Atoms in electric fields

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This section deals with how atoms behave in static electric fields. The method is straightforward, involving second order perturbation theory. The treatment describes the effects of symmetry on the basic interaction, polarizability, and the concept of oscillator strength.


Review of parity

Review: Results of Stationary Perturbation Theory

Atoms in a Static Electric Field

We can use this basic idea in understanding the problem of an atom subjected to an electric field. We begin by writing down the potential due to a collection of charges,

where

where is the charge distribution. is the total charge, are the dipole moments, are the quadrupole moments, etc. The energy of an overall neutral collection of charges in an electric field can similarly be expanded as

where is the dipole and is the polarizability.

Now we are in a better position to solve the problem of the hydrogen atom in a static electric field, , just about the simplest example.

The hamiltonian for this problem can be written

where is the "unperturbed" hamiltonian for the hydrogen atom.

We chose to solve this via matrix methods. The first step is to write down the matrix elements for the hamiltonian is a basis of our choosing. Let's try with the basis kets, the eigenkets of . So, only contributes diagonal elements to the matrix, . As and are scalars, not operators, we need only consider the effect of . First, is a parity odd operator, connecting only states of different parity. Thus contributes nothing to the diagonal entries nor to any entries with the same angular momentum, . States of the same parity but whose angular momentum differ by more than also result in zero because ... Finally, also only connects states of the same . One can see this by noting that

which is an even function in . Any states differing by would then result in an integral of two even functions (one of those being the originating from the ) and an odd function in which is zero. This resulta can also be seen directly by noting a result of the Wigner-Eckhart theorem that where is just a number. Thus, we produce the "selection rules" for the operator,

NOTE that this strictly applies only the this specific operator. If were pointing in some other direction then things might (and do) change.

The matrix for the our hamiltonian reads then

where the entries arranged in order. The 0's are designated with an indication of "why" those particular entries in the matrix are zero, meaning even/odd ( selection rule) and meaning parity ( selection rule. As mentioned above, the contribution to the diagonal elements is zero due to parity. Because the states are degenerate, degenerate pertubation theory must be used to solve the problem. Of course we know that in reality the problem is more complex than this. Both fine, hyperfine and the Lamb shift have been neglected. Solving the problem taking this into account would indicate the use of second order pertubation theory.

To see how this all shakes out, let's go ahead and apply pertubation theory directly.

If one is in the case where this simple pertubation theory does not work because of degenerate states (leading to in the denominator then it is best just to diagonalize the Hamiltonian in relation to . If you do that for the case of you find that the eigenstates are

where is a constant. The last two states have a linear response to the electric field, or a linear Stark effect. Even is there were a small splitting between the different states in the manifold, if the field interaction were higher that the splitting then there would be also be a linear Stark effect. At lower fields the interaction would be second order (second order pertubation theory would be called for) and the response would be quadratic in the applied electric field. Notice the the new eigenstates are a mixture of states of different parity. This mixture allows for a dipole to be formed and it is the interaction of the electic field with this dipole that gives rise to a linear response to the field. It is this dipole that is talked about by chemists when they say that a molecule "has a dipole moment". Molecules "have dipole moments" because they have closely lying states of opposite parity so small fields put them in the linear Stark regime. But make no mistake, at low enough fields, the response would be quadratic, just as it is in the case of atoms.

Now, all of this has been talked about under the (essentially correct) assumption that and, therefore, that the eigenstates of the H atom are also parity eigenstates. But what if  ? This occurs when the weak force is involved and will likely be present in nature and described, eventually, by extensions to the Standard Model. Such mechanisms can lead to the presence of permanent electic dipole moments of elementary particles.


