Ferroelectrics with a controlled oxygen-vacancy distribution by design

Abstract

Controlling and manipulating defects in materials provides an extra degree of freedom not only for enhancing physical properties but also for introducing additional functionalities. In ferroelectric oxides, an accumulation of point defects at specific boundaries often deteriorates a polarization-switching capability, but on the one hand, delivers interface-driven phenomena. At present, it remains challenging to control oxygen vacancies at will to achieve a desirable defect structure. Here, we report a practical route to designing oxygen-vacancy distributions by exploiting the interaction with transition-metal dopants. Our thin-film experiments combined with ab-initio theoretical calculations for BiFeO₃ demonstrate that isovalent dopants such as Mn³⁺ with a partly or fully electron-occupied e_g state can trap oxygen vacancies, leading to a robust polarization switching. Our approach to controlling oxygen vacancy distributions by harnessing the vacancy-trapping capability of isovalent transition-metal cations will realize the full potential of switchable polarization in ferroelectric perovskite oxides.

Introduction

Spontaneous polarization (P_s) in ferroelectrics presents unique opportunities to develop sensors, actuators, medical imaging transducers, and non-volatile random access memories^1,2,3,4. Recently, ferroelectric tunnel junctions have attracted much attention owing to their potential applications in non-destructive readout memories in high-density integration^5,6,7,8,9. In all these applications, the control of domain structures and polarization states by applying external fields are crucial to achieve desirable properties. Even though ferroelectric bulk has the insulating nature, charged domain walls stabilized by point defects act as an electrically conductive interface^{10,11,12,13,14,15}, which opens possibilities for nanoelectronics such as domain-wall memories^16,17,18. Moreover, exploiting a high mobility of defects enables to create a p–n junction that can be erased and inverted by electric fields¹⁹.

Meanwhile, an accumulation of defects at specific interfaces deteriorates the overall behaviour of polarization-switching dynamics^20,21. For the charged domain walls stabilized by oxygen vacancies, the defect kinetics determine the switching process that is accompanied by a vacancy redistribution^22,23, and thereby the device operation speed is limited by vacancy transport times²². The strong interaction with the vacancies gives rise to the clamping of domain walls^24,25,26,27 and eventually causes imprint, retention loss, and fatigue of polarization states, preventing the widespread use of ferroelectric-based memories^1,21,28,29.

For piezoelectric devices made of PbTiO₃-based ferroelectrics, the properties can be tailored by doping of lower-valent and/or higher valent cations, mainly on the Ti⁴⁺ site, by adjusting the concentration of oxygen vacancies^30,31,32,33. The doping of, e.g., Fe³⁺ increases an oxygen-vacancy concentration, and then the mobility of domain walls is reduced, leading to electromechanically hard lattices^32,34,35. By contrast, the introduction of Nb⁵⁺ decreases the concentration and then the interaction between the domain walls and the vacancies is suppressed, resulting in soft lattices^32,36,37. Despite over fifty years of intense research, it remains difficult to control the oxygen-vacancy distribution without changing its overall concentration. It is desirable to establish a design principle that can control and manipulate the vacant positions in the vicinity of the specific sites or interfaces at will with its controlled concentration.

Interaction Between Transition-Metal Cations and Oxygen Vacancies

Figure 1 shows the crystal structures of transition-metal (TM)-doped cells for DFT calculations. For the primitive cell with an oxygen vacancy (V_O^••) in P1 symmetry (Fig. 1b), the total energy (E_total) is calculated and compared; O1 and O2 are the oxygen atoms in the TM-O₆ octahedron, and their distance with TMs is ~0.2 nm, while O3 is present in the next nearest FeO₆ octahedra, and the distance of O3-TMs is lengthened to ~0.4 nm. Figure 2 displays the E_total of the defective cell with an oxygen vacancy (V_On^••) on the n^th nearest-neighbor (NN) sites (n = 1−3) with respect to TMs, where the E_total of n = 1 is set at zero. Figure 3a,b depicts the total and (selected) partial density of states (DOS) with V_O1^•• (V_O2^••) and V_O3^•• along with the partial charge densities of the states indicated by arrows. The downward E_total with increasing n shows that the system is lower in energy when V_O^•• is away from TMs, while the upward E_total features an attractive interaction between TMs and V_O^••. In an ionic picture, TM³⁺ has the following electronic configuration: Ti³⁺ with d¹, V³⁺ with d², Cr³⁺ with d³, Mn³⁺ with d⁴, Co³⁺ with d⁶, Ni³⁺ with d⁷, Cu³⁺ with d⁸. The valence states of TMs expect for Ti, Co, and Cu are confirmed by the partial magnetic moment analysis³⁸: V³⁺ with ~1.8 μ_B, Cr³⁺ with ~2.8 μ_B, Mn³⁺ with ~3.6 μ_B, Ni³⁺ with ~0.8 μ_B, where μ_B is the Bohr magneton. We note that the cells of TM = Ti, V, and Cr have a smaller E_total of n = 3 than that of n = 1, whereas those of others exhibit the smallest E_total with n = 1. These tendencies reflect the following spin configuration of TM³⁺: the e_g state for the cells of Ti, V, and Cr is empty, while that for others is partly or fully electron-occupied. The detailes of the formation energies of TM dopants in the trivalent ionic state into BiFeO₃ have been reported by Gebhardt and Rappe³⁹.

