scientific commentaries\(\def\hfill{\hskip 5em}\def\hfil{\hskip 3em}\def\eqno#1{\hfil {#1}}\)

STRUCTURAL SCIENCE CRYSTAL ENGINEERING MATERIALS

ISSN: 2052-5206

Volume 72| Part 1| February 2016| Pages 1-2

doi:10.1107/S2052520616001062

Free 

Polarization in RMnO₃ multiferroics

A. N. Pirogov^a,b*

^aInstitute of Metal Physics of UB of RAS, Ekaterinburg, Russia, and ^bUral Federal University, Ekaterinburg, Russia
^*Correspondence e-mail: pirogov05@gmail.com

Some comments on the review by Sim et al. [(2016). Acta Cryst. B72, 3–19] are given. The review is devoted to hexagonal multiferroics RMnO₃, in which there are ferroelectric and magnetic orders. Strong interaction between these orders causes a series of interesting properties of multiferroics.

Keywords: multiferroic materials; ferroelectricity; magnetic structures; magnetic frustration; spin-phonon coupling.

The review of Sim et al. (2016) is devoted to multiferroics RMnO₃ (R = Ho–Lu and Y) which possess a hexagonal crystal structure. Multiferroics are the class of crystalline materials in which at least two order parameters exist simultaneously: ferro(or anti)ferromagnetic, ferroelectric and ferroelastic degrees of freedom. Although multierroics have been studied for 60 years (Astrov, 1960; Folen et al., 1961), intensive research only started in the current century (Wang et al., 2009; Khomskii, 2009; Chupis, 2011). The revival is explained by the possible application of multiferroics as magnetic sensors, capacity electromagnets, elements of magnetic memory etc. One of the features of multiferroic devices is the absence of thermal loss because there is no need to pass electric currents through them.

The above-mentioned review describes multiferroics with antiferromagnetic and ferroelectric orders. An interaction between these orders is realized through a crystal lattice; therefore, effects such as phonons, magnons and spin-phonon coupling can exist. These effects together with the description of crystal and magnetic structures of hexagonal RMnO₃ multiferroics, are presented in the review. Hexagonal multiferroics are related to the group of improper ferroelectrics. If a material is non-ferroelectric, it is characterized by a single energy potential in terms of polarization, having its minimum at zero polarization. Proper ferroelectrics are defined by a double-well potential and minimum energy at non-zero polarization. In proper multiferroics a relative displacement of the metallic sublattice in regard to the oxygen sublattice results in a spontaneous polarization, which is the primary order parameter in the ferroelectric transition. Improper ferroelectrics are characterized by single-well energy potential. The ferroelectric transition is driven by an unstable non-polar mode, which is linearly coupled with the polar mode, decreasing the energy of the latter and inducing a non-zero polarization. In improper ferroelectrics, the spontaneous polarization is a second-order parameter coupled to a primary non-polar lattice distortion.

In both groups of multiferroics the coupling between the electric polarization and a magnetic field or between the magnetization and an electric field is called a magnetoelectric effect. This effect can be observed in the appearance of the electric polarization as proportional to a magnetic field and vice versa arising of the magnetization proportional to the electric field. The necessary condition for the existence of a linear magnetoelectric effect in a material is a violation of space and time parities separately, and a conservation of the combined space-time parity. As an example, the value of the magnetoelectric effect in YMnO₃ is ∼ 5.5 µC cm⁻². The much larger values of this coefficient (by two or three orders) are achieved in composite materials, in which magnetostrictive and piezoelectric layers alternate.

Experimentally the polarization is determined by measuring the electric current going through a ferroelectric capacitor when the polarization is switched. The magnitude of spontaneous polarization can also be estimated by means of calculations which apply Born effective charges Z^* and distortions τ from a centrosymmetric structure to the ferroelectric phase

where Ω is the unit-cell volume. The polarization can also be more accurately obtained using a Berry phase approximation (Resta, 1994).

Using group theoretical analysis it was found (Fennie & Rabe, 2005) that the zone-boundary K₃ mode and a polar zone-center mode are the dominant modes in the ferroelectric distortion that relates the high-temperature paraelectric phase P6₃/mmc and the low-temperature ferroelectric phase P6₃cm of YMnO₃. The hexagonal lattice of RMnO₃ multiferroics belongs to geometrically frustrated structures. Fig. 1 illustrates frustration on a simple example of a triangular lattice. How should the spin in the upper vertex of the triangle be oriented such that it is antiferromagnetically ordered with respect to the other two spins?

Figure 1 Illustration of frustration in a simple triangular lattice.

In the review by Sim et al. (2016) the physical properties of only bulk multiferroics are described. Recently the first experiments were carried out on nanocrystalline materials and films of YMnO₃ (Bergum et al., 2011). Results of these experiments show that the c lattice parameter increases with film thickness.

It is worthwhile mentioning materials that are not multiferroics but exhibit similar properties. For example, in the system BaTiO₃/Fe magnetic order extends in segnetoelectric BaTiO₃ across nanometer distances (Valencia et al., 2011). Another example of materials which can show similar properties to multiferroics is topological isolators (Kopaev et al., 2011). A band-gap forms and a strong magnetoelectric effect arises if a topological isolator covered by magnetic film is located in the magnetic field.