Quantum excitation (accelerator physics)

Template:Short description Quantum excitation is the effect in circular accelerators or storage rings whereby the discreteness of photon emission causes the charged particles (typically electrons) to undergo a random walk or diffusion process.

An electron moving through a magnetic field emits radiation called synchrotron radiation. The expected amount of radiation can be calculated using the classical power. Considering quantum mechanics, however, this radiation is emitted in discrete packets of photons. For this description, the distribution of the number of emitted photons and also the energy spectrum for the electron should be determined instead.

In particular, the normalized power spectrum emitted by a charged particle moving in a bending magnet is given by

${\displaystyle S(\xi )=\frac{9\sqrt{3}}{8\pi }\xi {\displaystyle \underset{\xi }{\overset{\mathrm{\infty }}{\int }}}{K}_{5/3}(\overline{\xi })d\overline{\xi }.}$

This result was originally derived by Dmitri Ivanenko and Arseny Sokolov and independently by Julian Schwinger in 1949.^[1]

Dividing each power of this power spectrum by the energy yields the photon flux:

${\displaystyle F(\xi )=\frac{1}{\xi }S(\xi )=\frac{9\sqrt{3}}{8\pi }{\displaystyle \underset{\xi }{\overset{\mathrm{\infty }}{\int }}}{K}_{5/3}(\overline{\xi })d\overline{\xi }.}$

The photon flux from this normalized power spectrum (of all energies) is then

${\displaystyle {\dot{N}}_{norm}=\frac{9\sqrt{3}}{8\pi }{\displaystyle \underset{\xi =0}{\overset{\mathrm{\infty }}{\int }}}{\displaystyle \underset{\overline{\xi }=\xi }{\overset{\mathrm{\infty }}{\int }}}{K}_{5/3}(\overline{\xi })d\overline{\xi }d\xi =\mathrm{\Gamma }(11/6)\mathrm{\Gamma }(1/6)\frac{9\sqrt{3}}{8\pi }=\frac{15\sqrt{3}}{8}.}$

The fact that the above photon flux integral is finite implies discrete photon emission. It is a Poisson process. The emission rate isTemplate:RTemplate:RTemplate:R

${\displaystyle r_{\gamma }=\frac{5\sqrt{3}}{6}\frac{r_e{e}_0{\beta }^4\gamma }{\hslash |\rho |}\text{ photons/sec}.}$

For a travelled distance ${\displaystyle \mathrm{\Delta }s}$ at a speed close to ${\displaystyle c}$ (${\displaystyle \beta \approx 1}$), the average number of emitted photons by the particle can be expressed as

${\displaystyle ⟨n_{\gamma }⟩=\frac{5\sqrt{3}}{6}\frac{r_e{e}_0\gamma }{\hslash |\rho |}\frac{\mathrm{\Delta }s}{c}=\frac{5\sqrt{3}}{6}\frac{\alpha \gamma }{|\rho |}\mathrm{\Delta }s,}$

where ${\displaystyle \alpha }$ is the fine-structure constant. The probability that Template:Mvar photons are emitted over ${\displaystyle \mathrm{\Delta }s}$ is

${\displaystyle Pr(n_{\gamma }=k)=\frac{⟨n_{\gamma }{⟩}^k}{k!}{e}^{-⟨n_{\gamma }⟩}.}$

The photon number curve and the power spectrum curve intersect at the critical energy

${\displaystyle u_c=\frac{3c\hslash {\gamma }^3}{2\rho },}$

where Template:Mvar, Template:Mvar is the total energy of the charged particle, Template:Mvar is the radius of curvature, Template:Math the classical electron radius, Template:Math the particle rest mass energy, Template:Mvar the reduced Planck constant, and Template:Mvar the speed of light.

The mean of the quantum energy is given by ${\displaystyle ⟨u⟩=\frac{8}{15\sqrt{3}}{u}_c}$ and impacts mainly the radiation damping. However, the particle motion perturbation (diffusion) is mainly related by the variance of the quantum energy ${\displaystyle ⟨u^2⟩}$ and leads to an equilibrium emittance. The diffusion coefficient at a given position Template:Mvar is given by

${\displaystyle d(s)=\frac{55}{48\sqrt{3}}\alpha {\left(\frac{\hslash }{m_{e}c}\right)}^2\frac{{\gamma }^5}{|\rho (s){|}^3}.}$ ^[2]

For an early analysis of the effect of quantum excitation on electron beam dynamics in storage rings, see the article by Matt Sands.^[3]

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