Figure 1

Crystal structures of transition-metal (TM)-doped BiFeO₃. (a) Hexagonal Bi₁₆(Fe₁₅TM)O₄₈ cell in space group R3 (Z = 3) and (b) primitive Bi₁₆(Fe₁₅TM)O₄₈ in P1 symmetry (Z = 1) for DFT calculations. As TM atoms are positioned on the three-fold axis, TMs form the shortest bonds with three O1 atoms and the next-shortest bonds with three O2. O3 is the third nearest-neighbor oxygen atom with respect to TMs. For creating the defective cells with an oxygen vacancy, we remove one oxygen atom from the primitive cell and then perform the calculations for the Bi₁₆(Fe₁₅TM)O₄₇ cell in P1 symmetry.

Figure 2

Total energies of transition-metal (TM)-doped BiFeO₃. Total energy as a function of n, where n denotes the n-th nearest neighbor (NN) site of oxygen vacancy (V_On^••) with respect to TM. As shown in Fig. 1, O1 and O2 are the 1^st-NN and 2^nd-NN oxygen atoms forming the TM-O polyhedron, respectively. The total energy of n = 1 is set at zero. A downward total energy with increasing n indicates that V_O^•• tends to keep away from TM atoms, whereas an upward total energy shows that V_O^•• is apt to be located close to the TM atoms.

Figure 3

Electronic structures of transition-metal (TM)-doped BiFeO₃. (a) Representative partial charge densities of the electronic states indicated by arrows in (b) total density of states (DOS) and partial DOS of TM atoms, where the states in the majority spin component (↑) are colored in blue while those in the minority spin component (↓) in yellow. In (b), the Fermi energy (E_F) is set at zero, and upper and lower dashed lines are the conduction band minimum and the valence band maximum, respectively. For the TM = Ti cells, the DOS of the Fe1 adjacent to V_On^•• is also shown. In each the DOS panel, the majority spin component (↑) is displayed in the right while the minority spin component (↓) in the left.

The results described above can be intuitively explained by the electronic states formed by the orbital interaction between TM-3d and adjacent O-2p. For TM = Ti, the system has Ti⁴⁺ (d⁰) and Fe1²⁺ (d⁶) because of the higher energy states of Ti-3d, where the Fermi level (E_F) is located at the electron-occupied Fe1-3d state. These results are supported by the partial magnetic moments of 0.1 μ_B for Ti-3d and 3.6 μ_B for Fe1-3d (smaller than the other Fe-3d values of ~4.1 μ_B). This can be qualitatively understood by the charge transfer: the electron of Ti³⁺ is transferred to Fe1 on the 1^st NN site with the oxygen vacancies. With respect to the valence band maximum (VBM; the lower dashed line), the Fe1-d_xy state with V_O3^•• is lower by ~0.1 eV than the Fe1-d_z2 state with V_O1^••, which is the main reason why the n = 3 cell is lower in energy than the n = 1 cell. The V cells have two occupied states of V-3d (d²) in the gap; comparing the higher gap states at the E_F, the d_yz state with V_O3^•• is lower in energy by ~0.1 eV than the d_yz state with V_O2^••, resulting in the lower E_total of n = 3. For TM = Cr, the empty gap state with the d_z2 character appears with V_O1^••, whereas there is no state in the gap with V_O3^••. Although the change in the coordinate from CrO₆ (n = 3) to CrO₅ (n = 1) splits the e_g state into the low-lying d_z2 and the high-lying d_x2−y2, this does not lead to a significant stabilization in the system, because both the states are empty. The CrO₆ structure (n = 3) maintains a regular octahedron, and the Cr-3d state is represented by t_2g³e_g⁰, which contributes to a lower E_total of n = 3. A stabilization of V^•• away from Cr has also been reported for hexagonal BaTiO₃⁴⁰. The details for TM = Mn are described later.

