From 549b1e963183b6284aefbc52b9167009fefa551d Mon Sep 17 00:00:00 2001 From: Prefetch Date: Sat, 20 Feb 2021 18:08:52 +0100 Subject: Fix "Time-independent perturbation theory" --- .../index.html | 66 +++++++++++----------- 1 file changed, 33 insertions(+), 33 deletions(-) (limited to 'static/know/concept/time-independent-perturbation-theory') diff --git a/static/know/concept/time-independent-perturbation-theory/index.html b/static/know/concept/time-independent-perturbation-theory/index.html index eeb53a3..aeaa570 100644 --- a/static/know/concept/time-independent-perturbation-theory/index.html +++ b/static/know/concept/time-independent-perturbation-theory/index.html @@ -54,41 +54,41 @@

\[\begin{aligned} \hat{H} = \hat{H}_0 + \lambda \hat{H}_1 \end{aligned}\]

-

Where \(\hat{H}_0\) is a Hamiltonian for which the time-independent Schrödinger equation has a known solution, and \(\hat{H}_1\) is a small perturbing Hamiltonian. The eigenenergies \(E_n\) and eigenstates \(\ket{\psi_n}\) of the composite problem are expanded accordingly in the perturbation “bookkeeping” parameter \(\lambda\):

+

Where \(\hat{H}_0\) is a Hamiltonian for which the time-independent Schrödinger equation has a known solution, and \(\hat{H}_1\) is a small perturbing Hamiltonian. The eigenenergies \(E_n\) and eigenstates \(\ket{\psi_n}\) of the composite problem are expanded in the perturbation “bookkeeping” parameter \(\lambda\):

\[\begin{aligned} \ket{\psi_n} - &= \ket{\psi_n^{(0)}} + \lambda \ket{\psi_n^{(1)}} + \lambda^2 \ket{\psi_n^{(2)}} + ... + &= \ket*{\psi_n^{(0)}} + \lambda \ket*{\psi_n^{(1)}} + \lambda^2 \ket*{\psi_n^{(2)}} + ... \\ E_n &= E_n^{(0)} + \lambda E_n^{(1)} + \lambda^2 E_n^{(2)} + ... \end{aligned}\]

-

Where \(E_n^{(1)}\) and \(\ket{\psi_n^{(1)}}\) are called the first-order corrections, and so on for higher orders. We insert this into the Schrödinger equation:

+

Where \(E_n^{(1)}\) and \(\ket*{\psi_n^{(1)}}\) are called the first-order corrections, and so on for higher orders. We insert this into the Schrödinger equation:

\[\begin{aligned} \hat{H} \ket{\psi_n} - &= \hat{H}_0 \ket{\psi_n^{(0)}} - + \lambda \big( \hat{H}_1 \ket{\psi_n^{(0)}} + \hat{H}_0 \ket{\psi_n^{(1)}} \big) \\ - &\qquad + \lambda^2 \big( \hat{H}_1 \ket{\psi_n^{(1)}} + \hat{H}_0 \ket{\psi_n^{(2)}} \big) + ... + &= \hat{H}_0 \ket*{\psi_n^{(0)}} + + \lambda \big( \hat{H}_1 \ket*{\psi_n^{(0)}} + \hat{H}_0 \ket*{\psi_n^{(1)}} \big) \\ + &\qquad + \lambda^2 \big( \hat{H}_1 \ket*{\psi_n^{(1)}} + \hat{H}_0 \ket*{\psi_n^{(2)}} \big) + ... \\ E_n \ket{\psi_n} - &= E_n^{(0)} \ket{\psi_n^{(0)}} - + \lambda \big( E_n^{(1)} \ket{\psi_n^{(0)}} + E_n^{(0)} \ket{\psi_n^{(1)}} \big) \\ - &\qquad + \lambda^2 \big( E_n^{(2)} \ket{\psi_n^{(0)}} + E_n^{(1)} \ket{\psi_n^{(1)}} + E_n^{(0)} \ket{\psi_n^{(2)}} \big) + ... + &= E_n^{(0)} \ket*{\psi_n^{(0)}} + + \lambda \big( E_n^{(1)} \ket*{\psi_n^{(0)}} + E_n^{(0)} \ket*{\psi_n^{(1)}} \big) \\ + &\qquad + \lambda^2 \big( E_n^{(2)} \ket*{\psi_n^{(0)}} + E_n^{(1)} \ket*{\psi_n^{(1)}} + E_n^{(0)} \ket*{\psi_n^{(2)}} \big) + ... \end{aligned}\]