Perturbation Theory of Polarizability

We will find the energy and polarizability of an atom in a static field along the +z direction. We apply perturbation theory taking to describe the unperturbed atomic system and

Non-degenerate eigenstates have to be eigenstates of parity. Since is odd under parity operation, parity requires that . So the first order perturbation vanishes. To second order, the energy is given by

If we define now the polarizability in state as

{EQ_polarsix}

we obtain

The dipole moment is the expectation value of the dipole operator, using the first order perturbed state vector.

where the sum is over Only the term will contribute, and we can express the induced dipole moment by the polarizability:


Note that polarizability has the dimensions of length, i.e. volume. As an example, for the ground state of hydrogen we can obtain a lower limit for the polarizability by considering only the contribution to the sum of the state. Values for the various moments in hydrogen are given in Bethe and Salpeter, Section 63. Using = 1.666, and , we obtain atomic units (i.e. ).

The polarizability of the ground state of hydrogen can be calculated exactly. It turns out that the state makes the major contribution, and that the higher bound states contribute relatively little. However, the continuum makes a significant contributions. The exact value is 4.5.

To put the above result for the polarizability in perspective, note that the potential of a conducting sphere of radius in a uniform electric field is given by

The induced dipole moment is , so that the polarizability is . For the ground state of hydrogen, , so to a crude approximation, in an electric field hydrogen behaves like a conducting sphere.

Polarizability may be approximated easily, though not accurately, using Unsold's approximation in which the energy term in the denominator of Eq. \ref{EQ_polarsix} is replaced by an average energy interval . The sum can then be evaluated using the closure rule . (Note that the term does not need to be excluded from the sum, since .). With this approximation,

For hydrogen in the ground state, . If we take the average excitation energy to be , the result is .


Field ionization

If an atom is placed in a sufficiently high electric field it will be ionized, a process called <it> field ionization </it>. An excellent order of magnitude estimate of the field , required to ionize an atom which is initially in a level bound by energy can be obtained by the following purely classical argument: the presence of the field adds the term to the potential energy of the atom. This produces a potential with a maximum and the atom will ionize if .

File:06-E-FIELD/Field ion.eps
Potential diagram for field ionization.

The figure shows the combined potential as well as and

(EQ_ fieldionone)

The appropriate maximum occurs at

(EQ_ fieldiontwo)

as determined from . Equating and gives

(EQ_ fieldionthree)

for level with energy and quantum number .

The predictions of this formula for is usually accurate within 20% in spite of its neglect of both quantum tunneling and the change in produced by the field. [This latter deficiency is remedied in the comparison with Li data shown in the preceding part of this section because the eye naturally uses the ionization field appropriate to the perturbed energy of the state rather than its zero-field energy.] Tunneling manifests itself as a finite decay rate for states which classically lie lower than the barrier. The increase of the ionization rate with field is so dramatic, however, that the details of the experiment do not influence the field at which ionization occurs very much: calculations [u'BHR65'] show the ionization rate increasing from /sec to /sec for a 30% increase in the field.\

Oddly enough the classical prediction works worse for H than for any other atom. This is a reflection of the fact that certain matrix elements necessary to mix the states (so the wave function samples the region near ) are rigorously zero in H, as discussed in the preceding part of this section. Hence the orbital ellipse of the electron does not precess and can remain on the side of the nucleus. There its energy will increase with , but it will not spill over the lip of the potential and ionize.

Atoms in an Oscillating Electric Field

There is a close connection between the behavior of an atom in a static electric field and its response to an oscillating field, i.e. a connection between the Stark effect and radiation processes. In the former case, the field induces a static dipole moment; in the latter case, it induces an oscillating moment. An oscillating moment creates an oscillating macroscopic polarization and leads to the absorption and emission of radiation. We shall calculate the response of an atom to an oscillating field

where is the polarization vector for the field. For a weak field the time varying state of this system can be found from first order time dependent perturbation theory. We shall write the electric dipole operator as D = -er. (This is a change of notation. Previously the symbol was d.) The Hamiltonian naturally separates into two parts, , where is the unperturbed Hamiltonian and

We shall express the solution of the time dependent Schroedinger equation in terms of the eigenstates of .

where . Because of the perturbation , the 's become time dependent, and we have

Left multiplying the final two expressions by to project out the -th terms yields

where . In perturbation theory, this set of equations is solved by a set of approximations to labeled . Starting with

one sets

and solves for the successive approximations by integration.