For TM = Co, the electronic configuration of Co³⁺ (d⁶) in O_h symmetry is expressed as t_2g⁴e_g² in the high-spin state^41,42. Regardless of the position of V^•• 40, the occupied DOS of Co-3d in the majority spin component (↑) is spread in the valence band (−5 to 0 eV), showing that one electron is present in the bonding state of e_g(↑). In this case, the electronic state is regarded as t_2g(↓)³e_g(↓)²e_g(↑)¹ rather than as t_2g(↓)³e_g(↓)²t_2g(↑)¹, in which the strong hybridization of Co-e_g with O-2p leads to a relatively small magnetic moment of Co³⁺ with ~3.0 μ_B. Comparing the energies of the d_z2-derived state (↓), we found that the cell with V_O1^•• has the low-lying state at the valence band minimum of −7.1 eV, which is mainly due to the absence of O1 (the presence of V_O1^••), along with the orbital mixing with O-2p of two apical oxygen atoms. This marked stabilization of the d_z2-derived bonding state is attributed to the lower E_total of n = 1. The Ni cells exhibit relatively complex electronic features; the electronic configuration of Ni³⁺ (d⁷) in O_h symmetry is described as t_2g⁶e_g¹. With V_O1^•• in the minority spin component (↓), the unoccupied d_x2−y2 state is present in the gap, while the d_z2-derived state is markedly stabilized and appears at the valence band minimum because of the strong hybridization with the adjacent O-2p. Although the similar feature was found in that with V_O3^••, its energy is higher by ~0.5 eV. The low-lying d_z2-derived state with V_O1^•• is responsible for the lower E_total of n = 1. For TM = Cu, the electronic configuration of Cu³⁺ (d⁸) is expressed as t_2g⁶e_g², which is supported by the empty e_g(↑) state present in the band gap. Nevertheless, the apparent orbital mixing of Cu-e_g(↑) and O-2p is clearly seen in their partial charge density (Fig. 3a) and thus result in a relatively small magnetic moment of Cu³⁺ with 0.6–0.8 μ_B. The cell with V_O3^•• has the e_g(↑) state whereas that with V_O1^•• features the low-lying d_z2 and the high-lying d_x2−y2 sates owing to the absence of O1. Also for the occupied states in the minority spin component (↓), the cell with V_O1^•• has the d_z2-derived state at ~−6.1 eV, which is lower by ~0.3 eV than that with V_O3^••, leading to the lower E_total of n = 1.

Oxygen-vacancy distributions

Figure 4 shows the V_O^•• distributions of the TM-doped cells. For TM = Ti, V, and Cr, V_O^•• does not find an energetically favourable site inside the lattice; the vacancies in the vicinity of the bottom electrode are pulled toward its interface owing to a strong depolarization field arising from the discontinuity of P_s, suggesting a formation of an V_O^••-rich layer (Fig. 4a). This defective layer has been reported for non-doped BiFeO₃ films^{22,43,44,45,46}. By contrast, the cells with TM = Mn, Co, Ni, and Cu provide a stable position of V_O^••, i.e., the 1^st NN site adjacent to the TMs. Provided that the concentration of TMs is higher than that of V_O^•• and also that the attractive interaction between V_O^•• and TMs is sufficiently strong, V_O^•• is trapped by TMs in an equilibrium state, as displayed in Fig. 4b.

Figure 4

Oxygen-vacancy distributions in capacitor form. (a) BiFeO₃ and transition-metal (TM)-doped BiFeO₃ [Bi(Fe,TM)O₃, TM = V, Cr (Ti)] and (b) TM-doped BiFeO₃ [Bi(Fe,TM)O₃, TM = Mn, Co, Ni, Cu]. The TM atoms except for Ti have a valence state of TM³⁺. As the TM = Ti cell exhibits a valence state of Ti⁴⁺ because of the presence of Fe²⁺, Ti is indicated in parenthesis in (a). In (a), oxygen vacancy (V_O^••) does not find a stable site inside the lattice and thereby accumulates at the interface with the bottom electrode, forming a V_O^••-rich layer; this defective layer is formed by an attractive interaction with negative bound charges caused by a discontinuity of spontaneous polarization (P_s). In (b), V_O^•• is stabilized adjacent to TM³⁺; provided that the concentration of TM is higher than that of V_O^•• ([V_O^••]), all of V_O^•• are trapped by TM³⁺.

