Английская Википедия:Compton wavelength
Шаблон:Short description Шаблон:Use American English The Compton wavelength is a quantum mechanical property of a particle, defined as the wavelength of a photon the energy of which is the same as the rest energy of that particle (see mass–energy equivalence). It was introduced by Arthur Compton in 1923 in his explanation of the scattering of photons by electrons (a process known as Compton scattering).
The standard Compton wavelength Шаблон:Mvar of a particle of mass <math>m</math> is given by <math display="block"> \lambda = \frac{h}{m c}, </math> where Шаблон:Mvar is the Planck constant and Шаблон:Mvar is the speed of light. The corresponding frequency Шаблон:Mvar is given by <math display="block">f = \frac{m c^2}{h},</math> and the angular frequency Шаблон:Mvar is given by <math display="block"> \omega = \frac{m c^2}{\hbar}.</math>
The CODATA 2018 value for the Compton wavelength of the electron is Шаблон:Math.[1] Other particles have different Compton wavelengths.
Reduced Compton wavelength
The reduced Compton wavelength Шаблон:Math (barred lambda, denoted below by <math>\bar\lambda</math>) is defined as the Compton wavelength divided by Шаблон:Math:
- <math>\bar\lambda = \frac{\lambda}{2 \pi} = \frac{\hbar}{m c},</math>
where Шаблон:Math is the reduced Planck constant.
Role in equations for massive particles
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. The reduced Compton wavelength appears in the relativistic Klein–Gordon equation for a free particle: <math display="block"> \mathbf{\nabla}^2\psi-\frac{1}{c^2}\frac{\partial^2}{\partial t^2}\psi = \left(\frac{m c}{\hbar} \right)^2 \psi.</math>
It appears in the Dirac equation (the following is an explicitly covariant form employing the Einstein summation convention): <math display="block">-i \gamma^\mu \partial_\mu \psi + \left( \frac{m c}{\hbar} \right) \psi = 0.</math>
The reduced Compton wavelength is also present in Schrödinger's equation, although this is not readily apparent in traditional representations of the equation. The following is the traditional representation of Schrödinger's equation for an electron in a hydrogen-like atom: <math display="block"> 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.</math>
Dividing through by <math>\hbar c</math> and rewriting in terms of the fine-structure constant, one obtains: <math display="block">\frac{i}{c}\frac{\partial}{\partial t}\psi=-\frac{\bar{\lambda}}{2} \nabla^2\psi - \frac{\alpha Z}{r} \psi.</math>
Distinction between reduced and non-reduced
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's equations.[2]Шаблон:Rp
Equations that pertain to the wavelengths of photons interacting with mass use the non-reduced Compton wavelength. A particle of mass Шаблон:Math has a rest energy of Шаблон:Math. The Compton wavelength for this particle is the wavelength of a photon of the same energy. For photons of frequency Шаблон:Math, energy is given by <math display="block"> E = h f = \frac{h c}{\lambda} = m c^2, </math> which yields the Compton wavelength formula if solved for Шаблон:Math.
Limitation on measurement
The Compton wavelength expresses a fundamental limitation on measuring the position of a particle, taking into account quantum mechanics and special relativity.[3]
This limitation depends on the mass Шаблон:Math of the particle. To see how, note that we can measure the position of a particle by bouncing light off it – but measuring the position accurately requires light of short wavelength. Light with a short wavelength consists of photons of high energy. If the energy of these photons exceeds Шаблон:Math, when one hits the particle whose position is being measured the collision may yield enough energy to create a new particle of the same type.Шаблон:Citation needed This renders moot the question of the original particle's location.
This argument also shows that the reduced Compton wavelength is the cutoff below which quantum field theory – which can describe particle creation and annihilation – becomes important. The above argument can be made a bit more precise as follows. Suppose we wish to measure the position of a particle to within an accuracy Шаблон:Math. Then the uncertainty relation for position and momentum says that <math display="block">\Delta x\,\Delta p\ge \frac{\hbar}{2},</math> so the uncertainty in the particle's momentum satisfies <math display="block">\Delta p \ge \frac{\hbar}{2\Delta x}.</math>
Using the relativistic relation between momentum and energy Шаблон:Math, when Шаблон:Math exceeds Шаблон:Math then the uncertainty in energy is greater than Шаблон:Math, which is enough energy to create another particle of the same type. But we must exclude this greater energy uncertainty. Physically, this is excluded by the creation of one or more additional particles to keep the momentum uncertainty of each particle at or below Шаблон:Math. In particular the minimum uncertainty is when the scattered photon has limit energy equal to the incident observing energy. It follows that there is a fundamental minimum for Шаблон:Math: <math display="block">\Delta x \ge \frac{1}{2} \left(\frac{\hbar}{mc} \right).</math>
Thus the uncertainty in position must be greater than half of the reduced Compton wavelength Шаблон:Math.