If we collect the terms according to the order of \(\lambda\), we arrive at the following endless series of equations, of which in practice only the first three are typically used:

\[\begin{aligned} - \hat{H}_0 \ket{\psi_n^{(0)}} - &= E_n^{(0)} \ket{\psi_n^{(0)}} + \hat{H}_0 \ket*{\psi_n^{(0)}} + &= E_n^{(0)} \ket*{\psi_n^{(0)}} \\ - \hat{H}_1 \ket{\psi_n^{(0)}} + \hat{H}_0 \ket{\psi_n^{(1)}} - &= E_n^{(1)} \ket{\psi_n^{(0)}} + E_n^{(0)} \ket{\psi_n^{(1)}} + \hat{H}_1 \ket*{\psi_n^{(0)}} + \hat{H}_0 \ket*{\psi_n^{(1)}} + &= E_n^{(1)} \ket*{\psi_n^{(0)}} + E_n^{(0)} \ket*{\psi_n^{(1)}} \\ - \hat{H}_1 \ket{\psi_n^{(1)}} + \hat{H}_0 \ket{\psi_n^{(2)}} - &= E_n^{(2)} \ket{\psi_n^{(0)}} + E_n^{(1)} \ket{\psi_n^{(1)}} + E_n^{(0)} \ket{\psi_n^{(2)}} + \hat{H}_1 \ket*{\psi_n^{(1)}} + \hat{H}_0 \ket*{\psi_n^{(2)}} + &= E_n^{(2)} \ket*{\psi_n^{(0)}} + E_n^{(1)} \ket*{\psi_n^{(1)}} + E_n^{(0)} \ket*{\psi_n^{(2)}} \\ ... &= ... \end{aligned}\]

-

The first equation is the unperturbed problem, which we assume has already been solved, with eigenvalues \(E_n^{(0)} = \varepsilon_n\) and eigenvectors \(\ket{\psi_n^{(0)}} = \ket{n}\):

+

The first equation is the unperturbed problem, which we assume has already been solved, with eigenvalues \(E_n^{(0)} = \varepsilon_n\) and eigenvectors \(\ket*{\psi_n^{(0)}} = \ket{n}\):

\[\begin{aligned} \hat{H}_0 \ket{n} = \varepsilon_n \ket{n} \end{aligned}\]

@@ -96,17 +96,17 @@

Without degeneracy

We start by assuming that there is no degeneracy, in other words, each \(\varepsilon_n\) corresponds to one \(\ket{n}\). At order \(\lambda^1\), we rewrite the equation as follows:

\[\begin{aligned} - (\hat{H}_1 - E_n^{(1)}) \ket{n} + (\hat{H}_0 - \varepsilon_n) \ket{\psi_n^{(1)}} = 0 + (\hat{H}_1 - E_n^{(1)}) \ket{n} + (\hat{H}_0 - \varepsilon_n) \ket*{\psi_n^{(1)}} = 0 \end{aligned}\]

-

Since \(\ket{n}\) form a complete basis, we can express \(\ket{\psi_n^{(1)}}\) in terms of them:

+

Since \(\ket{n}\) form a complete basis, we can express \(\ket*{\psi_n^{(1)}}\) in terms of them:

\[\begin{aligned} - \ket{\psi_n^{(1)}} = \sum_{m \neq n} c_m \ket{m} + \ket*{\psi_n^{(1)}} = \sum_{m \neq n} c_m \ket{m} \end{aligned}\]