We now apply this to the problem of an atom which is in its ground state at , and which is subject to the interaction of Eq.\ \ref{EQ_atomoef2}. Consequently , . Substituting in Eq.\ \ref{EQ_atomoef7} and integrating from to gives

The -1 terms in the square bracketed term arises because it is assumed that the field was turned on instantaneously at . They represent transients that rapidly damp and can be neglected.

The term with , in the denominator is the counter-rotating term. It can be neglected if one is considering cases where (i.e. near resonance), but we shall retain both terms and calculate the expectation value of the first order time dependent dipole operator

If we consider the case of linearly polarized light , then

We can write in terms of a polarizability :

This result diverges if . Later, when we introduce radiative damping, the divergence will be avoided in the usual way.

Oscillator Strength

Eq.\ \ref{EQ_atomoef11} resemble the oscillating dipole moment of a system of classical oscillators. Consider a set of oscillators having charge , mass , and natural frequency , driven by the field . The amplitude of the motion is given by

If we have a set of such oscillators, then the total oscillating moment is given by

This is strongly reminiscent of Eq.\ \ref{EQ_atomoef10}. It is useful to introduce the concept of oscillator strength, a dimensionless quantity defined as

where and are any two eigenstates. Note that is positive if , i.e. for absoprtion, and negative if Then, Eq.\ \ref{EQ_atomoef10} becomes

Comparing this with Eq.\ \ref{EQ_ostre2}, we see that the behavior of an atom in an oscillating field mimics a set of classical oscillators with the same frequencies as the eigenfrequencies of the atom, but having effective charge strengths .\\

The oscillator strength is useful for characterizing radiative interactions and also the susceptibiltiy of atoms. It satisfies an important sum rule, the Thomas-Reiche-Kuhn sum rule:

We prove by considering the general Hamiltonian

Using the commutator relation

and the relation , we have

where , and . However,

Consequently,

where . Thus, we can write Eq.\ \ref{EQ_ostre3} in either of two forms:

Taking half the sum of these equations and using the closure relation , we have

We have calculated this for a one-electron atom, but the application to a Z-electron atom is straightforward because the Hamiltonian in Eq.\ \ref{EQ_ostre6} is quite general. In this case

Here is some eigenstate of the system, and the index describes all the eigenstates of all the electrons -- including continuum states. In cases where only a single electron will be excited, however, for instance in the optical regime of a "single-electron" atom where the inner core electrons are essentially unaffected by the radiation, the atom behaves as if it were a single electron system with .

Note that is positive if , i.e. if the final state lies above the initial state. Such a transition corresponds to absorption of a photon. Since , the oscillator strength for emission of a photon is negative.

Our definition of oscillator strength, Eq.\ \ref{EQ_ostre3}, singles out a particular axis, the -axis, fixed by the polarization of the light. Consequently, it depends on the orientation of the atom in the initial state and final states. It is convenient to introduce the average oscillator strength (often simply called the oscillator strength), by letting , summing over the initial state and averaging over the final state.\\

(This is the conversion followed by Sobelman.) It is evident that

where is the multiplicity factor for state . An extensive discussion of the sum rules and their applications to oscillator strengths and transition momentums can be found in Bethe and Salpeter, section 6.1. Among the interesting features they point out is that transitions from an initial state to a final state on the average have stronger oscillator strengths for absorption if , and stronger oscillator strengths for emission if . In other words, atoms "like" to increase their angular momentum on absorption of a photon, and decrease it on emission. The following page gives a table of oscillator strengths for hydrogen in which this tendency can be readily identified. (Taken from {\it The Quantum Mechanics of One- and Two-Electron Atoms}, H.A. Bethe and E.E. Salpeter, Academic Press (1957).)



Atoms in electric fields-oscillator-strength.png

\caption{ Oscillator strengths for hydrogen. From Mechanics of One- and Two-Electron Atoms}

Index of refraction

(in preparation)

References