Toroidal moment
A toroidal moment is an independent term in the multipole expansion of electromagnetic fields besides magnetic and electric multipoles. In the electrostatic multipole expansion, all charge and current distributions can be expanded into a complete set of electric and magnetic multipole coefficients. However, additional terms arise in an electrodynamic multipole expansion. The coefficients of these terms are given by the toroidal multipole moments as well as time derivatives of the electric and magnetic multipole moments. While electric dipoles can be understood as separated charges and magnetic dipoles as circular currents, axial toroidal dipoles describes toroidal charge arrangements whereas polar toroidal dipole correspond to the field of a solenoid bent into a torus.
Classical toroidal dipole moment
A complicated expression allows the current density J to be written as a sum of electric, magnetic, and toroidal moments using Cartesian or spherical differential operators. The lowest order toroidal term is the toroidal dipole. Its magnitude along direction i is given bySince this term arises only in an expansion of the current density to second order, it generally vanishes in a long-wavelength approximation.
However, a recent study comes to the result that the toroidal multipole moments are not a separate multipole family, but rather higher order terms of the electric multipole moments.
Quantum toroidal dipole moment
In 1957, Yakov Zel'dovich found that because the weak interaction violates parity symmetry, a spin Dirac particle must have a toroidal dipole moment, also known as an anapole moment, in addition to the usual electric and magnetic dipoles. The interaction of this term is most easily understood in the non-relativistic limit, where the Hamiltonian iswhere d, μ, and a are the electric, magnetic, and anapole moments, respectively, and σ is the vector of Pauli matrices.
The nuclear toroidal moment of cesium was measured in 1997 by Wood et al..
Symmetry properties of dipole moments
All dipole moments are vectors which can be distinguished by their differing symmetries under spatial inversion and time reversal. Either the dipole moment stays invariant under the symmetry transformation or it changes its direction :Dipole moment | P | T |
axial toroidal dipole moment | +1 | +1 |
electric dipole moment | −1 | +1 |
magnetic dipole moment | +1 | −1 |
polar toroidal dipole moment | −1 | −1 |
Magnetic toroidal moments in condensed matter physics
In condensed matter magnetic toroidal order can be induced by different mechanisms:- Order of localized spins breaking spatial inversion and time reversal. The resulting toroidal moment is described by a sum of cross products of the spins Si of the magnetic ions and their positions ri within the magnetic unit cell: T = ∑i ri × Si
- Formation of vortices by delocalized magnetic moments.
- On-site orbital currents.
- Orbital loop currents have been proposed in copper oxides superconductors that might be important to understand high-temperature superconductivity. Experimental verification of symmetry-breaking by such orbital currents has been claimed in cuprates through polarized neutron-scattering.
Magnetic toroidal moment and its relation to the magnetoelectric effect
Ferrotoroidicity in condensed matter physics
A phase transition to spontaneous long-range order of microscopic magnetic toroidal moments has been termed "ferrotoroidicity". It is expected to fill the symmetry schemes of primary ferroics with a space-odd, time-odd macroscopic order parameter. A ferrotoroidic material would exhibit domains which could be switched by an appropriate field, e.g. a magnetic field curl. Both of these hallmark properties of a ferroic state have been demonstrated in an artificial ferrotoroidic model system based on a nanomagnetic arrayThe existence of ferrotoroidicity is still under debate and clear-cut evidence has not been presented yet—mostly due to the difficulty to distinguish ferrotoroidicity from antiferromagnetic order, as both have no net magnetization and the order parameter symmetry is the same.
Anapole dark matter
All CPT self-conjugate particles, in particular the Majorana fermion, are forbidden from having any multipole moments other than toroidal moments.At tree level, an anapole-only particle interacts only with external currents, not with free-space electromagnetic fields, and the interaction cross-section diminishes as the particle velocity slows. For this reason, heavy Majorana fermions have been suggested as plausible candidates for cold dark matter.
Literature
- Stefan Nanz: . Springer 2016.