-

Importantly, \(n\) has been removed from the summation to prevent dividing by zero later. This is allowed, because \(\ket{\psi_n^{(1)}} - c_n \ket{n}\) also satisfies the \(\lambda^1\)-order equation for any value of \(c_n\), as demonstrated here:

+

Importantly, \(n\) has been removed from the summation to prevent dividing by zero later. We are allowed to do this, because \(\ket*{\psi_n^{(1)}} - c_n \ket{n}\) also satisfies the order-\(\lambda^1\) equation for any value of \(c_n\), as demonstrated here:

\[\begin{aligned} - (\hat{H}_1 - E_n^{(1)}) \ket{n} + (\hat{H}_0 - \varepsilon_n) \ket{\psi_n^{(1)}} - (\varepsilon_n - \varepsilon_n) c_n \ket{n} = 0 + (\hat{H}_1 - E_n^{(1)}) \ket{n} + (\hat{H}_0 - \varepsilon_n) \ket*{\psi_n^{(1)}} - (\varepsilon_n - \varepsilon_n) c_n \ket{n} = 0 \end{aligned}\]

-

Where we used \(\hat{H}_0 \ket{n} = \varepsilon_n \ket{n}\). Inserting the series form of \(\ket{\psi_n^{(1)}}\) into the order-\(\lambda^1\) equation gives us:

+

Where we used \(\hat{H}_0 \ket{n} = \varepsilon_n \ket{n}\). We insert the series form of \(\ket*{\psi_n^{(1)}}\) into the \(\lambda^1\)-equation:

\[\begin{aligned} (\hat{H}_1 - E_n^{(1)}) \ket{n} + \sum_{m \neq n} c_m (\varepsilon_m - \varepsilon_n) \ket{m} = 0 \end{aligned}\]

@@ -125,10 +125,10 @@

\[\begin{aligned} \matrixel{k}{\hat{H}_1}{n} + c_k (\varepsilon_k - \varepsilon_n) = 0 \end{aligned}\]

-

We isolate this result for \(c_k\) and insert it into the series form of \(\ket{\psi_n^{(1)}}\) to get the full first-order correction to the wave function:

+

We isolate this result for \(c_k\) and insert it into the series form of \(\ket*{\psi_n^{(1)}}\) to get the full first-order correction to the wave function:

\[\begin{aligned} \boxed{ - \ket{\psi_n^{(1)}} + \ket*{\psi_n^{(1)}} = \sum_{m \neq n} \frac{\matrixel{m}{\hat{H}_1}{n}}{\varepsilon_n - \varepsilon_m} \ket{m} } \end{aligned}\]

@@ -143,7 +143,7 @@ E_n^{(2)} = \matrixel{n}{\hat{H}_1}{\psi_n^{(1)}} - E_n^{(1)} \braket{n}{\psi_n^{(1)}} \end{aligned}\]

-

We explicitly removed the \(\ket{n}\)-dependence of \(\ket{\psi_n^{(1)}}\), so the last term is zero. By simply inserting our result for \(\ket{\psi_n^{(1)}}\), we thus arrive at:

+

We explicitly removed the \(\ket{n}\)-dependence of \(\ket*{\psi_n^{(1)}}\), so the last term is zero. By simply inserting our result for \(\ket*{\psi_n^{(1)}}\), we thus arrive at:

\[\begin{aligned} \boxed{ E_n^{(2)} @@ -196,7 +196,7 @@ c_1 \\ \vdots \\ c_D \end{bmatrix} \end{aligned}\]

-

This is an eigenvalue problem for \(E_n^{(1)}\), where \(c_d\) are the components of the eigenvectors which represent the “good” states. Suppose that this eigenvalue problem has been solved, and that \(\ket{n, g}\) are the resulting “good” states. Then, as long as \(E_n^{(1)}\) is a non-degenerate eigenvalue of \(M\):

