--- title: "Fermi's golden rule" firstLetter: "F" publishDate: 2021-07-10 categories: - Physics - Quantum mechanics - Optics date: 2021-07-03T14:41:11+02:00 draft: false markup: pandoc --- # Fermi's golden rule In quantum mechanics, **Fermi's golden rule** expresses the transition rate between two states of a system, when a sinusoidal perturbation is applied at the resonance frequency $\omega = E_g / \hbar$ of the energy gap $E_g$. The main conclusion is that the rate is independent of time. From [time-dependent perturbation theory](/know/concept/time-dependent-perturbation-theory/), we know that the transition probability for a particle in state $\ket{a}$ to go to $\ket{b}$ is as follows for a periodic perturbation at frequency $\omega$: $$\begin{aligned} P_{ab} = \frac{|V_{ba}|^2}{\hbar^2} \frac{\sin^2\!\big((\omega_{ba} - \omega) t / 2\big)}{(\omega_{ba} - \omega)^2} \end{aligned}$$ Where $\omega_{ba} \equiv (E_b - E_a) / \hbar$. If we assume that $\ket{b}$ irreversibly absorbs an unlimited number of particles, then we can interpret $P_{ab}$ as the "amount" of the current particle that has transitioned since the last period $2 \pi n / (\omega_{ba} \!-\! \omega)$. For generality, let $E_b$ be the center of a state continuum with width $\Delta E$. In that case, $P_{ab}$ must be modified as follows, where $\rho(E_x)$ is the destination's [density of states](/know/concept/density-of-states/): $$\begin{aligned} P_{ab} &= \frac{|V_{ba}|^2}{\hbar^2} \int_{E_b - \Delta E / 2}^{E_b + \Delta E / 2} \frac{\sin^2\!\big((\omega_{xa} - \omega) t / 2\big)}{(\omega_{xa} - \omega)^2} \:\rho(E_x) \dd{E_x} \end{aligned}$$ If $E_b$ is not in a continuum, then $\rho(E_x) = \delta(E_x - E_b)$. The integrand is a sharp sinc-function around $E_x$. For large $t$, it is so sharp that we can take out $\rho(E_x)$. In that case, we also simplify the integration limits. Then we substitute $x \equiv (\omega_{xa}\!-\!\omega) / 2$ to get: $$\begin{aligned} P_{ab} &\approx \frac{2}{\hbar} |V_{ba}|^2 \rho(E_b) \int_{-\infty}^\infty \frac{\sin^2(x t)}{x^2} \:dx \end{aligned}$$ This definite integral turns out to be $\pi |t|$, so we find, because clearly $t > 0$: $$\begin{aligned} P_{ab} &= \frac{2 \pi}{\hbar} |V_{ba}|^2 \rho(E_b) \: t \end{aligned}$$ The transition rate $R_{ab}$, i.e. the number of particles per unit time, then takes this form: $$\begin{aligned} \boxed{ R_{ab} = \pdv{P_{ab}}{t} = \frac{2 \pi}{\hbar} |V_{ba}|^2 \rho(E_b) } \end{aligned}$$ Note that the $t$-dependence has disappeared, and all that remains is a constant factor involving $E_b = E_a \!+\! \hbar \omega$, where $\omega$ is the resonance frequency. ## References 1. D.J. Griffiths, D.F. Schroeter, *Introduction to quantum mechanics*, 3rd edition, Cambridge.