--- title: "Ehrenfest's theorem" sort_title: "Ehrenfest's theorem" date: 2021-02-24 categories: - Quantum mechanics - Physics layout: "concept" --- In quantum mechanics, **Ehrenfest's theorem** gives a general expression for the time evolution of an observable's expectation value $$\expval{\hat{L}}$$. The time-dependent Schrödinger equation is as follows, where prime denotes differentiation with respect to time $$t$$: $$\begin{aligned} \Ket{\psi'} = \frac{1}{i \hbar} \hat{H} \Ket{\psi} \qquad \Bra{\psi'} = - \frac{1}{i \hbar} \Bra{\psi} \hat{H} \end{aligned}$$ Given an observable operator $$\hat{L}$$ and a state $$\Ket{\psi}$$, the time-derivative of the expectation value $$\expval{\hat{L}}$$ is as follows (due to the product rule of differentiation): $$\begin{aligned} \dv{\expval{\hat{L}}}{t} &= \matrixel{\psi}{\hat{L}}{\psi'} + \matrixel{\psi'}{\hat{L}}{\psi} + \matrixel{\psi}{\hat{L}'}{\psi} \\ &= \frac{1}{i \hbar} \matrixel{\psi}{\hat{L}\hat{H}}{\psi} - \frac{1}{i \hbar} \matrixel{\psi}{\hat{H}\hat{L}}{\psi} + \Expval{\dv{\hat{L}}{t}} \end{aligned}$$ The first two terms on the right can be rewritten using a commutator, yielding the general form of Ehrenfest's theorem: $$\begin{aligned} \boxed{ \dv{\expval{\hat{L}}}{t} = \frac{1}{i \hbar} \Expval{[\hat{L}, \hat{H}]} + \Expval{\dv{\hat{L}}{t}} } \end{aligned}$$ In practice, since most operators are time-independent, the last term often vanishes. As a interesting side note, in the [Heisenberg picture](/know/concept/heisenberg-picture/), this relation proves itself, when one simply wraps all terms in $$\Bra{\psi}$$ and $$\Ket{\psi}$$. Two observables of particular interest are the position $$\hat{X}$$ and momentum $$\hat{P}$$. Applying the above theorem to $$\hat{X}$$ yields the following, which we reduce using the fact that $$\hat{X}$$ commutes with the potential $$V(\hat{X})$$, because one is a function of the other: $$\begin{aligned} \dv{\expval{\hat{X}}}{t} &= \frac{1}{i \hbar} \Expval{[\hat{X}, \hat{H}]} = \frac{1}{2 i \hbar m} \Expval{[\hat{X}, \hat{P}^2] + 2 m [\hat{X}, V(\hat{X})]} = \frac{1}{2 i \hbar m} \Expval{[\hat{X}, \hat{P}^2]} \\ &= \frac{1}{2 i \hbar m} \Expval{\hat{P} [\hat{X}, \hat{P}] + [\hat{X}, \hat{P}] \hat{P}} = \frac{2 i \hbar}{2 i \hbar m} \expval{\hat{P}} = \frac{\expval{\hat{P}}}{m} \end{aligned}$$ This is the first part of the "original" form of Ehrenfest's theorem, which is reminiscent of classical Newtonian mechanics: $$\begin{gathered} \boxed{ \dv{\expval{\hat{X}}}{t} = \frac{\expval{\hat{P}}}{m} } \end{gathered}$$ Next, applying the general formula to the expected momentum $$\expval{\hat{P}}$$ gives us: $$\begin{aligned} \dv{\expval{\hat{P}}}{t} &= \frac{1}{i \hbar} \Expval{[\hat{P}, \hat{H}]} = \frac{1}{2 i \hbar m} \Expval{[\hat{P}, \hat{P}^2] + 2 m [\hat{P}, V(\hat{X})]} = \frac{1}{i \hbar} \Expval{[\hat{P}, V(\hat{X})]} \end{aligned}$$ To find the commutator, we go to the $$\hat{X}$$-basis and use a test function $$f(x)$$: $$\begin{aligned} \Comm{- i \hbar \dv{}{x}}{V(x)} \: f(x) &= - i \hbar \frac{dV}{dx} f(x) - i \hbar V(x) \frac{df}{dx} + i \hbar V(x) \frac{df}{dx} = - i \hbar \frac{dV}{dx} f(x) \end{aligned}$$ By inserting this result back into the previous equation, we find the following: $$\begin{aligned} \dv{\expval{\hat{P}}}{t} &= - \frac{i \hbar}{i \hbar} \Expval{\frac{d V}{d \hat{X}}} = - \Expval{\frac{d V}{d \hat{X}}} \end{aligned}$$ This is the second part of Ehrenfest's theorem, which is also similar to Newtonian mechanics: $$\begin{gathered} \boxed{ \dv{\expval{\hat{P}}}{t} = - \Expval{\pdv{V}{\hat{X}}} } \end{gathered}$$ There is an important consequence of Ehrenfest's original theorems for the symbolic derivatives of the Hamiltonian $$\hat{H}$$ with respect to $$\hat{X}$$ and $$\hat{P}$$: $$\begin{gathered} \boxed{ \Expval{\pdv{\hat{H}}{\hat{P}}} = \dv{\expval{\hat{X}}}{t} } \qquad \quad \boxed{ - \Expval{\pdv{\hat{H}}{\hat{X}}} = \dv{\expval{\hat{P}}}{t} } \end{gathered}$$ These are easy to prove yourself, and are analogous to Hamilton's canonical equations.