Einstein–Brillouin–Keller method

Template:Short description The Einstein–Brillouin–Keller (EBK) method is a semiclassical technique (named after Albert Einstein, Léon Brillouin, and Joseph B. Keller) used to compute eigenvalues in quantum-mechanical systems. EBK quantization is an improvement from Bohr-Sommerfeld quantization which did not consider the caustic phase jumps at classical turning points.^[1][2] This procedure is able to reproduce exactly the spectrum of the 3D harmonic oscillator, particle in a box, and even the relativistic fine structure of the hydrogen atom.^[3]

In 1976–1977, Michael Berry and M. Tabor derived an extension to Gutzwiller trace formula for the density of states of an integrable system starting from EBK quantization.^[4][5]

There have been a number of recent results on computational issues related to this topic, for example, the work of Eric J. Heller and Emmanuel David Tannenbaum using a partial differential equation gradient descent approach.^[6]

Given a separable classical system defined by coordinates ${\displaystyle (q_i,p_i);i\in \{1,2,\cdots ,d\}}$, in which every pair ${\displaystyle (q_i,p_i)}$ describes a closed function or a periodic function in ${\displaystyle q_i}$, the EBK procedure involves quantizing the line integrals of ${\displaystyle p_i}$ over the closed orbit of ${\displaystyle q_i}$:

${\displaystyle I_i=\frac{1}{2\pi }{\displaystyle \oint }{p}_{i}d{q}_i=\hslash (n_i+\frac{{\mu }_i}{4}+\frac{b_i}{2})}$

where ${\displaystyle I_i}$ is the action-angle coordinate, ${\displaystyle n_i}$ is a positive integer, and ${\displaystyle {\mu }_i}$ and ${\displaystyle b_i}$ are Maslov indexes. ${\displaystyle {\mu }_i}$ corresponds to the number of classical turning points in the trajectory of ${\displaystyle q_i}$ (Dirichlet boundary condition), and ${\displaystyle b_i}$ corresponds to the number of reflections with a hard wall (Neumann boundary condition).^[7]

The Hamiltonian of a simple harmonic oscillator is given by

${\displaystyle H=\frac{p^2}{2m}+\frac{m{\omega }^2{x}^2}{2}}$

where ${\displaystyle p}$ is the linear momentum and ${\displaystyle x}$ the position coordinate. The action variable is given by

${\displaystyle I=\frac{2}{\pi }{\displaystyle \underset{0}{\overset{x_0}{\int }}}\sqrt{2mE-m^2{\omega }^2{x}^2}\mathrm{d}x}$

where we have used that ${\displaystyle H=E}$ is the energy and that the closed trajectory is 4 times the trajectory from 0 to the turning point ${\displaystyle x_0=\sqrt{2E/m{\omega }^2}}$.

The integral turns out to be

${\displaystyle E=I\omega }$,

which under EBK quantization there are two soft turning points in each orbit ${\displaystyle {\mu }_x=2}$ and ${\displaystyle b_x=0}$. Finally, that yields

${\displaystyle E=\hslash \omega (n+1/2)}$,

which is the exact result for quantization of the quantum harmonic oscillator.

The Hamiltonian for a non-relativistic electron (electric charge ${\displaystyle e}$) in a hydrogen atom is:

${\displaystyle H=\frac{p_r^2}{2m}+\frac{p_{\phi }^2}{2m{r}^2}-\frac{e^2}{4\pi {ϵ}_{0}r}}$

where ${\displaystyle p_r}$ is the canonical momentum to the radial distance ${\displaystyle r}$, and ${\displaystyle p_{\phi }}$ is the canonical momentum of the azimuthal angle ${\displaystyle \phi }$. Take the action-angle coordinates:

${\displaystyle I_{\phi }=\text{constant}=|L|}$

For the radial coordinate ${\displaystyle r}$:

${\displaystyle p_r=\sqrt{2mE-\frac{L^2}{r^2}+\frac{e^2}{4\pi {ϵ}_{0}r}}}$

${\displaystyle I_r=\frac{1}{\pi }{\displaystyle \underset{r_1}{\overset{r_2}{\int }}}{p}_{r}dr=\frac{m{e}^2}{4\pi {ϵ}_0\sqrt{-2mE}}-|L|}$

where we are integrating between the two classical turning points ${\displaystyle r_1,r_2}$ (${\displaystyle {\mu }_r=2}$)

${\displaystyle E=-\frac{m{e}^4}{32{\pi }^2{ϵ}_0^2(I_r+I_{\phi }{)}^2}}$

Using EBK quantization ${\displaystyle b_r={\mu }_{\phi }=b_{\phi }=0,n_{\phi }=m}$ :

${\displaystyle I_{\phi }=\hslash m;m=0,1,2,\cdots }$

${\displaystyle I_r=\hslash (n_r+1/2);n_r=0,1,2,\cdots }$

${\displaystyle E=-\frac{m{e}^4}{32{\pi }^2{ϵ}_0^2{\hslash }^2(n_r+m+1/2{)}^2}}$

and by making ${\displaystyle n=n_r+m+1}$ the spectrum of the 2D hydrogen atom ^[8] is recovered :

${\displaystyle E_n=-\frac{m{e}^4}{32{\pi }^2{ϵ}_0^2{\hslash }^2(n-1/2{)}^2};n=1,2,3,\cdots }$

Note that for this case ${\displaystyle I_{\phi }=|L|}$ almost coincides with the usual quantization of the angular momentum operator on the plane ${\displaystyle L_z}$. For the 3D case, the EBK method for the total angular momentum is equivalent to the Langer correction.

Template:Portal

• Hamilton–Jacobi equation
• WKB approximation
• Quantum chaos

• Template:Cite book

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