc^2)^2}\,</math>

We solve this for p_e':

<math>(hf + mc^2-hf')^2 = (p_{e'}c)^2 + (mc^2)^2\,</math>

<math>\frac{(hf + mc^2-hf')^2-m^2c^4}{c^2}= p_{e'}^2 \quad \quad \quad \quad \quad (3) \,</math>

Solving (2)

Rearrange equation (2)

<math>\vec{p}_{e'} = \vec{p}_\gamma - \vec{p}_{\gamma'} \,</math>

and square it to see

<math>p_{e'}^2 = (\vec{p}_\gamma - \vec{p}_{\gamma'}) \cdot (\vec{p}_\gamma - \vec{p}_{\gamma'})</math>

<math>p_{e'}^2 = p_{\gamma}^2 + p_{\gamma'}^2 - 2\vec{p_{\gamma}} \cdot \vec{p_{\gamma'}}</math>

<math>p_{e'}^2 = p_\gamma^2 + p_{\gamma'}^2 - 2|p_{\gamma}||p_{\gamma'}|\cos(\theta) \,</math>

<math>p_{e'}^2 = \left(\frac{h f}{c}\right)^2 + \left(\frac{h f'}{c}\right)^2 - 2\left( \frac{hf}{c} \right) \left(\frac{h f'}{c} \right) \cos{\theta} \quad \quad \quad (4) </math>

Putting it together

Then we have two equations for <math>p_{e'}^2</math> (eq 3 & 4), which we equate:

<math> \left(\frac{h f}{c}\right)^2 + \left(\frac{h f'}{c}\right)^2 - \frac{2h^2 ff'\cos{\theta}}{c^2} = \frac{(hf + mc^2-hf')^2 -m^2c^4}{c^2} \,</math>

Now, one simplifies. First by multiplying both sides by c²:

<math>h^2 f^2 + h^2 f'^2 - 2h^2 ff' \cos \theta = (hf + mc^2 - hf')^2 - m^2c^4 . \,</math>

Next, multiply out the right-hand side:

<math>h^2f^2+h^2f'^2-2h^2ff'\cos{\theta} = h^2f^2+m^2c^4+h^2f'^2-2h^2ff'+2h(f-f')mc^2 -m^2c^4 .\,</math>

A few terms cancel from both sides, so we have

<math> -2h^2ff'\cos{\theta} = -2h^2ff'+2h(f-f')mc^2 .\,</math>

Then divide both sides by '<math>-2h</math>' to see

<math>hff'\cos{\theta} = hff'-(f-f')mc^2 \,</math>

<math>(f-f')mc^2 = hff'(1-\cos{\theta}) .\,</math>

Now divide both sides by <math>mc^2</math> and then by <math>ff^\prime</math>:

<math>\frac{f-f^\prime}{f f^\prime} = \frac{h}{mc^2}\left(1-\cos \theta \right) . \,</math>

Now the left-hand side can be rewritten as simply

<math> \frac{1}{f^\prime} - \frac{1}{f} = \frac{h}{mc^2}\left(1-\cos \theta \right) \,</math>

This is equivalent to the Compton scattering equation, but it is usually written using <math>\lambda</math>'s rather than <math>f</math>'s. To make that switch use

<math>f=\frac{c}{\lambda} \,</math>

so that finally,

<math>\lambda'-\lambda = \frac{h}{mc}(1-\cos{\theta}) \, </math>

Applications

Compton scattering

Compton scattering is of prime importance to radiobiology, as it happens to be the most probable interaction of high energy X rays with atomic nuclei in living beings and is applied in radiation therapy.

In material physics, Compton scattering can be used to probe the wave function of the electrons in matter in the momentum representation.

Compton Scatter is an important effect in Gamma spectroscopy which gives rise to the Compton edge, as it is possible for the gamma rays to scatter out of the detectors used. Compton suppression is used to detect stray scatter gamma rays to counteract this effect.

Inverse Compton scattering

Inverse Compton scattering is important in astrophysics. In X-ray astronomy, the accretion disk surrounding a black hole is believed to produce a thermal spectrum. The lower energy photons produced from this spectrum are scattered to higher energies by relativistic electrons in the surrounding corona. This is believed to cause the power law component in the X-ray spectra (0.2-10 keV) of accreting black holes.

The effect is also observed when photons from the Cosmic microwave background move through the hot gas surrounding a galaxy cluster. The CMB photons are scattered to higher energies by the electrons in this gas, resulting in the Sunyaev-Zel'dovich effect.

See also

• Thomson scattering
• Klein-Nishina formula
• Photoelectric effect
• Pair production
• Timeline of cosmic microwave background astronomy
• Peter Debye
• Walther Bothe
• List of astronomical topics
• List of physics topics
• Washington University in St. Louis (Site of discovery)

External links

• Compton Effect (PDF file) by Michael Brandl for Project PHYSNET.
• A Quantum Theory of the Scattering of X-Rays by Light Elements - the original 1923 Physical Review paper by Arthur H. Compton (on the AIP website).cs:Comptonův jev

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