For many years strontium titanate SrTiO3 has been the workbench where disruptive concepts and properties in solid state physics have been explored, discovered and tested1. Upon cooling, SrTiO3 (STO) displays2 a transition from a cubic phase (C) to a tetragonal (T), centrosymmetric phase at TCT ≈ 105 K. This structural transition involves octahedra rotations along all three cubic axis and it is accompanied by elastic strains3,4. It was earlier recognized, that temperature-dependent electrical permittivity of STO displayed Curie-like behavior down to ≈35 K signaling a strong tendency towards a ferroelectric instability. However, no ferroelectricity was observed and it was argued that this was blocked by quantum fluctuations and STO is understood as a quantum paraelectric5. Associated with the C-T transition, ferroelastic twin domains (FTD) are formed. It has been found that upon cooling, the population of distinctly oriented FTD remains basically unperturbed6,7,8. However, application of electric fields or strain promotes reordering of FTD7 and even the appearance of ferroelectric signatures9,10, including switchable ferroelectric Bloch lines11,12,13, emerging at T ≤ 50 K. Moreover, as the T-phase results from a cooperative rotation of octahedra, regions with clockwise and anti-clockwise rotation should exist, producing antiphase boundaries (APB). Concomitantly, domain walls (DWs) are formed where local symmetry can be further lowered; the interplay of coexisting domains and DWs, both potentially responsive to external stimuli, challenges detailed understanding of the STO properties. The consensus achieved could be summarized as follows: i) bulk STO can be driven to be polar under suitably large electric field or mechanical stress9,10, ii) at ≈80 K, the local symmetry is reduced to a triclinic-like11,14,15,16 and iii) ferroelastic DWs display a polar response, incipient at ≈105 K12, but clearly visible at T1* (≈80 K) and further enhanced below T2* (≈45 K)6,11.

STO is also the most used substrate for epitaxial growth of functional oxides of interest in spintronics, ferroelectric memories, etc. where it acts as an “inert” substrate and only epitaxial strain arising from structural mismatch with overgrown films, has been exploited to modulate film’s properties8,17. Imposed by the continuity of the metal-oxygen coordination polyhedral network, the elastic coupling across interface transmits any structural transformation of the substrate into the overgrown thin film18. Indeed, it has been shown that the magnetization of a La1−xSrxMnO3 (LSMO) thin film grown on STO(100) displays remarkable changes upon crossing TCT19,20,21,22, which were attributed to changes of the LSMO magnetic domain structure when shacked by the structural transition occurring in STO19,20,21.

Here, we shall demonstrate that STO can be used as “active” substrate to modify the magnetic properties of a LSMO epitaxial overlayer, namely the magnetic domain configuration, by exploiting its various low-temperature structural transformations and the presence of polar nanoregions at DWs. The results here presented constitute a fresh example of making use of the polar nature of domain walls in one layer to manipulate the magnetic domains in a neighboring layer. This approach differs in its essence from the much investigated strain control - including through piezoelectric substrates - of the magnetic properties of LSMO and other oxides23,24,25, where domains rather than DWs are the primarily responsive elements of the substrate. To enhance the sensitivity of the magnetic structure of the manganite layer to tiny structural changes, the LSMO composition has been chosen to be close to the verge of the ferromagnetic-antiferromagnetic phase transition; this is achieved in La1/2Sr1/2MnO326,27; an instability further reinforced by the tensile strain imposed by the STO substrate27. Moreover, it will be shown that upon applying a suitable electric field to the STO substrate, an unparalleled response and even a reversal of magnetic moment (m) of the LSMO layer can be obtained.


Oxide epitaxial heterostructures

Several LSMO thin films of different thickness were grown on 0.5 mm thick STO(001) single crystals. Data reported here correspond to films of 34 nm and 10 nm. The STO substrate induces a tensile strain (1.5%). X-ray measurements have been done to assess the quality of the films, their strain state (Supplementary Information 1) and to estimate the film thickness27. A LSMO film (20 nm) was grown on LaAlO3(001) single crystalline substrate under identical conditions, for comparison purposes27.

