Light-driven motion of charged domain walls in isolated ferroelectrics

Abstract: Light-induced ferroelectric domain wall motion turns out to be a promising phenomenon to develop new photo-controlled devices. However, the physical origin of this ligh-matter coupling when material is irradiated with visible light remains unclear. Here, a phenomenological model predicting the motion of charged domain walls (CDWs) is developed. The photo-induced electronic reconstruction mechanism is proposed as the primary absorption mechanism, leading to a linear dependence for the polarization perturbation … Show more

“…The investigation is prompted by our prior exploration of visible-light-induced deformation in BaTiO 3 , which demonstrated the feasibility of controlling the strain by visible light in a ferroelectric crystal. 7 , 8 , 46 Here, we observe a remarkable macroscopic elongation of approximately 300 nm along the Y -direction ( Figure 4 a), accompanied by a contraction of about 200 nm in the X -direction ( Figure 4 b). In relative terms, the photostrain along the Y -axis is +0.006%, while the contraction along the X -axis is −0.004%.…”

“…As a consequence of these electric fields, ferroelectric domain movements lead to local electric polarization and atomic displacements that are induced at the interface. ,,, The magnetoelectric effect, specifically the converse, involves a variation of magnetization ( M ) due to the application of an electric field ( E ) according to the relation Δ M = α C ·Δ E , where α C represents the magnetoelectric coupling coefficient. Studies have demonstrated significant modifications in the magnetic properties of multiferroic structures with the application of an electric field, including M s modulations of up to 10%. ,, In our case, the incidence of light modifies the domain wall compensation such that the depolarization field inside each domain changes, thereby triggering the domain wall motion . Likewise, the charge-mediated mechanism is claimed to generate an electric polarization at the interface that leads to changes in the oxidation and spin state of the Fe cations, which are responsible for the variations in M s . , To verify this, we conducted XPS measurements on the Fe 2p core level to identify potential electronic variations in the Fe 2+ and Fe 3+ populations on the surface.…”

“…To comprehend the variations in magnetic behavior induced by light on the Fe 3 O 4 /BaTiO 3 heterostructure ( M r , HC, and M s ), we need to scrutinize the changes in the ferroelectric domain structure and the macroscopic elongation and local strain of the BaTiO 3 substrate. The investigation is prompted by our prior exploration of visible-light-induced deformation in BaTiO 3 , which demonstrated the feasibility of controlling the strain by visible light in a ferroelectric crystal. ,, Here, we observe a remarkable macroscopic elongation of approximately 300 nm along the Y -direction (Figure a), accompanied by a contraction of about 200 nm in the X -direction (Figure b). In relative terms, the photostrain along the Y -axis is +0.006%, while the contraction along the X -axis is −0.004%.…”

Concomitant Light-Reversible Magnetic Response in Multiferroic Oxide Heterostructures for Multiphysics Applications

“…The investigation is prompted by our prior exploration of visible-light-induced deformation in BaTiO 3 , which demonstrated the feasibility of controlling the strain by visible light in a ferroelectric crystal. 7 , 8 , 46 Here, we observe a remarkable macroscopic elongation of approximately 300 nm along the Y -direction ( Figure 4 a), accompanied by a contraction of about 200 nm in the X -direction ( Figure 4 b). In relative terms, the photostrain along the Y -axis is +0.006%, while the contraction along the X -axis is −0.004%.…”

“…As a consequence of these electric fields, ferroelectric domain movements lead to local electric polarization and atomic displacements that are induced at the interface. ,,, The magnetoelectric effect, specifically the converse, involves a variation of magnetization ( M ) due to the application of an electric field ( E ) according to the relation Δ M = α C ·Δ E , where α C represents the magnetoelectric coupling coefficient. Studies have demonstrated significant modifications in the magnetic properties of multiferroic structures with the application of an electric field, including M s modulations of up to 10%. ,, In our case, the incidence of light modifies the domain wall compensation such that the depolarization field inside each domain changes, thereby triggering the domain wall motion . Likewise, the charge-mediated mechanism is claimed to generate an electric polarization at the interface that leads to changes in the oxidation and spin state of the Fe cations, which are responsible for the variations in M s . , To verify this, we conducted XPS measurements on the Fe 2p core level to identify potential electronic variations in the Fe 2+ and Fe 3+ populations on the surface.…”

“…To comprehend the variations in magnetic behavior induced by light on the Fe 3 O 4 /BaTiO 3 heterostructure ( M r , HC, and M s ), we need to scrutinize the changes in the ferroelectric domain structure and the macroscopic elongation and local strain of the BaTiO 3 substrate. The investigation is prompted by our prior exploration of visible-light-induced deformation in BaTiO 3 , which demonstrated the feasibility of controlling the strain by visible light in a ferroelectric crystal. ,, Here, we observe a remarkable macroscopic elongation of approximately 300 nm along the Y -direction (Figure a), accompanied by a contraction of about 200 nm in the X -direction (Figure b). In relative terms, the photostrain along the Y -axis is +0.006%, while the contraction along the X -axis is −0.004%.…”

Concomitant Light-Reversible Magnetic Response in Multiferroic Oxide Heterostructures for Multiphysics Applications

“…The light-driven domain wall motion has been postulated as the main mechanism for the control of strain in BTO. 21,24 In the particular case of the here studied FeAl/BTO heterostructure, the highly oriented domain structure of BTO gives rise to a strong anisotropic strain (Fig. 2a and b) that is responsible for optical modulation of the magnetic properties of the Fe 75 Al 25 film.…”

“…The visible-light-induced deformation of the FeAl/BTO heterostructure is explored as a first step to evidence that a strain-mediated light-control of magnetic properties is possible in this engineered magnetostrictive-ferroelectric heterostructure. Since the light-induced macroscopic strain in BTO originates mainly from the light-driven motion of the domain walls, 18,24 an anisotropic strain should be expected. Results show a significant macroscopic elongation of ∼270 nm in the direction perpendicular to the domain walls arrangement upon light illumination (Fig.…”

Reversible optical control of magnetism in engineered artificial multiferroics

Light-induced strain and its correlation with the optical absorption at charged domain walls in polycrystalline ferroelectrics