Relationship to other constants
Typical atomic lengths, wave numbers, and areas in physics can be related to the reduced Compton wavelength for the electron Шаблон:Nowrap{2\pi}\simeq 386~\textrm{fm}</math>)}} and the electromagnetic fine-structure constant Шаблон:Nowrap
The Bohr radius is related to the Compton wavelength by: <math display="block">a_0 = \frac{1}{\alpha}\left(\frac{\lambda_\text{e}}{2\pi}\right) = \frac{\bar{\lambda}_\text{e}}{\alpha} \simeq 137\times\bar{\lambda}_\text{e}\simeq 5.29\times 10^4~\textrm{fm} </math>
The classical electron radius is about 3 times larger than the proton radius, and is written: <math display="block">r_\text{e} = \alpha\left(\frac{\lambda_\text{e}}{2\pi}\right) = \alpha\bar{\lambda}_\text{e} \simeq\frac{\bar{\lambda}_\text{e}}{137}\simeq 2.82~\textrm{fm}</math>
The Rydberg constant, having dimensions of linear wavenumber, is written: <math display="block">\frac{1}{R_\infty}=\frac{2\lambda_\text{e}}{\alpha^2} \simeq 91.1~\textrm{nm}</math> <math display="block">\frac{1}{2\pi R_\infty} = \frac{2}{\alpha^2}\left(\frac{\lambda_\text{e}}{2\pi}\right) = 2 \frac{\bar{\lambda}_\text{e}}{\alpha^2} \simeq 14.5~\textrm{nm}</math>
This yields the sequence: <math display="block">r_{\text{e}} = \alpha \bar{\lambda}_{\text{e}} = \alpha^2 a_0 = \alpha^3 \frac{1}{4\pi R_\infty}.</math>
For fermions, the reduced Compton wavelength sets the cross-section of interactions. For example, the cross-section for Thomson scattering of a photon from an electron is equal toШаблон:Clarify <math display="block">\sigma_\mathrm{T} = \frac{8\pi}{3}\alpha^2\bar{\lambda}_\text{e}^2 \simeq 66.5~\textrm{fm}^2 ,</math> which is roughly the same as the cross-sectional area of an iron-56 nucleus. For gauge bosons, the Compton wavelength sets the effective range of the Yukawa interaction: since the photon has no mass, electromagnetism has infinite range.
The Planck mass is the order of mass for which the Compton wavelength and the Schwarzschild radius <math> r_{\rm S} = 2 G M /c^2 </math> are the same, when their value is close to the Planck length (<math>l_{\rm P}</math>). The Schwarzschild radius is proportional to the mass, whereas the Compton wavelength is proportional to the inverse of the mass. The Planck mass and length are defined by:
<math display="block">m_{\rm P} = \sqrt{\hbar c/G}</math> <math display="block">l_{\rm P} = \sqrt{\hbar G /c^3}.</math>
Geometrical interpretation
A geometrical origin of the Compton wavelength has been demonstrated using semiclassical equations describing the motion of a wavepacket.[4] In this case, the Compton wavelength is equal to the square root of the quantum metric, a metric describing the quantum space: <math>\sqrt{g_{kk}}=\lambda_\mathrm{C}</math>
See also
References
External links
de:Compton-Effekt#Compton-Wellenlänge
- ↑ CODATA 2018 value for Compton wavelength for the electron from NIST.
- ↑ Greiner, W., Relativistic Quantum Mechanics: Wave Equations (Berlin/Heidelberg: Springer, 1990), pp. 18–22.
- ↑ Шаблон:Cite journal
- ↑ Шаблон:Cite journal