Magnetic properties of films

The 34 nm thick LSMO on STO(001) sample displays a Curie temperature and a saturation magnetization typical for strained films of this composition (Supplementary Information 2)27. The low temperature magnetic moment (m(T)) data (Fig. 1(left-bottom)) recorded upon warming, either after magnetic field-cooling (H-FC) or after a zero-field-cooling (H-ZFC), solid and empty circles respectively, do not merge. This is a common feature of ferromagnetic systems when measured at small magnetic fields. Of more interest is the observation that the H-ZFC branch displays remarkable changes of slope at some temperatures: T0 ≈ 108 K, T1 ≈ 90 K and T2 ≈ 45 K. One immediately recognizes that T0 closely coincides with the cubic-to-tetragonal transition temperature TCT. This is a fingerprint of the magnetic domain reordering of LSMO when the STO substrate transforms to tetragonal phase and a complex array of crystalline domains is formed19,20,21. This magnetic anomaly is also visible in the H-FC branch at TCT. These changes of slope in m(T) are indications of a change of the magnetic domain structure or its stiffness. As LSMO does not present any structural transformation or prominent magnetic anisotropy change in this temperature range, the observed anomalies of m(T) at T1 and T2 should be related to modification of the magnetic domain structure associated to changes in the STO substrate.

Figure 1
figure 1

Phase diagram of SrTiO3, magnetic moment of a LSMO/STO(001) films and coupling of magnetic domains by polar domain walls in STO.

Left top: representation of the known phase diagram of STO. Left bottom: temperature dependence of the magnetic moment of LSMO films on STO(001), of thickness 34 nm and 10 nm (blue circles and red triangles, respectively), measured on warming, after cooling in zero-magnetic field from room-temperature and on cooling . Data have been collected using Hmeas = 60 Oe. For clarity, data for 34 nm and 10 nm samples have been shifted along the m-axis, to to make the H-ZFC data equal at TCT. Vertical dashed lines indicate the temperatures (TCT, T1* and T2*) where the known transformations in STO occur. Right central panel: polar domain walls in SrTiO3 whose width (horizontal double ended arrows) is modified by E-biasing. Right panel (a) illustrates the ferromagnetic domain distribution in the LSMO film, pinned by STO domain walls, under a (small) measuring magnetic field (H). Right panel (b) illustrates the domain configuration in LSMO film, under a (small) measuring magnetic field (H), when the pining strength provided by STO domain walls is reduced under E-bias.

As emphasized by sketch in Fig. 1(left-top), T1 ≈ T1* (≈90 K) - where triclinic distortions, compatible with polar DW regions develop and T2 ≈ T2* (≈45 K) - where the polar character in STO is reinforced6,11. For comparison, we include in Fig. 1(bottom) the m(T) data of a similar LSMO sample, 10 nm thick (triangles); the pronounced features at TCT, T1 and T2 can also be appreciated. These data indicate that the magnetic state of LSMO is a probe to the structural, microstructural and dielectric changes occurring at the substrate. As FTD orientation can be modified by electric fields7 and polar (piezoelectric) DWs sensitive to electric fields, are formed at temperatures below TCT11,12, it should be expected that application of a suitable electric field to the STO substrate would induce a domain and domain wall reconstruction, which in turn should impact, via interface magnetoelastic coupling, the magnetic state of the LSMO layer (Fig. 1 right).

