What is Compton?
Compton is the scattering of photons by a charged particle (electron).
Do you know what is light and how does it interact with matter? After the success of electromagnetic radiation in the 19th century, the light was considered a wave. It means the light was a self-propagating ripple in the electromagnetic field.
However, in 1905, Einstein introduced the Photoelectric effect that considered light as a bunch of photons instead of waves. Initially, people didn’t believe in the photon theory of light; therefore, to make people believe in this theory, in 1922, Arthur Compton, worked on X-ray scattering, which was called Compton scattering. So, what is Compton scattering?
Compton Scattering
In 1912, Max Von Laue said that X-rays perform diffraction but the diffraction occurs in light only. If this is the case, then X-rays should be considered light and they have a wave nature.
However, if we go to the past, in 1905, Einstein considered light as a bunch of small packets or quanta called photons. Since X-rays and light have the same nature, so if the light has a particle nature, X-rays must have a particle nature too.
Now, a person arrives named Arthur Holly Compton. In his experiment, named Compton scattering (or the effect called Compton effect), he said that when X-rays and electrons interact with each other, it seems like two balls are colliding with each other.
For his experiment in 1927, Arthur was conferred Nobel Prize. Now, let us understand the Compton effect in detail.
Compton Effect
In the experiment, Arthur Compton considered a molybdenum X-ray tube from which a beam of X-rays of sharp wavelength (0.71 Å) when passed onto the graphite target, it scatters in different directions and the wavelength varies according to the scattering angle.
To study the X-rays, Compton employed Bragg’s spectrometer that can rotate around the graphite target, so why did he consider this instrument? It’s because we have to determine the Compton wavelength value and the spectrometer helps us determine the wavelength of electromagnetic waves falling on it.
Since the wavelength varies with the scattering angle, so the spectrometer rotates around the target to determine the varying wavelengths.
The scattering of rays continues; however, a case comes when the maximum part of wavelength λ0 when reaches the target changes to λ1 and that change is because of the scattering angle Θ. Compton observed that the difference between λ1 and λ0 totally depends upon the angle Θ. So, we arrive at the equation as:
λ1 - λ0 = h/mc(1 - Cos Θ)
Here,
λ1 - λ0 = difference in the wavelength
m = rest mass
c = speed of light ,i.e., 3 x 10⁸ m/s
h = Planck’s constant = 6.626 x 10⁻³⁴ J/s
Now, let’s derive the above equation mathematically:
Compton Wavelength
Let’s suppose that a photon collides with an electron. Initially, its kinetic energy and momentum are E0’ and p0’, when it collides with an electron along the x-axis, its kinetic energy decreases and changes to E1’ momentum to p1’, and the wavelength becomes '. The angle made by the scattering photon with the x-axis is Θ.
However, an electron gains momentum ‘p’ and kinetic energy ‘k’, and the angle made by an electron with the x-axis is Ф.
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We know that momentum remains conserved at all the axes. Here, we will apply the law of conservation of momentum at x and the y-axis:
Along the X-axis
p0 = p1 Cos Θ + p Cos Ф
⇒ p0 - p1 Cos Θ= p Cos Ф……(1)
Now, along the y-axis, p0 becomes zero and dividing the component of the momentum of the electron and the photon along the y-axis will be:
0 = p1 Sin Θ - p Sin Ф
p1 Sin Θ = p Sin Ф …(2)
Now, squaring equation (1) & (2), we get:
From equation (1):
(p0 - p1 CosΘ)² = p² Cos²Ф
= p0² + p1²CosΘ + 2p0p1 CosΘ = p² Cos²Ф …….(3)
From equation (2):
p1Sin²Θ = p²Sin²Ф …..(4)
And, adding equations (3) and (4), we get:
po² + p1² CosΘ + 2p0p1 CosΘ + p1Sin²Θ = p²Cos²Ф + p²Sin²Ф
po² + p1² + 2p0p1CosΘ = p² ……(5)
Now, applying the law of conservation of energy:
E0 = E1 + k
E0 - E1 = k
cp0 - cp1 = k
⇒ p0 - p1 = k/c…..(5)
The momentum of a photon is given by:
p = h/λ = hf/λf = E/c
So, we represent the energy of a photon as;
E = pc
The relation among the relativistic energy, momentum, and the rest mass of the electron after the collision is:
(k + mc²)² = p²c² + m²c⁴
⇒ k² + m²c⁴ + 2kmc² = p²c² + m²c⁴
⇒ k² + 2kmc² = p²c²
⇒ k²/c² + 2km = p² ……(6)
From eq (5) in (6):
(p0 - p1)² + 2km = p² …..(7)
From eq (5) in (6):
(p0 - p1)² + 2km = p0² + p1² - 2p0p1 CosΘ
On solving, we get the equation as:
1/p1 - 1/p0 = 1/mc (1 - CosΘ)
Now, putting p = λ/h
⇒ λ0 - λ1 = h/mc (1 - Cos Θ)
The Compton wavelength value of an electron is 0.243 Å.