For a robust switching of P_s by applying electric fields, in addition to the attractive interaction of V_O^••-TM, the doped lattice should meet the following requirements: the first is a high solubility limit of TM; the second is the stable valence state of TM³⁺; and the third is the electronic character of TM that does not lead to a significant increase in leakage current. Here, we choose Mn as a TM because of the following reasons: Mn can be introduced into the lattice in a wide composition range⁴⁷, and the valence state is controllable to Mn^3+ 48. Moreover, the empty d_x2−y2 state of the Mn cell with V_O1^•• is far above the VBM⁴⁹, and thereby a leakage current is expected to be relatively low.

Crystal structures and properties

As displayed in Fig. 5 of the X-ray diffraction reciprocal space maps (XRD-RSMs), we confirmed that the capacitors are hetero-epitaxially grown on the SrTiO₃ substrate, i.e., the [001]_pc directions of the films are normal to (001) of the substrate. For both the capacitors, we observed the superlattice reflections of 1/2 1/2 3/2 and 3/2 3/2 1/2 in addition to the fundamental ones. Figure 5c–f displays the high-resolution XRD-RSMs of the 103 _pc and 113 _pc reflections. The Ba_0.3Sr_0.7TiO₃ film exhibits the reflection with a smaller q_x value compared with the substrate. We note that the q_x position of the reflection for the Ba_0.1Sr_0.9RuO₃ electrode is almost the same as that of the Ba_0.3Sr_0.7TiO₃ film. These results show that the Ba_0.1Sr_0.9RuO₃ electrode along with the Ba_0.3Sr_0.7TiO₃ film acts as a buffer layer for reducing the lattice mismatch between BiFeO₃ (BFO) or Bi(Fe_0.95Mn_0.05)O₃ (Mn-BFO) and SrTiO₃.

Figure 5

X-ray diffraction analysis. X-ray diffraction reciprocal space maps for (a,c,d) BiFeO₃ and (b,e,f) Bi(Fe_0.95Mn_0.05)O₃ capacitors with a Ba_0.3Sr_0.7TiO₃ (300 nm)-buffered Ba_0.1Sr_0.9RuO₃ electrodes. (a,b) Maps measured using the sources of Cu-Kα + Kβ while (c,d,e,f) those measured using Cu-Kα₁. All the Mirror indices and crystallographic directions are described in the pseudo-cubic notation; ‘pc’ is omitted.

The 103 and 113 reflections are split into two spots, which is the typical character of the rhombohedral structure in R3c space group. From the peak positions of these spots, we obtained the following rhombohedral lattice parameters for the BFO film: a = 0.3984 nm, α = 89.53 deg., and V (lattice volume) = 6.32 × 10⁻² nm³, which are almost the same as those of the bulk (a = 0.3964 nm, α = 89. 43 deg. and V = 6.23 × 10⁻² nm³)⁵⁰. Because a monoclinic distortion induced by compressive stress was not found from the XRD data and the difference in the parameter a is as small as 0.5%, we think that a strain-free bulk-like lattice is obtained for the BFO film. The Mn-BFO film has a = 0.3978 nm, α = 89.59 deg., and V = 6.29 × 10⁻² nm³, indicating that the 5% Mn doping does not lead to a significant change in crystal structure and that a bulk-like lattice is also attained for the Mn-BFO film.