Electrical biasing of SrTiO3 substrate. Effect on the magnetic properties of LSMO films

To demonstrate this effect, thermomagnetic curves were measured at a fixed magnetic field (Hmeas) under different constant electrical field (E) applied as indicated in Fig. 2a (see also Supplementary Information 3). Prior each run, the sample was cooled down to 5 K from , in an E-field identical to the E-field under which the corresponding thermomagnetic curve was recorded. Any possible E-field effect on the magnetic response should be more pronounced close to the magnetic coercivity field (≈60–70 Oe at 10 K, for this particular sample). This is why in the experiment of Fig. 2b, the sample was cooled down in a negative magnetic field (−65 Oe) and m(T) was measured either during the cooling process or using a positive Hmeas = 65 Oe field upon warming. The comparison of data recorded upon warming (Fig. 2b-top), under V = 0, +150 V and +210 V shows that whereas for T > 80 K, the m(T) data match those recorded at V = 0 V, this is not the case for T < 80 K where a strong dependence of m(T) on V is observed. We note that the magnetic moment measured (after the H-ZFC procedure) is smaller when m(T) measurements are performed under E-field. Further after, the m(T) data recorded during the H-FC process (Fig. 2b-bottom) (Hmeas = −65 Oe) also displays the characteristic feature at TCT ≈ 108 K and splitting between the E-ZFC and E-FC. Consistently, |m| is smaller when measured under E-field (Fig. 2b), implying electric-field induced magnetic “hardening”.

Figure 2
figure 2

Electric connection of the sample and its electric-field and temperature-dependent magnetic moment.

(a) Sketch of sample connection for electrical biasing and electric field distribution (Supplementary Information 3). Calculation has been made by using the finite elements solver COMSOL 4.4 package. Color indicates the strength of the electric field. (b) Temperature dependence of magnetic moment of a LSMO (34 nm) sample measured at different electric fields. Top: on warming, under Hmeas = +65 Oe, after cooling at different electric fields. During cooling and warming the electric field is identical. Bottom: on cooling down (Hmeas = −65 Oe), with and without electrical field applied. Prior each measurement the sample was cooled down from in magnetic field of −65 Oe.

Data in Fig. 2b indicate that an electric-field-induced modification of the crystalline domain structure of STO translates into different magnetic domain structures in the LSMO layer and therefore into magnetization differences. In this scenario, it can be expected that similar effect should be visible in isothermal measurements. We show in Fig. 3a isothermal (5 K) measurements of m as a function of the applied E-field. Prior to measurements, sample was first cooled down to 5 K under V = 0 V and nominally H = 0 Oe conditions. The measuring magnetic field Hmeas = 55 Oe was applied at 5 K and m was recorded subsequently. First, a sequence of measurements was performed for t ≈ 50 min to monitor the eventual presence of E-independent magnetic aftereffects28. As shown in Fig. 3a, the magnetic moment only varies by about 2% in 50 min. Next, an E-field step sequence (Fig. 3a (inset)) was applied as indicated. It follows from data in Fig. 3a that any V change, irrespectively of its sign, induces an increase of magnetic moment. This implies that the magnetization is driven towards its equilibrium value by V steps (Supplementary Information 4). Therefore, it should be possible to reverse the magnetic moment of the sample by a V-step, if the measurement is performed under appropriate H > 0 on a sample previously cooled down in H < 0. Indeed, this is clearly observed in Fig. 3b where m is recorded isothermally (21 K) after cooling in H = −65 Oe and measuring in +55 Oe.

Figure 3
figure 3

Isothermal changes of magnetic moment of LSMO films under E-field biasing.

Data for: LSMO (34 nm) on STO (a,b) and (20 nm) on LAO (c) are shown. (a) at T = 5 K after nominally zero-field cooling and under Hmeas = 55 Oe; Inset: voltage steps applied to the sample during magnetic measurements. (b) (top panel) at T = 21 K, after field cooling in H = −65 Oe and at Hmeas = 55 Oe; bottom panel, indicates the voltage steps applied during measurements. (c) sample LSMO(20 nm) on (001)LAO at T = 5 K, after field cooling in H = −65 Oe and at Hmeas = 230 Oe; bottom panel, indicates the voltage steps applied during measurements. The Hmeas values were chosen to be close to coercivity field of the corresponding sample. In all cases samples were cooled under V = 0. In all figures the connecting lines are guide to eyes.