FAQs on Compton Wavelength
1. What is the Compton Wavelength and what does it represent?
The Compton Wavelength is a fundamental quantum mechanical property of a particle. It represents the wavelength of a photon that has the same energy as the rest-mass energy of that specific particle. Essentially, it defines the length scale at which a particle's quantum nature becomes significant, particularly in high-energy interactions like scattering.
2. What is the Compton Effect and how does it relate to the Compton Wavelength?
The Compton Effect, also known as Compton scattering, is the phenomenon where a high-frequency photon (like an X-ray) loses energy and increases in wavelength after colliding with a charged particle, typically an electron. The Compton Wavelength is a crucial constant in the formula that quantifies this exact change in the photon's wavelength during the scattering process.
3. What is the formula for Compton Wavelength and what does each variable mean?
The formula for the Compton wavelength (λc) of any particle is given by:
- λc = h / (m₀c)
Where:
- h is Planck's constant (approximately 6.626 x 10⁻³⁴ J·s).
- m₀ is the rest mass of the particle in question (e.g., the mass of an electron at rest).
- c is the speed of light in a vacuum (approximately 3 x 10⁸ m/s).
4. What is the accepted value of the Compton Wavelength for an electron?
For an electron, the Compton Wavelength is a fundamental physical constant. By substituting the electron's rest mass (9.109 × 10⁻³¹ kg) into the formula, its value is calculated to be approximately 2.426 × 10⁻¹² metres. This is often expressed in other units as 0.0243 angstroms (Å) or 0.00243 nanometres (nm).
5. How is the Compton Wavelength different from the de Broglie Wavelength?
While both relate to the wave-particle duality, they describe different concepts:
- The Compton Wavelength is a fixed value for a given particle, dependent only on its rest mass. It is associated with the wavelength change of a photon during scattering.
- The de Broglie Wavelength is a variable property of a particle, dependent on its momentum (and therefore its velocity). It describes the wave-like nature of the moving particle itself.
6. Why is the Compton Effect generally not observed with visible light?
The Compton Effect is not noticeable with visible light because its photons have very low energy and long wavelengths compared to the Compton wavelength of an electron. The shift in wavelength is only significant when the incident photon's wavelength is comparable to or smaller than the particle's Compton wavelength. For visible light (400-700 nm), the change is so minuscule that it is practically undetectable.
7. How does the Compton Wavelength of a proton compare to that of an electron?
The Compton wavelength is inversely proportional to the particle's rest mass. Since a proton is approximately 1836 times more massive than an electron, its Compton wavelength is about 1836 times smaller than the electron's. This extremely small wavelength makes the Compton Effect much more difficult to observe for protons and other heavier particles.
8. Under what conditions is the Compton shift in wavelength zero?
The Compton shift (the change in a photon's wavelength) is zero when the scattering angle is 0°. This physical scenario implies that the photon has passed the electron without any interaction or energy transfer. Consequently, its path is not deviated, and its wavelength remains unchanged. A non-zero shift requires a collision that alters the photon's direction.
