Spin-Magnetic Moment of Dirac Electron, and Role of Zitterbewegung ()
1. Introduction
The spin and the spin-magnetic moment are basic and the most important concepts in the spintronics [1] that is new research field in considerable expansion. In the previous work [2] , we found that the spin-magnetic moment seems to be caused from well-known definitional equation of magnetic moment. Such a case never happen in the non-relativistic quantum mechanics. In the relativistic quantum mechanics, however, the electron has another degree of freedom called Zitterbewegung [3] -[5] that is trembling motion of relativistic electron. Some physical connection between the spin-magnetic moment and Zitterbewegung was implied in the previous work [2] .
In this paper, we investigate a question about the origin of the spin-magnetic moment of the electron and roles of Zitterbewegung relating to it. The use of Heisenberg picture will make hidden roles of Zitterbewegung more clear than previous work. On the other hand, Zitterbewegung in solid state physics [6] -[8] has been a subject of great interest in recent years, since observable Zitterbewegung-like dynamics of band electron was predicted [9] [10] for electron moving in narrow-gap semiconductors [11] , graphene sheets [12] , carbon nanotube [13] , and super conductor [14] . Our research in this paper is therefore worthwhile on both sides of science and technology. As a result, we obtain
(1)
more easily than the previous work [2] , where
denotes expectation value of z-component of spin-magnetic moment of a free Dirac electron in positive energy state.
2. Relation between Spin and Spin-Magnetic Moment
It is well known that the relativistic electron put in the external magnetic field gives interaction energy with the magnetic field
. This term [15] [16]
(2)
was understood as the interaction energy
between an external magnetic field
and the magnetic moment
. Then, physicists concluded that
(3)
must be the spin-magnetic moment of the electron in comparison with Equation (2). However, Equation (3) provided merely the relation of the spin-magnetic moment
and the spin operator
by the analogy with classical electrodynamics. We do not still know how the spin-magnetic moment is generated, and what the spin-magnetic moment is. In order to clarify the origin of the spin-magnetic moment, we must deduce it without the external magnetic field which always leads to the interaction energy of the form
. Generally, the magnetic moment for a charged particle moving with the velocity
and the charge
is defined as [17] [18]
(4)
in the classical electrodynamics, where
is speed of light. In the non-relativistic quantum theory, the above equation can be expressed as
(5)
by using
and
.
In relativistic quantum theory, however, we should mind that we can not use Equation (5) for Dirac electron, because the velocity
and the momentum
are independent variables to each other (i.e.
) in this case [2] .
3. Zitterbewegung
As to Zitterbewegung, we briefly show all equations that are needed later. The velocity
of Dirac electron is given [19] by Heisenberg equation,
(6)
where
are the Dirac matrices in Dirac Hamiltonian
(7)
The
matrices
and
are defined as
(8)
where
are the Pauli matrices. These matrices satisfy the following relations:
(9)
(10)
In order to clarify the role of Zitterbewegung, we use Heisenberg picture hereafter to calculate the time evolution of any operator. We first investigate the behavior of matrix
as an operator
. Making use of Equation (10), we easily find [4]
(11)
where
is the original matrix
of Equation (7) in schrödinger picture. Differentiation of both sides of Equation (11) by
gives
(12)
The solution of the above differential equation is
(13)
We substitute Equation (13) into Equation (11) to obtain
(14)
Taking
, we have the above relation in another form.
(15)
We finally obtain
(16)
from Equations (15) and (14).
4. Solutions of Dirac Equation
For reader’s convenience, we summarize all equations in the following; they are necessary for our calculation. The Dirac equation
(17)
has four eigen-solutions. We name these solutions
defined as
(18)
where
is the energy of a free Dirac electron with momentum
,
(19)
Two arrows
and
denote ‘Up Spin’ and ‘Down Spin’ respectively. The explicit forms of eigensolutions in Heisenberg picture are given by
(20)
where
is normalization volume, and
are expressed as follows [16] ;
(21)
(22)
(23)
(24)
with normalization factor
(25)
and eigen states of “Up Spin” and “Down Spin”,
(26)
respectively. The momentum
takes discrete values in normalization volume
: That is
for
. The functions
are orthonormalized:
(27)
as well as
(28)
Next relations are especially important in a frame
:
(29)
(30)
Because each component of
satisfies
,
takes the eigenvalues
and
. This means the velocity
also has two eigenvalues
, that is the speed of light. However, states
are not eigen states of
. An explicit form of
in the next section is applicable to the states
.
5. Expectation Value of Zitterbewegung
In actual calculation, we will take z-axis along the momentum of the electron:
. This procedure is necessary in order to not only simplify our calculation but also exclude the z-component of angular momentum caused by orbital motion of the electron.
The velocity operator
is divided into two parts.
(31)
where
(32)
and
(33)
from Equation (16). The velocity
is Zitterbewegung part which includes oscillation factor, and
corresponds to uniform velocity. The coordinate operator
is also easily calculated from corresponding part of the above equations.