The experiments described so far signal the active role of STO and its responsivity to electric field stimulus to induce changes in the magnetic state of the LSMO layer. The rationale behind is directly related to the genuine properties of the low-temperature phase of STO, namely the presence of polar regions with their concomitant piezoresponse (Fig. 1 right). It thus follows that if similar experiments were performed using substrates where this instability was absent, one should not expect any change in the magnetic state of the magnetic layer upon applying a voltage at the substrate. We have performed such experiments on a LSMO (20 nm) film grown on LaAlO3(001) (Supplementary Information 2). In Fig. 3c we show the magnetic moment measured at 5 K, after cooling in nominally H = 0, under Hmeas = 230 Oe (a value similar to the coercivity field) when successive V-steps are applied. It is obvious that the applied electric field does not modify the magnetic moment of the LSMO layer.


The results presented above show that the magnetic moment of the LSMO films, when measured in absence of electric fields (Fig. 1), displays remarkable changes at some characteristic temperatures that closely coincide with: (i) cubic-to-tetragonal structural transition, (ii) the onset of the reported lowering of symmetry to a triclinic-like phase14 where polar domain walls are formed11 and (iii) at some lower temperature, where a polar nature of the DW appears to be reinforced11. These effects connect the changes in the domain structure and DW properties11,29 of the substrate with those of the magnetic films, epitaxially clamped on its surface. In fact, coupling between ferroic domain structure in piezo substrates and overgrown films has been shown to be a suitable way to modify the magnetic properties of the latter by applying an electric field to the former30,31. The magnetic layer is thus a sensitive probe of the substrate structural transformations.

More remarkable is the observation that when cooling the sample from under an E-field, the low-temperature magnetic structure of the film is modified and thus its magnetic response changes accordingly. This observation reflects that the microstructure of the STO substrate, namely its FTD distribution is modified, during the cooling process, by the presence of E field. At this point a question arises: is the observed effect related to the already reported redistribution of twin domains due to their anisotropic electrostriction7? To address this point we note that we observe E-field effects developing at T < 90 K (Fig. 2b). In this temperature region and within the sensitivity of X-ray diffraction experiments, effects were only perceptible, when E > 8 kV/cm. Therefore, as our applied electric field (Supplementary Information 3) is estimated to be ≈2.1 kV/cm, this mechanism is unlikely to be prominent. Instead, the polar nature of nanoregions in STO, either within the domains or at the domain walls, provides a simple framework to explain the observed effects. Indeed, in the temperature-dependent m(T) experiments (Fig. 2), we have observed that substantial E-field effects emerge below ≈90 K, close to the temperature where polar domain walls have been already identified11. Therefore, the applied E-field could be effective in changing the twin domain walls in STO and correspondingly sensed by the LSMO magnetization, as observed. Consistently, an even larger effect is observed at T below ≈45 K, which is where the DWs in STO appear to reinforce their polar character and their mobility11. It is interesting to note that the applied E-field is mainly concentrated under the electrodes (Fig. 2a and S2), thus affecting only about 20% of the LSMO volume. Still the E-induced changes of |m| are remarkably large (up to 50%, see Supplementary Information 4). This indicates that substrate domain walls modification promotes magnetic avalanches in the LSMO, as commonly found in many magnetic systems32.

In brief, an applied electric field, benefiting from the presence of polar nanoregions in STO and its associated piezoresponse, produce dramatic changes in the magnetic state of an overlying layer, magnetoelastically coupled to the substrate. In an appropriate magnetic state, the magnetic moment of the films can be even reversed by an electric field applied to its substrate. These results show, for the first time, that STO can be used as active substrate and they suggest new ways to explore and exploit its properties. We strength that STO domain wall responsiveness to electric fields, due to its inherent polar nature, is at the heart of the observed response which thus constitute an example of exploiting polar domain walls to trigger a magnetic response. The experiments here reported have been made in the simplest back-contacting configuration, which although good enough to demonstrate the soaked effects, can be largely improved by suitable nanotechnology contacting procedures33. The impact of these findings can be far reaching. For instance, in the celebrated 2DEGs formed at LAO-STO (001) and (110) interfaces34 and particularly in gating experiments35,36 where large electric fields are applied across films, the piezoresponse shown here could have interesting impacts on the observed properties of the gas and their anisotropy. Finally, it is worth noticing that polar DWs are not unique to STO but other systems have been shown to have ferroelectric DWs, even offering the possibility to be operated at room temperature37. We thus conclude that our results constitute a contribution towards domain wall nanoelectronic38.


