The Heisenberg Picture
Previously, we have used the Schrödinger picture to describe the dynamics of a system.
This involves solving the time-dependent Schrödinger equation to find the time-evolution operator
Table of Contents
Introduction
The key difference between the two pictures is how we treat the operators and the states.
This can be illustrated by considering an unitary operator
This means that the inner product is invariant under the time-evolution operator, which is a direct result from the fact that
(These are equivalent from the associative axiom.)
- The left-hand side takes the approach of
remaining constant while . - The right-hand side takes the approach of
while remains constant.
The first approach is the Schrödinger picture, where the operators are time-independent and the states evolve in time.
The second approach is the Heisenberg picture, where the operators evolve in time and the states are time-independent.
This is a matter of convention, and both pictures are equivalent.
To take an example, consider taking the expectation value of
-
In the Schrödinger picture, we have:
-
In the Heisenberg picture, we have:
The Heisenberg picture is more closely related to classical mechanics because it treats the operators as observables that evolve in time, similar to how classical quantities evolve in time.
To distinguish between the two, we use the superscript
The following table summarizes the differences between the two pictures:
| Schrödinger Picture | Heisenberg Picture | |
|---|---|---|
| Operators | Time-independent | Time-dependent |
| States | Time-dependent | Time-independent |
| Expectation Value |
Heisenberg Equation of Motion
Now one may wonder what the Heisenberg-picture equivalent of the Schrödinger equation
To find the time derivative of
Now, we can take the time derivative of
Since
Notice that outside of the common factors, the only difference between the two terms is the order of the operators.
As such, we can rewrite the equation with the commutator
Recall that in the Hamiltonian picture, operators evolve over time as
This is the Heisenberg equation of motion, which describes how the operators evolve in time.
If one has studied Hamiltonian mechanics, this should look familiar. Hamilton's equations of motion are given by:
where
Time-Evolution of Base Kets
In the Schrödinger picture, state vectors evolve in time while their base kets and operators remain constant.
On the other hand, in the Heisenberg picture, base kets do change in time.
To begin with, suppose we have an operator
In the Schrödinger picture,
Then, insert
We see the left-hand side is just
This implies that
In other words, because of the
The coefficient
whereas in the Heisenberg picture, the coefficient
because
An Explicit Form of the Hamiltonian (Ehrenfest's Theorem)
Now that we have both the Schrödinger and Heisenberg equations of motion, we can start applying them to real systems.
Notice that both of them rely on the Hamiltonian
- Typically, we assume that
is just the quantum equivalent of the classical Hamiltonian, but with the classical variables replaced with operators. - If, using the above method, there are noncommuting observables, we resolve this ambiguity by requiring that the Hamiltonian be Hermitian.
- If there is no classical equivalent for the physical system, we make an educated guess for the Hamiltonian based on properties of the system. Then, we use experiments to determine its validity.
We will study a particle in one dimension, which is a simple system that has a well-defined classical Hamiltonian. This acts as a sanity-check for quantum mechanics; we will derive results that closely match the equations for classical mechanics:
- Momentum is conserved for a free particle.
- For a free particle, position evolves in time as
. - Newton's second law:
.
First, we will derive two important results regarding the commutator of
Proof. We assume that
(If this appears unfamiliar, this is the Taylor series for a function of several variables.)
To simplify the notation, we can use a multi-index notation, where
Our strategy is to first prove the result for a single monomial term
The Hamiltonian for a free particle is the same as the classical Hamiltonian:
Taking any momentum operator
The commutator
If we take the position operator
Now we use the result that
where we have used the fact that
This satisfies our second classical sanity-check.
Lastly, suppose we now place the particle in a potential
We will use the result that
For
But because this is just Heisenberg's equation applied to
We know that
Finally, if we apply this to all directions, we obtain a vector form of the equation:
This is the quantum equivalent of Newton's second law, which states that the acceleration of a particle is equal to the force acting on it divided by its mass.
This satisfies our third classical sanity-check.
However, this equation still explicitly uses operators, and hence only applies to the Heisenberg picture.
To generalize this, we can multiply both sides by
Because expectation values are the same in both pictures, this equation is more general. It is known as Ehrenfest's theorem.
Summary and Next Steps
In this section, we have introduced the Heisenberg picture of quantum mechanics, which is an alternative formulation to the Schrödinger picture. The differences between the pictures are summarized in the table below.
| Schrödinger Picture | Heisenberg Picture | |
|---|---|---|
| Operators | Time-independent | Time-dependent |
| States | Time-dependent | Time-independent |
| Base Kets | Time-independent | Time-dependent |
| Equation of Motion |
We also derived Ehrenfest's theorem, an important sanity-check for quantum mechanics:
In the next section, we will study Feynman's path integral formulation of quantum mechanics.