Dynamical anisotropic magnetoelectric effects at ferroelectric/ferromagnetic insulator interfaces

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Li Yaojin, Koval Vladimir, Jia Chenglong. Dynamical anisotropic magnetoelectric effects at ferroelectric/ferromagnetic insulator interfaces. Chinese Physics B, 2019, 28(9): 097501 Copy to clipboard

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Dynamical anisotropic magnetoelectric effects at ferroelectric/ferromagnetic insulator interfaces

Li Yaojin^{1, 2}, Koval Vladimir³, Jia Chenglong^{1, †}

1Key Laboratory for Magnetism and Magnetic Materials of Ministry of Education, Lanzhou University, Lanzhou 730000, China

2Electronic Materials Research Laboratory International Center for Dielectric Research, Xi’an Jiaotong University, Xi’an 710049, China

3Institute of Materials Research, Slovak Academy of Sciences Watsonova 47, 04001 Kosice, Slovakia

† Corresponding author. E-mail: cljia@lzu.edu.cn

Abstract

The interfacial magnetoelectric interaction originating from multi-orbital hopping processes with ferroelectric-associated vector potential is theoretically investigated for complex-oxide composite structures. Large mismatch in the electrical permittivity of the ferroelectric and ferromagnetic materials gives rise to giant anisotropic magnetoelectric effects at their interface. Our study reveals a strong linear dynamic magnetoelectric coupling which genuinely results in electric control of magnetic susceptibility. The constitutive conditions for negative refractive index of multiferroic composites are determined by the analysis of light propagation.

PACS: 75.30.Cr;75.50.Dd;78.20.Ci

Keyword:interfacial magnetoelectric effect;ferromagnetic insulator;magnetic susceptibility;refractive index

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1. Introduction

The study on the magnetic response of materials subjected to an external electric fields has generated great interest from both fundamental physics and potential application perspectives.^[1–8] In particular, the direct coupling between electrical and magnetic polarization allows for purely electrical manipulation of magnetism with promising multi-functionality and low energy consumption. From the symmetry point of view, the magnetoelectric (ME) interactions can only develop in systems with both time-reversal and spatial-inversion symmetry breaking,^[2] such as single phase magnetoelectric hexaferrites,^[9] multiferroic bismuth ferrites^[10] or ferroelectric/ferromagnetic (FE/FM) composite structures.^[11] For single phase multiferroics, the mechanisms of ferroelectricity with spin origin have been identified^[9,12] and the multiferroic response is well documented experimentally and theoretically.^[13] On the other hand, a comprehensive understanding of coupling between spin and charge degrees of freedoms in the insulating interface state of composite multiferroics is still missing. In artificial FE/FM multiferroics, the studies on the interfacial ME effect have thus far remained interesting such as the electrostatic screening effect,^[5,14–17] ionic liquid gating,^[18–20] orbital reconstruction,^[20–24] etc. However, this electric field effect can be ruled out in case of the FM insulator (FMI) interfaces due to the absence of mobile charge carriers.

In this paper, the non-local FE-associated vector potential is demonstrated to give rise to an anisotropic ME interaction through the multiorbital hopping occurring in FMI. The large electrical permittivity mismatch between FE and FMI is found to bring about a significant enhancement of the interfacial ME effects. The dynamic magnetic response driven by electromagnetic waves via strong linear ME coupling is investigated in detail. The electrical tuning of magnetic permeability in FE/FMI is discussed as well. Moreover, the negative refractive index is possible in the FM system with small electric permittivity. All these findings not only contribute to the current understanding of the magnetoelectric effects in composite structures but also fetch in a new perspective to nanoscale composite multiferroics.

2. Theoretical model

Let us consider lightly doped manganese oxides La_1−xSr_xMnO₃ (LSMO with ) as the potential candidates of FMI in our setup.^[25] The phase diagram of LSMO is well established^[26,27] and the metallic La_1−xSr_xMnO₃ ( ) has been used for multiferroic heterosturctures.^[28–32] A selected list of values for the magnetoelectric coupling constant of artificial multiferroic systems based on LSMO is given in Table 1.

Table 1.

Values of the magneto-electric coupling coefficient, α, reported in the literature for selected multiferroic heterostructures. T is the temperature and LSMO stands for La_1−xSr_xMnO₃.

