nLab semiclassical state

Contents

under construction

Context

Geometric quantum theory

Physics

Idea
Definition

Semiclassical state of the non-relativistic particle in a potential

As a wave function
As a Lagrangian submanifold of phase space equipped with a half-density

In symplectic geometry / geometric quantum theory

Related concepts
References

Idea

In physics, a semiclassical state is the approximation to a quantum state in semiclassical approximation.

In the original sense of the WKB approximation, in the Schrödinger picture a semiclassical state is a wave function which solves the Schrödinger equation to first order in Planck's constant $\hbar$ .

In the broader formalization of quantum physics in symplectic geometry/geometric quantization one finds that such WKB semiclassical states are formalized as being Lagrangian submanifolds of the given phase space symplectic manifold equipped with with a half-density.

Definition

We first give the traditional definition of semiclassical states according to the WKB method for a non-relativistic particle propagating on the Euclidean space $\mathbb{R}^n$ with its standard kinetic action and some arbitrary force potential

Of a non-relativistic particle in a potential

Then we discuss the formalization of this in the broader context of symplectic geometry/geometric quantization in

In symplectic geometry

Semiclassical state of the non-relativistic particle in a potential

Consider the physical system given by a non-relativistic particle of mass $m$ propagating on the Cartesian space $\mathbb{R}^n$ with standard kinetic action and sunbject to a force induced by a given potential smooth function $V \colon \mathbb{R}^n \to \mathbb{R}$ .

As a wave function

The Hamilton operator for this system is the standard

\hat H \coloneqq - \frac{\hbar^2}{2 m} \Delta + V \,,

where

\Delta = \mathbf{d}^\dagger \mathbf{d} = \sum_{i = 1}^n \frac{\partial}{\partial x^i} \frac{\partial}{\partial x^i}

is the Laplace operator on $\mathbb{R}^n$ regarded as a Riemannian manifold with its canonical flat metric ( $\mathbf{d}$ is the de Rham differential).

Then for

\psi \colon \mathbb{R}^n \times \mathbb{R} \to \mathbb{C}

a smooth 1-parameter collection of smooth functions (of wave functions), the Schrödinger equation is

i \hbar \frac{d}{ dt} \psi = \hat H \psi \,,

where $\frac{d}{d t}$ is the differentiation with respect to the additional parameter (time).

We say that $\psi$ is a stationary solution to the Schrödinger equation if it is a solution of the form

\psi(x, t) = \phi(x)\exp(- i \omega t)

for some $\omega \in \mathbb{R}$ . For the following it is useful to decompose the remaining complex-valued smooth function

\phi \colon \mathbb{R}^n \to \mathbb{C}

into its modulus and phase by writing it as

\phi(x) = \exp(i S(x)/\hbar) a(x)

for two smooth functions $S \colon \mathbb{R}^n \to \mathbb{R}$ and $a \colon \mathbb{R}^n \to \mathbb{R}_{\geq 0}$ .

In fact it is often useful (such as in the symplecto-geometric interpretation that we turn to below) to restrict attention to non-vanishing solutions (or else to solutions restricted to their support) in which case we can regard $\phi$ as a function of the form

\phi \colon \mathbb{R}^n \to \mathbb{C}^\times \simeq U(1) \times \mathbb{R}_{\gt 0}

and then this decomposition is unique up to a global global offset of $S$ by $2\pi i \cdot n$ for $n \in \mathbb{Z}$ .

In terms of this decomposition the Schrödinger equation becomes

\begin{aligned} 0 &= \left(i \hbar \frac{d}{dt} - \hat H\right) \psi \\ & = \left( \left( \frac{{\vert \mathbf{d} S \vert}^2 }{2 m } + (V - \hbar \omega) \right) - \frac{i \hbar}{ 2m a} \mathbf{d}^\dagger \left(a^2 \mathbf{d} S\right) \right) \exp( i S / \hbar ) a + \mathcal{O}(\hbar^2 ) \end{aligned} \,,

where $\mathbf{d} S$ is the gradient covector field of $S$ , where $\mathbf{d}^\dagger ( a^2 \mathbf{d}S)$ is the divergence of $a ^2 \mathbf{d}S$ , and where $\mathcal{O}(\hbar^2)$ denotes all further terms that are non-linear in $\hbar$ .