Thin film growth and structural characterization

Several La1/2Sr1/2MnO3 (LSMO) thin films of different thickness were grown on as-received 0.5 mm thick STO(001) single crystals (5 × 5 mm2) by Pulsed Laser Deposition. Films have been deposited at 725 °C in 0.2 mbar oxygen pressure with subsequent free cooling in 100 mbar oxygen pressure. The STO substrate induces a tensile strain (1.5%). X-ray measurements have been done to assess the quality of the films, their strain state (Supplementary Information 1) and to estimate the film thickness27. For comparison purposes, a LSMO film (20 nm) was grown on LaAlO3(001) single crystalline substrate under identical conditions. The growth rate has been calibrated by measuring, by X-ray reflectivity (XRR), the thickness of some on-purpose prepared films. The X-ray diffraction (XRD) and XRR measurements were carried out using Cu-Kα radiation, in a Siemens D-5000 diffractometer and a Rigaku RU-200B diffractometers. Reciprocal space maps (RSM) were collected using a Bruker 1T8 Advance diffractometer equipped with a bidimensional detector and used to determine in-plane cell parameters.

Magnetic measurements

Magnetic measurements were conducted using a SQUID magnetometer (QD) equipped with an in-house made wiring set-up that allows applying in-situ electric fields on samples. In all experiments reported here, the magnetic field has been applied in plane of the film. It turned out that all the fine details of the sample magnetic moment variations are very sensitive to the specific measuring conditions, i.e. the strength of the magnetic field in which the sample is cooled down and the strength of the magnetic field, in which the magnetic moment is recorded as well as the temperature from which the sample is cooled down and the number of measurements/cycles (magnetic history). In magnetic zero-field cooling (H-ZFC) experiments the samples are cooled down from temperatures well above TCT, in nominally zero magnetic field after carefully demagnetizing the Mu-metal shield surrounding the SQUID magnet and also quenching the magnet to get rid of the trapped field.

Electric biasing

For electric biasing, two wires were connected to the back of the crystalline substrate, along the edges of the substrate using conducting graphite paste (Fig. 2a). The distance between the wires is of about 4 mm. Electric field was applied by voltage V (up to ±210 V) using a Keithley 2400 sourcemeter to the connecting wires. Due to the geometry used in the experiment, the electric field inside the dielectric STO is inhomogeneous: mostly concentrated under the electrodes with a relatively large value (E ≈ V/d, where d is the substrate thickness), reaching up to 2.1 kV/cm for the maximum voltage used) and much smaller field E’ between the electrodes; for the used geometry, at the midline between electrodes, E’ averages to ≈0.1 kV/cm (for V = 210 V) and depends on the permittivity of STO (Supplementary information 3). When appropriate, we use E as a label of the applied electric field and accordingly, the applied fields are within the range: −2.1 kV/cm < E < +2.1 kV/cm. During measurements, the current flowing was monitored and it was always found to be limited by the sensitivity of the test set-up (<10 nA); no changes were observed either when applying 210 V at the electrodes or upon varying the temperature, confirming that no appreciable current was flowing across the device and confirming the absence of shortcuts. Magnetic measurements were typically started within 20–30 sec after setting the voltage values. It is worth mentioning that, when exploring the m(T,V) data under different V-bias, such as in Fig. 2b-top, results depend slightly on sample history.

Additional Information

How to cite this article: Fontcuberta, J. et al. Polar domain walls trigger magnetoelectric coupling. Sci. Rep. 5, 13784; doi: 10.1038/srep13784 (2015).