Figure 6a,b shows the polarization-electric field (P-E) hysteresis properties with the current profiles during the polarization switching. For the BFO capacitor, the P curve in a positive field exhibits a loop typical for normal ferroelectrics, whereas that in a negative field rounds. This feature is attributed to a markedly large leakage current at negative fields. The asymmetric hysteresis loop has been reported for as-prepared BFO films in a strained state^44,51,52. We note that the Mn-BFO capacitor presents a well-saturated hysteresis loop with a remanent polarization of 55.4 μC cm⁻², where the P-E loop, as well as the current profile, is symmetric with respect to E. This P_r value along [001]_pc provides a P_s (// [111]_pc) of 96.0 μC cm⁻², which is close to the P_s observed for bulk crystals⁵³ and calculated by first-principles calculations⁵⁴. Figure 6c,d displays the current density-electric field (J-E) properties in the low field region (−50 kV cm⁻¹ to 50 kV cm⁻¹). The BFO capacitor exhibits a rectification behavior, where the J becomes larger when the E direction is parallel to the macroscopic polarization. In particular, the negative P state (−P) at negative fields (−E) features a markedly large J, which is consistent with the P-E properties. Even though the Mn-BFO capacitor has a higher J by over an order of magnitude, it presents a symmetric J-E property. The rectified current behavior and the associated round P-E loop observed for the BFO capacitor can be explained by an V_O^••-rich layer at the BFO/electrode interface (Fig. 4a)^{22,43,44,45,46}, which is probably formed during either the film deposition or the cooling process⁵⁵.

Figure 6

Polarization and leakage-current properties. (a,b) Polarization-electric field (P-E) hysteresis loops (3 kHz) and (c,d) leakage-current density as a function of E (J-E) properties along the [001]_pc direction; (a,c) BiFeO₃ and (b,d) Bi(Fe_0.95Mn_0.05)O₃ capacitors with a Ba_0.3Sr_0.7TiO₃ (300 nm)-buffered Ba_0.1Sr_0.9RuO₃ electrodes. Data were measured at 25 °C.

Electronic structures of Mn-doped BiFeO₃

Figure 7 presents the results of the DFT calculations for the defective cells of TM = Mn. The relative value of E_total as a function of n is plotted in Fig. 7a. We note that the cells of n greater than three exhibit a relatively large E_total by 0.1–0.2 eV compared with n = 1 and 2, indicating that the cell has a lower energy provided that V_O^•• is located adjacent to Mn. Notably, the energy gain when V_O^•• is present on the O1 (n = 1) site is 250 meV, which is three times as large as that of the thermal energy k_BT even at the deposition temperature (T_sub = 610 °C, k_BT_sub ~75 meV). Because the Curie temperature (830 °C for BiFeO₃) is higher than T_sub, a crystallization during the film deposition occurs in the ferroelectric state. We assume that the majority of V_O^•• are trapped by Mn even in the deposition process at high temperatures through a trapping-detrapping dynamics^56,57. Also, after the film is exposed to a subsequent annealing or a polarization switching, Mn provides the preferred site for V_O^•• in its immediate vicinity, and then almost all V_O^•• associates with Mn in an equilibrium state.

Figure 7

Interaction between Mn and Oxygen vacancy. (a) Total energy as a function of n obtained by DFT calculations, where n denotes the n-th nearest neighbor (NN) site of oxygen vacancy (V_On^••) with respect to Mn³⁺. O1 and O2 are the 1^st-NN and 2^nd-NN oxygen atoms (see in Fig. 1b). The total energy of n = 1 is set at zero. Total density of states (DOS) and partial DOS of the cells of (b) V_O3^•• and (c) V_O1^•• and their respective band structures are shown in (d,e). In DOS panels, the majority spin component (↑) is indicated in the right while the minority spin component (↓) in the left. The Fermi energy (E_F) is set at zero, and upper and lower dashed lines are the conduction band minimum and the valence band maximum, respectively. In band structures, the majority spin component is colored in red and the minority spin component in blue. Partial charge densities of the gap states formed primarily by the orbital interaction between Mn-3d and O-2p for the (f) V_O3^•• and (g) V_O1^•• cells, where the majority spin components are colored in blue while those in the minority spin component in yellow. The lower panel of (g) is the Mn-3d derived state in the valence band indicated by an arrow in (c).

Here, we address the mechanism of the attractive interaction between Mn and V_O^•• (Fig. 4b). Given that Mn is octahedrally coordinated with six oxygen atoms and is placed in O_h symmetry, Mn³⁺ (d⁴) has a configuration of t_2g³e_g¹, and an electron occupies the half of the e_g state. In the ferroelectric state with V_O^••, the degeneracy of e_g is lifted, rendering either of the component d_x2−y2 or d_z2 filled with electron. Therefore, the total energy of the system is governed by an energy lowering of the highest-occupied d level as a result of the interaction with neighbors.

