Difference between revisions of "Fermi's Golden Rule"
(→Statement) |
(→Statement) |
||
| Line 17: | Line 17: | ||
Fermi golden rule then states that up to the first order perturbation theory, the probability <math>P</math> of finding the system in the continuum states is a linear function of time. This behavior allows the definition of a transition rate with the explicit expression of | Fermi golden rule then states that up to the first order perturbation theory, the probability <math>P</math> of finding the system in the continuum states is a linear function of time. This behavior allows the definition of a transition rate with the explicit expression of | ||
| − | <math>w = \frac{d P}{d t} = \frac{2\pi}{\hbar } |g (E_b )|^2 \rho(E_b)/ | + | <math>w = \frac{d P}{d t} = \frac{2\pi}{\hbar } |g (E_b )|^2 \rho(E_b)/tag {1}</math>. |
The characteristic feature is that <math>w</math> is proportional to the density of state of the continuum and the squared modulus of the coupling strength both at <math>E= E_b</math>. | The characteristic feature is that <math>w</math> is proportional to the density of state of the continuum and the squared modulus of the coupling strength both at <math>E= E_b</math>. | ||
Revision as of 19:10, 16 February 2017
J. M. Zhang Fujian Provincial Key Laboratory of Quantum Manipulation and New Energy Materials, College of Physics and Energy, Fujian Normal University, Fuzhou 350007, China and Fujian Provincial Collaborative Innovation Center for Optoelectronic Semiconductors and Efficient Devices, Xiamen, 361005, China.
1 Deftnition
Fermi’s golden rule gives an approximate prediction of the decay rate of a discrete level imbedded in and coupled to a continuum. As a nontrivial and practical result within the first order time- dependent perturbation theory, it finds widespread use in all branches of physics. Sometimes, it appears under the guise of other names. For example, the so-called Born approximation in scattering theory is a Fermi’s golden rule result in essence.
2 History
The rule was first derived by Dirac [1, 2]. However, it was Fermi who conferred the title golden on the rule [3], possibly because of its instrumental role in his most cherished theory of Beta decay [4, 5].
3 Statement
The following scenario is quite common in quantum dynamics. Initially the system is in some discrete state [math]\left |b \right \rangle[/math], which is an eigenstate of the unperturbed Hamiltonian [math]H_{0}[/math] with eigenenergy [math]H_{b}[/math]. Besides this discrete state, [math]H_{0}[/math] has a set of eigenstates {[math]\left |n \right \rangle[/math]}, with eigenenergies [math]{E_{n}}[/math] which form a continuum. The discrete state [math]\left |b \right \rangle[/math] is coupled to the continuum states {[math]\left |n \right \rangle[/math]} by a perturbation [math]V[/math], which induces the transition from the former to the latter. The coupling strengthes are denoted as [math]g_n = \langle n | V | b \rangle[/math]. In many cases, both [math]E_n[/math] and [math]g_n[/math] are slowly and smoothly varying functions of [math]n[/math]. Hence, it is legitimate to introduce the coupling function [math]g(E)[/math] such that [math]g(E_n) = g_n [/math], and the density of states [math]\rho(E)[/math] such that [math]\rho(E) d E [/math] is the number of continuum states in the interval [math][E, E + d E ][/math].
Fermi golden rule then states that up to the first order perturbation theory, the probability [math]P[/math] of finding the system in the continuum states is a linear function of time. This behavior allows the definition of a transition rate with the explicit expression of
[math]w = \frac{d P}{d t} = \frac{2\pi}{\hbar } |g (E_b )|^2 \rho(E_b)/tag {1}[/math].
The characteristic feature is that [math]w[/math] is proportional to the density of state of the continuum and the squared modulus of the coupling strength both at [math]E= E_b[/math].