+

This is an eigenvalue problem for \(E_n^{(1)}\), where \(c_d\) are the components of the eigenvectors which represent the “good” states. After solving this, let \(\ket{n, g}\) be the resulting “good” states. Then, as long as \(E_n^{(1)}\) is a non-degenerate eigenvalue of \(M\):

\[\begin{aligned} \boxed{ E_{n, g}^{(1)} = \matrixel{n, g}{\hat{H}_1}{n, g} @@ -205,18 +205,18 @@

Which is the same as in the non-degenerate case! Even better, the first-order wave function correction is also unchanged:

\[\begin{aligned} \boxed{ - \ket{\psi_{n,g}^{(1)}} + \ket*{\psi_{n,g}^{(1)}} = \sum_{m \neq (n, g)} \frac{\matrixel{m}{\hat{H}_1}{n, g}}{\varepsilon_n - \varepsilon_m} \ket{m} } \end{aligned}\]

-

This works because the matrix \(M\) is diagonal in the \(\ket{n, g}\)-basis, such that when \(\ket{m}\) is any vector \(\ket{n, \gamma}\) in the \(\ket{n}\)-eigenspace (except for \(\ket{n,g}\) of course, which is explicitly excluded), then conveniently the corresponding numerator \(\matrixel{n, \gamma}{\hat{H}_1}{n, g} = M_{\gamma, g} = 0\), so the term does not contribute.

-

If any of the eigenvalues \(E_n^{(1)}\) of \(M\) are degenerate, then there is still some information missing about the components \(c_d\) of the “good” states, in which case we must find these states some other way.

-

An alternative way of determining these “good” states is also of interest if there is no degeneracy in \(M\), since such a shortcut would allow us use the formulae from non-degenerate perturbation theory straight away.

-

The method is to find a Hermitian operator \(\hat{L}\) (usually using symmetry) which commutes with both \(\hat{H}_0\) and \(\hat{H}_1\):

+

This works because the matrix \(M\) is diagonal in the \(\ket{n, g}\)-basis, such that when \(\ket{m}\) is any vector \(\ket{n, \gamma}\) in the \(\ket{n}\)-eigenspace (except for \(\ket{n,g}\), which is explicitly excluded), then the corresponding numerator \(\matrixel{n, \gamma}{\hat{H}_1}{n, g} = M_{\gamma, g} = 0\), so the term does not contribute.

+

If any of the eigenvalues \(E_n^{(1)}\) of \(M\) are degenerate, then there is still information missing about the components \(c_d\) of the “good” states, in which case we must find them some other way.

+

Such an alternative way of determining these “good” states is also of interest even if there is no degeneracy in \(M\), since such a shortcut would allow us to use the formulae from non-degenerate perturbation theory straight away.

+

The trick is to find a Hermitian operator \(\hat{L}\) (usually using symmetries of the system) which commutes with both \(\hat{H}_0\) and \(\hat{H}_1\):

\[\begin{aligned} -= [\hat{L}, \hat{H}_1] = 0 + [\hat{L}, \hat{H}_0] = [\hat{L}, \hat{H}_1] = 0 \end{aligned}\]

-

So that it shares its eigenstates with \(\hat{H}_0\) (and \(\hat{H}_1\)), meaning at least \(D\) of the vectors of the \(D\)-dimensional \(\ket{n}\)-eigenspace are also eigenvectors of \(\hat{L}\).

+

So that it shares its eigenstates with \(\hat{H}_0\) (and \(\hat{H}_1\)), meaning all the vectors of the \(D\)-dimensional \(\ket{n}\)-eigenspace are also eigenvectors of \(\hat{L}\).

The crucial part, however, is that \(\hat{L}\) must be chosen such that \(\ket{n, d_1}\) and \(\ket{n, d_2}\) have distinct eigenvalues \(\ell_1 \neq \ell_2\) for \(d_1 \neq d_2\):

\[\begin{aligned} \hat{L} \ket{n, b_1} = \ell_1 \ket{n, b_1} -- cgit v1.2.3