Figure 7b,c displays the density of states (DOS) of the V_O3^•• and V_O1^•• cells, and their respective band structures are presented in d and e. The fundamentals of the electronic structures are described in the literature^44,49,54. For the V_O1^•• cell having the smallest E_total, an empty state derived mainly from the Mn-3d state (d_x2−y2) is left in the band gap, i.e., an unoccupied gap state is formed in the minority spin component above the E_F. The relatively large DOS of Mn-3d around −5 eV indicates that the rest four occupied d states (d_xy, d_xz, d_yz, and d_z2) exist inside the valence band, which are hybridized with the neighboring O-2p (e.g., the d_z2-derived partial charge density depicted in the lower panel of Fig. 7g). By contrast, the V_O3^•• cell has two gap states: one is an empty d_x2−y2 state and the other is an occupied d_z2 state. This result proves that the d_z2-derived occupied state is much lower in the V_O1^•• cell than in the V_O3^•• one.

Oxygen-vacancy trapping

When V_O^•• associates with Mn in the immediate vicinity, a MnO₅ pyramid is formed, and Mn-3d interacts strongly with O-2p of the adjacent five oxygen atoms. Because a repulsive Coulomb interaction between electrons is markedly reduced along the Mn-V_O^•• direction, the MnO₅ pyramid can accommodate the d_z2 orbital affordably (see the partial charge density in Fig. 7g), and thereby its level is lower in energy far below E_F. Provided that V_O^•• is away from Mn, which involves a change from the MnO₅ pyramid to the MnO₆ octahedron, the d orbitals are affected by the adjacent six oxygens and then the d_z2 orbital is shifted to higher energy, forming the occupied gap state above the VBM. As a result, the system is stabilized when V_O^•• resides adjacent to Mn. These results lead to the conclusion that Mn acts as an effective trap for V_O^••.

We address the V_O^•• distribution in the capacitors. As reported in the literature⁵⁸ and shown in Fig. 6, the as-prepared BFO capacitor show the distinct characteristics such as the asymmetric P-E hysteresis loop and the rectified current behavior. All these properties can be explained by an V_O^••-rich layer formed at the BFO/electrode interface (Fig. 3a). During the deposition process at high temperatures, BFO tends to have a Bi-poor composition because of a high vapor pressure of Bi^46,59,60; Bi vacancy (V_Bi″′) is formed and acts as an acceptor^13,44, which is accompanied by V_O^•• for charge compensation^61,62. Atomic-scale chemical and structural analyses show that Fe⁴⁺ (Fe_Fe^•) is abundant in the domain wall region in BiFeO₃¹³. DFT calculations reveal that the iron atom adjacent to V_O^•• tends to a valence state of Fe⁴⁺ stabilized by a FeO₅ pyramid¹³, which can explain a high concentration of Fe⁴⁺ owing to an accumulation of V_O^•• at the domain walls. We therefore think the charge neutrality of [V_Bi″′] ~ [V_O^••] ~ [Fe_Fe^•] and express the overall defect formation by

$${{{\rm{Bi}}}_{{\rm{Bi}}}}^{\times }+{{{\rm{Fe}}}_{{\rm{Fe}}}}^{\times }+{{{\rm{O}}}_{{\rm{o}}}}^{\times }\to {V\prime\prime\prime }_{{\rm{Bi}}}+{{{\rm{Fe}}}_{{\rm{Fe}}}}^{\cdot }+{{V}_{{\rm{o}}}}^{\cdot \cdot }+{\rm{Bi}}({\rm{g}})+1/2({\rm{g}}),$$

(1)

where Bi_Bi^×, Fe_Fe^×, and O_O^× are Bi³⁺ on the Bi site, Fe³⁺ on the Fe site, and O²⁻ on the O site, respectively. Provided that V_O^•• hops to the other O site, the 1^st NN Fe atom adjacent to the newly created V_O^•• is oxidized from Fe³⁺ to Fe⁴⁺ as a result of an electron transfer. Therefore, Fe_Fe^• always associates with V_O^•• regardless of its position and is present as the defect complex of V_O^••-Fe_Fe^•, which leads us to propose that the charge neutrality is expressed by [V_Bi″′] ~ [V_O^••-Fe_Fe^•]⁴⁴. Because the mobility of V_O^•• is several orders of magnitude higher than that of cation defects such as V_Bi″′²⁵, we can consider that V_Bi″′ is frozen, except at high temperatures during the film deposition, and thus has a random distribution at low temperatures. By contrast, V_O^•• is mobile even at room temperatures¹⁹ and then accumulates if its preferred site exists. Although the negatively charged V_Bi″′ is supposed to attract V_O^•• owing to an electrostatic interaction, DFT calculations⁴⁴ show that V_Bi″′ does not act as a trap of V_O^•• and predict that V_O^•• is randomly distributed in bulk form. It has been reported that V_O^•• is apt to accumulate at high-energy boundaries such as ferroelastic domain (twin) walls and ferroelectric/electrode interfaces^{10,11,12,13,14,15,30,31,32,33}.

