Compton wavelength

The reduced Compton wavelength ${\displaystyle \lambda \!\!\!{\bar {}}}$  (barred lambda) of a particle is defined as its Compton wavelength divided by 2π:

${\displaystyle \lambda \!\!\!{\bar {}}={\frac {\lambda }{2\pi }}={\frac {\hbar }{mc}},}$ 

where ħ is the reduced Planck constant.

The inverse reduced Compton wavelength is a natural representation for mass on the quantum scale, and as such, it appears in many of the fundamental equations of quantum mechanics.^{[citation needed]} The reduced Compton wavelength appears in the relativistic Klein–Gordon equation for a free particle: $${\displaystyle \mathbf {\nabla } ^{2}\psi -{\frac {1}{c^{2}}}{\frac {\partial ^{2}}{\partial t^{2}}}\psi =\left({\frac {mc}{\hbar }}\right)^{2}\psi .}$$ 

It appears in the Dirac equation (the following is an explicitly covariant form employing the Einstein summation convention): $${\displaystyle -i\gamma ^{\mu }\partial _{\mu }\psi +\left({\frac {mc}{\hbar }}\right)\psi =0.}$$ 

The reduced Compton wavelength is also present in the Schrödinger equation for an electron in a hydrogen-like atom, although this is not readily apparent in traditional representations of the equation. The following is the traditional representation of the Schrödinger equation: $${\displaystyle i\hbar {\frac {\partial }{\partial t}}\psi =-{\frac {\hbar ^{2}}{2m}}\nabla ^{2}\psi -{\frac {1}{4\pi \epsilon _{0}}}{\frac {Ze^{2}}{r}}\psi .}$$ 

Dividing through by ħc and rewriting in terms of the fine-structure constant, one obtains: $${\displaystyle {\frac {i}{c}}{\frac {\partial }{\partial t}}\psi =-{\frac {\lambda \!\!\!{\bar {}}}{2}}\nabla ^{2}\psi -{\frac {\alpha Z}{r}}\psi .}$$ 

The reduced Compton wavelength is a natural representation of mass on the quantum scale and is used in equations that pertain to inertial mass, such as the Klein–Gordon and Schrödinger equations.^{[7]: 18–22}

Equations that pertain to the wavelengths of photons interacting with mass use the non-reduced Compton wavelength. A particle of mass m has a rest energy of E = mc². The Compton wavelength for this particle is the wavelength of a photon of the same energy. For photons of frequency f, energy is given by $${\displaystyle E=hf={\frac {hc}{\lambda }}=mc^{2},}$$  which yields the Compton wavelength formula if solved for λ.

Typical atomic lengths, wave numbers, and areas in physics can be related to the reduced Compton wavelength for the electron (⁠${\displaystyle \textstyle \lambda \!\!\!{\bar {}}_{\text{e}}\equiv {\tfrac {\lambda _{\text{e}}}{2\pi }}\simeq \mathrm {386~fm} }$ ⁠) and the electromagnetic fine-structure constant (⁠${\displaystyle \alpha \simeq {\tfrac {1}{137}}}$ ⁠).

The classical electron radius is about 3 times larger than the proton radius, and is written: $${\displaystyle r_{\text{e}}=\alpha \lambda \!\!\!{\bar {}}_{\text{e}}\simeq 2.82~{\textrm {fm}}}$$ 

The Bohr radius is related to the Compton wavelength by: $${\displaystyle a_{0}={\frac {\lambda \!\!\!{\bar {}}_{\text{e}}}{\alpha }}\simeq 5.29\times 10^{4}~{\textrm {fm}}}$$ 

The angular wavenumber of a photon with one hartree (the atomic unit of energy ⁠${\displaystyle E_{\text{h}}=4\pi \hbar cR_{\infty }}$ ⁠, where ⁠${\displaystyle R_{\infty }}$ ⁠ is the Rydberg constant), being (approximately) the negative potential energy of the electron in the hydrogen atom, and twice the energy needed to ionize it, is: $${\displaystyle {\frac {\hbar c}{E_{\text{h}}}}={\frac {1}{4\pi R_{\infty }}}={\frac {\lambda \!\!\!{\bar {}}_{\text{e}}}{\alpha ^{2}}}\simeq 7.25~{\textrm {nm}}}$$ 

This yields the sequence: $${\displaystyle \alpha ^{-1}r_{\text{e}}=\lambda \!\!\!{\bar {}}_{\text{e}}=\alpha a_{0}=\alpha ^{2}{\hbar c/E_{\text{h}}}.}$$ 

For fermions, the classical (electromagnetic) radius sets the cross-section of electromagnetic interactions of a particle. For example, the cross-section for Thomson scattering of a photon from an electron is equal to $${\displaystyle \sigma _{\mathrm {e} }={\frac {8\pi }{3}}r_{\text{e}}{}^{2}\simeq \mathrm {66.5~fm^{2}} ,}$$  which is roughly the same as the cross-sectional area of an iron-56 nucleus.

A geometrical origin of the Compton wavelength has been demonstrated using semiclassical equations describing the motion of a wavepacket.^[8] In this case, the Compton wavelength is equal to the square root of the quantum metric, a metric describing the quantum space: ⁠${\displaystyle {\sqrt {g_{kk}}}=\lambda _{\mathrm {C} }}$ ⁠.

• de Broglie wavelength
• Planck–Einstein relation

• Length Scales in Physics: the Compton Wavelength