This means that $\psi(-,t) = \exp(i S / \hbar) a \exp(- i \omega )$ is a semiclassical stationary state with energy

E \coloneqq \hbar \omega

if the phase $S$ and the modulus $a$ satisfy the following two conditions:

The phase function $S$ satisfies the Hamilton-Jacobi equation or eikonal? equation

$H(x, \nabla S(x)) = \frac{\vert \mathbf{d} S\vert^2}{2 m } + V = E \,,$
The modulus $a$ is such that $a^2 \mathbf{d} S$ satisfies the homogeneous transport equation? in that it is a divergence-free vector field.

As a Lagrangian submanifold of phase space equipped with a half-density

The above characterization of semiclassical wave functions of the non-relativistic particle in a potential has a natural equivalent reformulation in terms of symplectic geometry/geometric quantization.

The phase space is

T^* \mathbb{R}^n \simeq \mathbb{R}^{2 n} \,.

Into this space is canonically embedded as the 0-section:

0 = (x \mapsto (x, p = 0)) \; \colon \; \mathbb{R}^n \hookrightarrow T^* \mathbb{R}^n

which is a Lagrangian submanifold.

Now every phase function $S \colon \mathbb{R}^n \to \mathbb{R}$ as above induces a deformation of this by regarding the de Rham differential $\mathbf{d}S$ as a section of the cotangent bundle

\mathbf{d}S \colon \mathbb{R}^n \hookrightarrow T^* X

(This is what related phase and phase space in physics.)

This is again a Lagrangian submanifold. We write

\pi \colon im(\mathbf{d}S) \to \mathbb{R}^n

for the restriction of the cotangent bundle projection to this Lagrangian submanifold.

The fact that $S$ satisfies the Hamilton-Jacobi equation means equivalently that this Lagrangian submanifold is the level-set of the Hamiltonian $H \colon \mathbb{R}^n \to \mathbb{R}$ at energy $E = \hbar \omega$

im(\mathbf{d}S) = H^{-1}(E) \,.

For the interpretation of the modulus function $a$ in this reformulation, first notice that for $vol$ the canonical volume form on $\mathbb{R}^n$ , the homogeneous transport equation

div( a^2 \mathbf{d}S) = 0

is equivalent to

\mathcal{L}_{\nabla S} ( a^2 vol ) = 0

where on the left we have the Lie derivative along the gradient of $S$ . Next observe that

\nabla S = \pi_* (v_H)|_{im(\mathbf{d}S)}

where $v_{H}$ is the Hamiltonian vector field corresponding to $H$ .

This means that the transport equation is equivalently

\mathcal{L}_{(v_H)} \pi^* (a^2 vol) = 0 \,.

Hence this says that $\pi^* a^2 vol$ is a volume form on $im(\mathbf{d}S)$ which is invariant with respect to the Hamiltonian flow of time evolution.

Finally, if instead of a volume form we choose a half-density $\sqrt{vol}$ , then $a \sqrt{vol}$ is another half-density and the condition is that this be invariant under the Hamiltonian flow.

In summary then, the semiclassical wave fuction is equivalently

a Lagrangian submanifold
- which is a level-set of the Hamiltonian at the given energy
such that $\mathbf{a} \coloneqq a \sqrt{vol}$ is a half-density on the Lagranian submaifold
- which in addition is invariant under the Hamiltonian flow.

This formulation now suggests a more general definition of semiclassical states in symplectic geometry/geometric quantization.

In symplectic geometry / geometric quantum theory

(…)

abstracting the above we have that

(…)

Related concepts

	classical mechanics	semiclassical approximation	…	formal deformation quantization	quantum mechanics
order of Planck's constant $\hbar$	$\mathcal{O}(\hbar^0)$	$\mathcal{O}(\hbar^1)$	$\mathcal{O}(\hbar^n)$	$\mathcal{O}(\hbar^\infty)$
states	classical state	semiclassical state			quantum state
observables	classical observable				quantum observable

References

An introduction to the formulation of semiclassical states in symplectic geometry is in the first section of

Sean Bates, Alan Weinstein, Lectures on the geometry of quantization (pdf)

Last revised on March 22, 2013 at 14:12:46. See the history of this page for a list of all contributions to it.