As described above, we think that the ferroelectric films are crystallized in the polar state in their deposition process; the films have ferroelectric polarization once the BFO lattice is constructed. In capacitor form, the discontinuity of the P_s vector is inevitable at interfaces with electrodes and results in a depolarization field^{22,43,44,45,46}. As the P_s of BFO is markedly large, the depolarization field becomes strong. We note that the tail of P_s vector has negative bound charges that attract positively charged V_O^••. DFT calculations⁵¹ predict that the V_O^•• near the electrodes moves to the interface and forms an V_O^••-rich layer to reduce an electrostatic energy. The concentration of V_Bi″′ ([V_Bi″′]) is likely to be less than 3%⁶³, and leads to a comparable [V_O^••] at most because of [V_Bi″′] ~ [V_O^••-Fe_Fe^•]. In the Mn-BFO capacitor, V_O^•• can associate exclusively with Mn because of its higher content (5% Mn), as depicted in Fig. 3b. We conclude that Mn acts as an effective trap of V_O^•• and thereby inhibits the formation of an V_O^••-rich layer at the interface.

Discussion

We show that isovalent dopants with partly or fully electron-filled e_g state, such as Mn³⁺ (Mn_Fe^×), act as an effective trap for oxygen vacancies, which enables us to provide a design principle to tailor the defect structures in a wide range of [V_O^••]. The isovalent dopants do not influence [V_O^••], and the intrinsic defect of V_Bi″′ dictates [V_O^••], where [V_Bi″′] is not easily controllable. Introducing higher valent cations such as Ti⁴⁺ (Ti_Fe^•) reduce [V_O^••]⁶⁴; the doping of a small amount of Mn_Fe^× together with [Ti_Fe^•] ( > 3[V_Bi″′]) can lower [V_O^••] by several orders of magnitude, and all the vacancies are present only in the adjacent vicinity of Mn³⁺. This defect structure leads to a high mobility of domain walls, which is suitable not only for reliable high-speed non-volatile memories but also for piezoelectric applications utilizing high strain constants. For the applications based on conducting domain walls stabilized by V_O^••, a finely tuned [V_O^••] should considerably improve the device performance, which is accomplished by the balanced co-doping of Mn_Fe^× and Ti_Fe^•; free, mobile V_O^•• with an adjusted concentration accumulates the domain walls and leads to a desirable interaction strength, delivering domain-wall memories exhibiting a high-speed switching.

We expect that the application of the design principle of defect structures to other (multi)ferroic materials can provide a practical route to controlling and manipulating oxygen-vacancy distributions by harnessing the vacancy-trapping capability of isovalent transition-metal cations in ferroelectric perovskite oxides.

Methods

Experiments

Thin films of ferroelectric BiFeO₃ (BFO) and Mn(5%)-substituted BiFeO₃ [Mn-BFO, Bi(Fe_0.95Mn_0.05)O₃] were fabricated on (100) SrTiO₃ single-crystal substrates. To reduce a lattice mismatch between the substrate and the ferroelectric films as much as possible, we adopted Ba_0.3Sr_0.7TiO₃ as a buffer layer and Ba_0.1Sr_0.9RuO₃ as an electrode. We prepared the capacitors of Ba_0.1Sr_0.9RuO₃ (30 nm)/BiFeO₃ or Bi(Fe_0.95Mn_0.05)O₃ (125 nm)/Ba_0.1Sr_0.9RuO₃ (30 nm)/ Ba_0.3Sr_0.7TiO₃ (300 nm)/SrTiO₃, where their thickness is indicated in parenthesis. All the films were deposited hetero-epitaxially by pulsed-laser deposition (PLD). The Ba_0.3Sr_0.7TiO₃ buffer layer was grown at a substrate temperature (T_sub) of 740 °C under 0.26 Pa O₂ atmosphere with a laser repetition rate of 1 Hz. The Ba_0.1Sr_0.9RuO₃ electrodes were prepared at a T_sub of 610 °C under 13 Pa O₂ atmosphere with a laser repetition rate of 1 Hz. For the ferroelectric layers, T_sub, oxygen pressure and a laser repetition rate were set at 640 °C, 2.6 Pa, and 7 Hz, respectively. Then, the Ba_0.1Sr_0.9RuO₃ top electrode was prepared in the same manner as the bottom one. After the deposition process, the capacitors were annealed in air at 450 °C for one hour.