(34)
(35)
(36)
where
is an integration constant, and
agrees to an initial point of the electron in classical sense. Remembering that
is equal to the original
of Equation (7), we easily calculate the expectation value of
for
in our frame, by the use of relations in Sections 3 and 4.
(37)
Equation (37) leads to
(38)
(39)
and
(40)
(41)
(42)
where
is used. Arbitrary constant
can set to zero without loss of generality. The similar results occur for x and y components of both
and
. The contribution from uniform velocity vanish at this time because of
.
(43)
(44)
(45)
(46)
where the expression of the expectation value for
is simplified. Results (38)-(46) indicate that Zitterbewegung (trembling motion) phenomenon for relativistic electron is un-observable effect in the sense that the expectation values of physical quantities always agree to classically measured one in accordance with Ehrenfest’s law [20] . A question whether Zitterbewegung works or not in actual physics phenomena then arises. The answer will be shown in the next section.
6. Spin-Magnetic Moment
We calculate the magnetic moment based on Equation (4). As mentioned in Section 2, the velocity
of relativistic electron is not equal to
but equal to
. So that the expression of magnetic moment
must be
(47)
for relativistic electron. It is our advantage that we need no external magnetic field. In what follows, we pay attention to the electron in state
, and to the z-component of the magnetic moment.
(48)
By the use of the completeness condition
(49)
we have an expression of the expectation value of
.
(50)
Each matrix elements of uniform part are calculated as follows:
(51)
(52)
(53)
We have also Zitterbewegung part of the velocity.
(54)
as well as
(55)
Substitution of Equations (51)-(55) into Equation (50) gives
(56)
We find here that
is made only by Zitterbewegung parts. We can easily obtain each element:
(57)
(58)
We then finally obtain
(59)
which is the same result as in the previous work [2] .
It is necessary to recall that there is not any z-component of magnetic moment arising from orbital motion of electron because of
and
in our frame. Nevertheless, magnetic moment of Equation (59) has actually appeared. Therefore, we may conclude that
of Equation (59) and the spin-magnetic moment of the electron must be identified. When the momentum of the electron is small and
, it becomes
(60)
indicating correct
-factor because of
for Dirac electron in our frame; that is
(61)
where
is the
spin matrix operator.
7. Concluding Remarks
As seen in Sections 5, the expectation values of all Zitterbewegung parts give zero or constant, both in velocity and coordinates. This means that we can not directly measure the effect of Zitterbewegung. However, they still survive behind some kind of physical quantities. The magnetic moment is an example. Although Zitter-bewegung relating to the velocity or coordinates is un-observable in the sense of the expectation value which corresponds to classical behavior, we have shown that it exists and works through the magnetic moment. A crucial point is non-diagonal matrix elements:
. The physical meaning of these matrix elements is inferred as follows:
The initial state
of electron with positive energy and up-spin undergoes transition into the state
with opposite signs of energy and spin (See Equations (29) and (30)), by operating
. This matrix element is a kind of “transition current” because it exactly corresponds to the electric current
in the definition of magnetic moment [2] which is written in another form [18] ,
(62)
In quantum theory, the conservation law of energy may break by
in time
, where
(63)
The electron which has undergone transition into
must immediately return to
within time
. The period of transition cycle is about
(64)
where
means the energy gap of Dirac Sea in vacuum. This
agrees with the frequency of Zitterbewegung (See Equations (57) and (58)).
In the classical electrodynamics, the magnetic moment is caused by periodic orbital motion of a charged particles which is equivalent to an electric current. In the relativistic quantum theory, it seems that it is possible to cause the magnetic moment also by periodic transition from the positive energy state to the negative energy state (Figure 1). It then seems that the former is the magnetic moment which corresponds to Equation (5) with
Figure 1. Spin-magnetic moment caused by transition current.
, and the latter is the spin-magnetic moment with
. In other word, the spin-magnetic moment may be caused not by usual electric current but by some new current which yield when the electron undergoes transition between two states of positive and negative energies. It should be noted that even an electron at rest (i.e.
and
) in space is able to yield this new current.
8. Another Remarks
Such a situation as described above occurs in some kind of solid state. In the two band model of Cohen and Blount [21] , Wolff [22] indicated that the Hamiltonian takes the Dirac form after a suitable transformation, and that the resulting equations are essentially identical to those of the Dirac theory. This fact means that we could apply the method developed here to the spin-magnetic moment of electron in solid state [23] . Zawadzki [11] indeed pointed out that the energy of the electron in narrow-gap semiconductor was given as
(65)
(
: effective mass), where
is maximum value of the group velocity
of electron in band:
(66)
The Hamiltonian which corresponds to Equation (65) has the form
(67)
in the frame

where
and
are the Dirac matrices. The above Hamiltonian agrees completely to the Dirac Hamiltonian in Equation (7) if we replace
by
, and
by
. Obeying the Heisenberg equation of motion, it is then predicted that
of the equal form reproduces the same results obtained here with the replacements
and
. They will appear as a change of
-factor of the electron in semiconductor from new equation corresponding to Equation (59).