In these perovskite systems, the five (Mn) d-orbitals split under the octahedral crystal field into three lower and two upper orbitals, the Jahn–Teller distortions further lift the double degeneracy of orbitals.^[33,34] The three electrons are mainly localised, whereas the electrons are mobile and hopping between Mn ions through the bridge of O p-orbitals. All spins in the active shell are aligned parallel to each other by a strong Hund coupling. The ME properties can be obtained from the two-orbitals Kondo lattice model with large on-site Hubbard interactions^[35–38]

where α and β denote two

orbitals, respectively.

is the destruction operator of an itinerant electron with spin

. t_ij describes the hoping between i and j sites, more precisely, between filled and empty orbitals at different sites, which is essential for the ME interaction.

is the Hund coupling,

is the spin of the itinerant electron on the orbital α at site i, and the local spin

is approximated by a classical spin.

is energy splitting between the two orbitals at site i, and

describes the Coulomb repulsion with

being the total number of itinerant electrons on the site. For

, an electron jumping between nearest-neighbor sites does not require energy (

), if all the spins are parallel. Hence, double exchange and FM ordering occur in the system.^[40–42] On the other hand, the hoping terms involving only single-orbital per site with the limit of large U result in the t–J model with antiferromagnetic interaction.^[43] Here, to second order perturbations of multi-orbital hopping, one gets an effective ferromagnetic interaction between the spins^[38]

where

and

is the unit vector along the local spin

By interfacing FMI layer with FE films, the effective electric field develops in FMI. Taking into account the boundary conditions for the electric field at the interfaces between materials^[39]

where

is a unit vector normal to the FE/FMI interface (hereafter we take

, the z axis has its origin at the FMI interface),

and

are the displacement field in FE and FMI, respectively, the vanishing of free charges (i.e.,

) at the insulator interfaces leads to

where

is the dielectric constant of FE and FMI. Considering

with

being an applied electric field by gate voltage, the normal component of the effective electric field

in FMI is significantly enhanced up to several orders (

) compared with the other two in-plane components

. As a consequence, giant anisotropic electric-field effects are expected in composite FE/FMI heterostructures.

In presence of electric field, the hopping amplitude can be modified in a gauge-invariant manner with the Peierls substitution,^[44,45] , where is the vector potential associated with effective electric field in FMI. The third order perturbation of hopping yields to the following interfacial ME interactions:

where

is the dimensionless coupling strength and describes the spin energy change due the electron hopping from site i to site j.

is related to the spin interactions that do not originate from exchange processes.

The low dimensionality of the FM film would lead to a uniaxial magnetic anisotropy, . The anisotropy depends on the FM film thickness , , where describes the surface anisotropy contributions, which are significant for ultra-thin film with magnetization aligned normal to the surface, whereas, denotes the demagnetization field that is equivalent to an easy in-plane contribution. Following the above ME discussion, an effective energy density in the continuous limit to the lowest order of can be written as

where the exchange constant

represents the effective ME interaction,

in which the first and the second terms describe the static and dynamic ME contributions, respectively.

3. Results and discussion

3.1. Static ME effects

By rewriting the magnetization , , in the spherical coordinates, the minimum of yields the Néel wall-like magnetization configuration. With further considering the Dzyaloshinskii–Moriya interaction stemming from the parity breaking of the lattice at the interfaces, an exponential spiral magnetization (analogous to that in FE/FM metal interface^[15]) and even magnetic skyrmions or bubbles, can develop instead,

where z₀ is the initial position and

with λ being the coherence length of the ME coupling. It should be pointed out that an initial ferromagnetic configuration is considered in the derivation of the above interfacial magnetization. Note that the sign of λ depends on the anisotropy

and the external electric field;

. Along with the boundary conditions determined by the magnetic anisotropy: (i)

for out-of-plane magnetization with

or (ii)

for in-plane magnetization with

, one can find that the interfacial nonlinear magnetization can be triggered by only and if only an outward external electric field from the FMI interface, i.e.,

. This selection rule of the interfacial ME coupling holds promising ways for the electric field-control of domain-wall excitations. On the other hand, following the arguments of ferroelectricity of spin origin,^[15,46,47] an inhomogeneous charge distribution can exist due to nonlinear magnetic moments at the interface.^[15] As for the typical values:

meV,

mC/cm²,

/cm, and the lattice constant of FMI

, we obtain a weak (∼0.1 meV) but long-range (

nm) static interfacial ME interaction, which is most pronounced in the vicinity of FE/FMI interface acting with the ME coherence length λ of the order of submicrometers.

