Magnetic moment: Difference between revisions

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In physics, the magnetic moment of an object is a vector property, denoted here as m, that determines the torque, denoted here by τ, it experiences in a magnetic flux density B, namely τ = m × B (where × denotes the vector cross product). As such, it also determines the change in potential energy of the object, denoted here by U, when it is introduced to this flux, namely U = −m·B.^[1]

Origin

A magnetic moment may have a macroscopic origin in a bar magnet or a current loop, for example, or microscopic origin in the spin of an elementary particle like an electron, or in the angular momentum of an atom.

Macroscopic examples

(CC) Image: John R. Brews
Electric motor using a current loop in a magnetic flux density, labeled B

The electric motor is based upon the torque experienced by a current loop in a magnetic field. The basic idea is that the current in the loop is made up of moving electrons, which are subect to the Lorentz force F in a magnetic field:

${\displaystyle \mathbf {F} =-e\left(\mathbf {v\times B} \right)\ ,}$

where e is the electron charge and v is the electron velocity. This force upon the electrons is communicated to the wire loop because the electrons cannot escape the wire, and so exert a force upon it. In the figure, the electrons at the left of the loop move oppositely to those at the right, so the force at the left is opposite in direction to that at the right. The magnetic field is in the plane of the loop, so the forces are normal to this plane, causing a torque upon the loop tending to turn the loop about an axis in the plane of the field.^[2] According to the right-hand rule, curling the fingers of the right hand about the loop in the direction of the forces twisting the loop makes the thumb point in the direction of the torque. In the figure the torque is therefore pointed in the plane of the B-field and parallel to the two faces of the magnet.

The torque exerted upon a current loop of radius a carrying a current I, placed in a uniform magnetic flux density B at an angle to the unit normal û_n to the loop is:^[3]

${\displaystyle {\boldsymbol {\tau }}={\mathit {I}}\mathbf {S\times B} \ ,}$

where the vector S is:

${\displaystyle \mathbf {S} =\pi a^{2}\ {\hat {\mathbf {u} }}_{n}\ .}$

Consequently the magnetic moment of this loop is:

${\displaystyle \mathbf {m} ={\mathit {I}}\ \mathbf {S} \ .}$

Microscopic examples

Apart from macroscopic currents, at a fundamental level, magnetic moment is related to the angular momentum of particles: for example, electrons, nucleii, and so forth. In this discussion, focus is upon the electron and the atom.

The discussion splits naturally into two parts: kinematics and dynamics.

Kinematics

The kinematical discussion, which does not enter upon the physical origins of magnetism and its effects upon mechanics, deals with the classification of atomic states based upon symmetry. To emphasize this distinction, spin and orbital motion are considered here as distinct from spin angular momentum and orbital angular momentum. Although these ideas apply to nucleii and other particles, here attention is focused on electrons in atoms.

Spherical symmetry

The symmetry analysis depends upon the environs of an atom. In situations where the spherical symmetry of an atom is little disturbed, spherical symmetry leads to the identification of spin S and orbital motion L and its combination J = L + S.^[4]

The electron has a spin. The resultant total spin S of an ensemble of electrons in an atom is the vector sum of the constituent spins s_j:

${\displaystyle \mathbf {S} =\sum _{j=1}^{N}\ \mathbf {s_{j}} \ .}$

Likewise, the orbital motions of an ensemble of electrons in an atom add as vectors.

Where both spin and orbital motion are present, they combine by vector addition:

${\displaystyle \mathbf {J=L+S} \ .}$

Assuming the atom remains symmetrical under rotations, J, L and S are connected to this symmetry. The mathematical basis is the infinitesimal rotation from which finite rotations can be generated.^[5] For example, a rotation by angle α about the z-axis is described by the matrix:

${\displaystyle {\begin{pmatrix}\cos \alpha &\sin \alpha &0\\-\sin \alpha &\cos \alpha &0\\0&0&1\end{pmatrix}}\ {\underset {\overset {\alpha \rightarrow 0}{}}{\to }}\ {\begin{pmatrix}1&0&0\\0&1&0\\0&0&1\end{pmatrix}}+i\alpha {\begin{pmatrix}0&-i&0\\i&0&0\\0&0&0\end{pmatrix}}={\begin{pmatrix}1&0&0\\0&1&0\\0&0&1\end{pmatrix}}+i\alpha R_{z}\ ,}$

where the form following the arrow applies for very small angles α. The matrix R_z is called the generator of the z-rotation. The factor i is introduced so the finite rotation can be expressed in terms of this generator as a simple exponential:

${\displaystyle {\begin{pmatrix}\cos \alpha &\sin \alpha &0\\-\sin \alpha &\cos \alpha &0\\0&0&1\end{pmatrix}}=e^{i\alpha R_{z}}\ ,}$

as can be verified using the Taylor series:

${\displaystyle e^{i\alpha R_{z}}=1+i\alpha R_{z}+{\frac {1}{2}}\left(i\alpha R_{z}\right)^{2}+...\ .}$

If the three coordinate axes are labeled {i, j, k } and the infinitesimal rotations about each of these axes are labeled {R_i, R_j, R_k}, then these generators of infinitesimal rotations obey the commutation relations:^[6]

${\displaystyle R_{i}R_{j}-R_{j}R_{i}=i\varepsilon _{ijk}R_{k}\ ,}$

for any choices of subscripts. Here ε_ijk is the Levi-Civita symbol.

These commutation relations now are viewed as applying in general, and while still considered as connected to rotations in three dimensional space, the question is opened as to what general mathematical objects might satisfy these rules.