We characterized the capacitors in the as-prepared state and did not employ any treatment such as an electrical training^43,44 to control the distribution of oxygen vacancy (V_O^••). Crystal structure analysis was performed by X-ray diffraction (XRD) reciprocal space mapping (RSM), where the sources of Cu-Kα + Kβ and Cu-Kα₁ were used for wide-area and small-area (high-resolution) RSMs, respectively. The polarization-electric field (P-E) properties were measured at 25 °C, where the upward (downward) electric field and polarization are expressed as + E (−E) and +P (−P). For example, the vector of +E or +P is directed from the bottom to the top electrodes. We adopted the pseudo-cubic notation (denoted by ‘pc’) throughout this paper.

DFT Calculations

First-principles calculations based on DFT⁶⁵ were performed within the generalized gradient approximation (GGA)⁶⁶ in the projector-augmented-wave (PAW) method⁶⁷, as implemented in the Vienna ab initio simulation package (VASP)⁶⁸. We employed the gradient corrected exchange-correlation functional of the Perdew-Burke-Ernzerhof revised for solids (PBEsol)⁶⁹. Within the simplified GGA + U approach⁷⁰, we added on-site Coulomb interaction parameters of U−J = 4 eV to all the d orbitals of transition metal (TM) atoms. Because the magnetic structure of BFO can be approximated to a G-type antiferromagnetism, we considered an antiferromagnetic spin configuration formed by the d electrons. Before geometry optimizations of BFO, we put a magnetic moment of +5 μ_B (μ_B denotes the Bohr magneton) or −5 μ_B to the Fe atoms, which is accompanied by a symmetry lowering: the space group changes from R3c to R3.

For TM-substituted cells (TM = Ti, V, Cr, Mn, Co, Ni, Cu), we transformed the optimized BiFeO₃ cell with R3 symmetry (Z = 6) to the primitive rhombohedral lattice (Bi₂Fe₂O₆, Z = 1) and then created the supercell of 2 × 2 × 2, leading to the Bi₁₆Fe₁₆O₄₈ structure. We replaced one Fe atom with a negative magnetic moment by TM [Bi₁₆(Fe₁₅TM)O₄₈] and lifted the symmetry to the hexagonal R3 [TM-BiFeO₃ cell (Z = 3), see Fig. 1a]. This supercell was geometrically optimized with a Monkhorst-Pack Γ-centred k-point mesh of 3 × 3 × 3. All results were obtained by treating the following valence electrons: 5d, 6s, and 6p for Bi, 3p, 3d, and 4s for Ti, V, Cr, and Mn, 3d and 4s for Fe, Co, Ni, and Cu, and 2s and 2p for O. The plane-wave cut-off energy was set at 520 eV in all calculations.

In the TM-BiFeO₃ cells, TM is positioned on the three-fold axis in R3 symmetry, and seventeen kinds of oxygen atom having different bond lengths with TM exist. After we created the primitive lattice of the TM-BiFeO₃ cell [Bi₁₆(Fe₁₅TM)O₄₈ (Z = 1), Fig. 1b], we constructed 17 defective TM-BiFeO₃ cells with one V_O^••, Bi₁₆(Fe₁₅TM)O₄₇, in P1 symmetry and then relaxed the fractional coordinates of all the atoms in the fixed cell size, where the Γ-centred 3 × 3 × 3 k-point mesh was also used. For these calculations, the valence state of TM remained to be +3 by controlling the total number of electrons. It has been reported that oxygen vacancies in zinc ferrites change the iron-iron coupling from the antiferromagnetic to the ferromagnetic spin configuration³⁸. We confirmed that the antiferromagnetic configuration of Fe atoms is established in the defective cells after the structural optimizations under no constraint regarding the total magnetic moment, even though the initial spin state around V_O^•• is set to the ferromagnetic order.