3.2. Dynamic ME effects

Without losing of generality, we assume an out-of-plane magnetization, which can be excited by applied (transversal) rf fields ,

where γ is the gyro-magnetic ratio defined as

with the G-factor g and the Bohr magneton

. Introducing the above Landau–Lifshitz equation into the ME interaction, Eq. (8), a linear dynamic ME coupling in the lowest order can be expressed as

where

is the driving rf magnetic field and

is the magnetic permeability of FMI.

(

) is the rf electric field. According to Eq. (4), the most pronounced dynamic ME coupling occurs if as the rf electric field normal to the interface, i.e.,

, then, the coupling constant reads

It should be pointed out that such linear ME effects can be enhanced further in the resonance regime through the magnetic permeability. For typical vaule , the coupling is estimated to be s/m. The does not involve the enhancement ratio and it is clearly several orders weaker. As a result, the strongly anisotropic interfacial ME effects appear in the system.

3.3. Transformable magnetic susceptibility

Phenomenologically, the linear ME coupling may result in an additional ME contribution to the magnetization^[2,28]

where

is the magnetic susceptibility of FMI,

for isotropic materials. The rf electric fields satisfy the Maxwell–Faraday equation,

. Taking the propagation of microwave as the

direction and

, one gets

where c is the speed of light in vacuum,

is the complex refractive index in FMI, and

is an antisymmetric tensor. By introducing

into Eq. (13), one obtains

Assuming that and , the effective magnetic susceptibility, reads then

which can be measured by a very sensitive technique, for instance, ferromagnetic resonance (FMR) spectroscopy. Due to the linear ME interaction, the magnetization dynamics is simultaneously influenced by the ac magnetic field

and the ac electric field

.^[49] The FMR spectrum, thus, is not of a pure absorptive Lorentz mode but an interference mode between the in-phase dispersive (

) and out-of-phase absorptive (

) modes. Furthermore, the mixture phase φ is angular-dependent and electric field-dependent as well, which offers electrical tuning of transformable magnetic susceptibility. More importantly, possible negative magnetic susceptibility could be obtained as

. Our recent direct permeability measurements confirmed these dynamic ME effects,^[50] in which the linear ME coupling is around

s/m in Co/BaTiO₃^[51] and CoZr/PMN-PT films.^[49]

3.4. Negative refraction

In order to explore the effects of the FE/FM interface on the refractive index , the light propagation in the FE/FM heterostructures was investigated. Considering the bound current near the FE/FMI interface, can be rewritten in the linear response as

where

is the Fourier transformation of the electromagnetic vector potential with the magnetic flux density field

and electric field

. In presence of linear ME effects (cf. Eq. (13), there are three different contributions to the bound current: (i) the magnetization current (ii) the polarization current

with

being the electric susceptibility of FMI, and (iii) the magnetoelectric current Assuming the propagation of light in the y direction,

, the bound current then reads

The Maxwell equation in the Lorentz gauge yields the following equation for the refractive index

For the case of

, similar equation is obtained but with the replacement of

. It is obvious that we get a standard refractive index

in the absence of any ME coupling. Considering ME interactions at the FE/FM interface, a large modification in the refraction index is obtained. For

and the limit of

, equation (20) gives two approximate solutions,

Note that

(with

being the phase velocity of light in materials), thus we might have negative refraction

in natural nanoscale FE/FM heterostructures. Such negative refraction can exist as well in natural ferromagnetic metals such as nickel, iron, or cobalt at a frequency close to the ferromagnetic resonance if the strength of the mode is large enough.^[52]

4. Conclusion

In summary, we have shown that magnetoelectric interactions may develop at the FE/FMI interface due to the non-local hopping between multi-orbitals. The large mismatch in dielectric constant of FE and FMI was found to give rise to giant anisotropic electric field effects on magnetization. The interfacial linear dynamic magnetoelectric coupling together with the transformable magnetic susceptibility and the negative refractive index were successfully described. It should be emphasized that the proposed dynamic ME effects are intrinsic phenomena occurring in multiferroic systems with strong linear magnetoelectric interaction and small enough electric permittivity. The predicted properties are of a huge importance in designing in a new class of optical negative-index metamaterials and the obtained results provide new perspectives for construction of the next-generation electronic components based on nanoscale composite multiferroics.

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