A set of symbols with a defined sum and a product taken as a commutator of the symbols is called a Lie algebra.^[7] In particular, one can construct sets of square matrices of various dimensions that satisfy these commutation rules; each set is a so-called representation of the rules.

The matrices of dimension 2 are found from observation to be connected to the spin of the electron. One set of these matrices is based upon the Pauli spin matrices:^[8]

${\displaystyle \sigma _{x}={\begin{pmatrix}0&1\\1&0\end{pmatrix}}\ ;\ \sigma _{y}={\begin{pmatrix}0&-i\\i&0\end{pmatrix}}\ ;\ \sigma _{z}={\begin{pmatrix}1&0\\0&-1\end{pmatrix}}\ ,}$

which satisfy:

${\displaystyle {\frac {1}{2}}\sigma _{\alpha }{\frac {1}{2}}\sigma _{\beta }-{\frac {1}{2}}\sigma _{\beta }{\frac {1}{2}}\sigma _{\alpha }=i\ \varepsilon _{\alpha \beta \gamma }{\frac {1}{2}}\sigma _{\gamma }\ ,}$

with αβγ any combination of xyz.

The matrix representation can be viewed as acting upon vectors in an abstract space. For example, a space with an odd number of dimensions (2ℓ+1) can be constructed from the spherical harmonics Y_ℓ^m, and their transformations under infinitesimal rotations.^[9]

The construction of irreducible matrices of any dimension at all is done as follows. If the generator of an infinitesimal rotation is labeled J where J = S or L or L + S, for example, then the basis vectors in this space can be labeled by the integers j and m where m is restricted to the values { −j, −j+1, ... , j−1, j }. Denoting a basis vector by |j, m⟩, one finds:

${\displaystyle J^{2}|j,\ m\rangle =j(j+1)|j,\ m\rangle \ ,}$

${\displaystyle J_{z}|j,\ m\rangle =m|j,\ m\rangle \ .}$

Here J_z generates an infinitesimal rotation about a direction chosen as the z-axis, and J² = J_x² + J_y² + J_z² is the so-called Casimir operator.^[10] In particular, these equations recover the Pauli matrices in two dimensions and the infinitesimal transformations of the Y_ℓ^m in (2ℓ+1) dimensions.^[11]

Of course, the formalism has application to other elementary particles as well.

Other symmetries

The symmetry of a crystal is described by one of the space groups, a set of transformations that includes certain particular rotations, reflections, translations, and operations called glides and screws. Subgroups of the space groups are the so-called point groups that include only certain rotations and reflections, and apply to a subset of crystal symmetries. Thus, an atom in a crystal does not find itself in a situation of spherical symmetry.

Nonetheless, the atom may maintain much of the behavior it exhibits under spherical symmetry, and that higher symmetry situation can be a good starting point for some materials. For others, the atomic symmetry is too distorted by the crystal environment, and a beginning point is based upon the electronic energy bands of the solid, which incorporate the space group symmetry.^[12] As described by Kubler:^[13] "We abandon the quantum numbers of the free atom states and try to work out a magnetic solution in the band picture."

Dynamics

The dynamic aspect introduces the proportionality between magnetic moment and angular momentum using the gyromagnetic ratio, and attempts to explain its origin based upon quantum electrodynamics.

Angular momentum is introduced as proportional to the generator of an infinitesimal rotation, and is related to the same commutation relations, but with a proportionality factor of ℏ. Thus, in general ℏJ is an angular momentum, which clearly extends the idea of angular momentum far beyond the intuitive classical concept that applies in only three-dimensional space.

The magnetic moment m_S of a system of electrons with spin S is:^[14]

${\displaystyle \mathbf {m_{S}} =2m_{B}\mathbf {S} \ ,}$

and the magnetic moment m_L of an electronic orbital motion L is:

${\displaystyle \mathbf {m_{L}} =m_{B}\mathbf {L} \ .}$

Here the factor m_B refers to the Bohr magneton, defined by:

${\displaystyle m_{B}={\frac {e\hbar }{2m_{e}}}\ ,}$

with e = the electron charge, ℏ = Planck's constant divided by 2π, and m_e = the electron mass. These relations are generalized using the g-factor:

${\displaystyle \mathbf {m_{J}} =gm_{B}\ \mathbf {J} \ ,}$

with g=2 for spin (J = S) and g=1 for orbital motion (J = L).^[15] As mentioned earlier, where both spin and orbital motion are present, they combine by vector addition:^[16]

${\displaystyle \mathbf {J=L+S} \ .}$

The magnetic moment of an atom of angular momentum ℏJ is

${\displaystyle \mathbf {m_{J}} =gm_{B}\mathbf {J} \ ,}$

with g now the Landé g-factor or spectroscopic splitting factor:^[17]

${\displaystyle g={\frac {3}{2}}+{\frac {S(S+1)-L(L+1)}{2J(J+1)}}\ .}$

This form assumes the LS coupling scheme in which all the orbital angular momenta couple to form L and all the spins to form S.

If an atom with this associated magnetic moment now is subjected to a magnetic flux, it will experience a torque due to the applied field.

This approach is approximate because spin and orbital angular momentum are coupled (the so-called spin-orbit coupling), an important influence in heavier atoms or highly ionized atoms. For atoms where this coupling is strong, a scheme called jj-coupling is more accurate. In this scheme the orbital and spin momenta of each electron are combined separately and then all the individual j-values are added to get the total J.^[18]

Because atoms in solids experience a lower symmetry than isolated atoms, they may require a different treatment, for example, one based upon itinerant electrons.^[19]

Notes