Abstract
Multiferroic materials composed of ferromagnetic and ferroelectric components are interesting for technological applications due to sizable magnetoelectric coupling allowing the control of magnetic properties by electric fields. Due to being compatible with the silicon-based technology, HfO2-based ferroelectrics could serve as a promising component in the composite multiferroics. Recently, a strong charge-mediated magnetoelectric coupling has been predicted for a Ni/HfO2 multiferroic heterostructure. Here, using density functional theory calculations, we systematically study the effects of the interfacial oxygen stoichiometry relevant to experiments on the magnetoelectric effect at the Ni/HfO2 interface. We demonstrate that the magnetoelectric effect is very sensitive to the interface stoichiometry and is reversed if an oxidized Ni monolayer is formed at the interface. The reversal of the magnetoelectric effect is driven by a strong Ni−O bonding producing exchange-split polarization-sensitive antibonding states at the Fermi energy. We argue that the predicted reversal of the magnetoelectric effect is typical for other 3d ferromagnetic metals, such as Co and Fe, where the metal-oxide antibonding states have an opposite spin polarization compared to that in the pristine ferromagnetic metals. Our results provide an important insight into the mechanism of the interfacial magnetoelectric coupling, which is essential for the physics and application of multiferroic heterostructures.
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Introduction
Multiferroic materials have drawn much attention due to the magnetoelectric coupling providing new paradigms for electronic devices1,2. The control of magnetic properties by an applied electric field rather than a magnetic field or a spin-polarized current requires much less energy3,4,5, making multiferroics promising for non-volatile memory and logic applications6,7. Layered multiferroic structures comprising ferroelectric and ferromagnetic components are most favorable in this regard owing to the significant interfacial magnetoelectric coupling strength, which can be a few orders of magnitude larger than that in the single-phase multiferroics8,9,10,11, as a result of the strain-mediated12,13,14,15,16 and charge-mediated17,18,19,20,21,22,23 coupling mechanisms. In addition, the magnetoelectric effect in the ferromagnet/ferroelectric heterostructures can be employed in multiferroic tunnel junctions—non-volatile multilevel electronic devices24,25,26,27,28,29.
Over the last years, a wide range of multiferroic materials and structures have been assessed for technological applications2. Within these efforts, the challenge was the compatibility of these materials with silicon-based technologies30. Most of the traditional perovskite ferroelectrics are incompatible with the complementary metal-oxide-semiconductor (CMOS) technology. In addition, ferroelectric properties of perovskites oxides often deteriorate with reduced film thickness that makes a composite structure impractical at the nanoscale.
Recently, ferroelectricity has been discovered in doped hafnia (HfO2) films31,32, which may help to address the abovementioned challenges. The origin of ferroelectric behavior was attributed to a non-centrosymmetric orthorhombic phase of HfO2 with the space group symmetry Pca2133,34 Due to robust ferroelectricity at the nanometer scale and good compatibility with the CMOS technology, HfO2-based ferroelectrics have attracted significant attention35,36,37. Considerable efforts have been invested in studying relevant properties to explore their applicability to non-volatile memory devices, such as ferroelectric random-access memories (FeRAM)38, ferroelectric field-effect transistors (FeFET)39,40, ferroelectric tunnel junctions (FTJs)41,42,43,44,45,46, and negative-capacitance field-effect transistors (NCFET)47,48.
The HfO2-based ferroelectric thin films are also promising as a ferroelectric component in multiferroic heterostructures for the high-density memory applications49,50,51,52. Based on density functional theory (DFT) calculations, a strong polarization-controlled magnetoelectric coupling has been predicted at the interface between ferromagnetic metal Ni and ferroelectric HfO249. Stimulated by this prediction, experimental studies of the magnetoelectric coupling at the Ni/Hf0.5Zr0.5O2 (HZO) interface have been conducted and revealed a sizable effect52. The ferroelectric polarization control of magnetocrystalline anisotropy and a coercive field have been demonstrated in ultrathin Al-doped-HfO2/Co/Pt heterostructures50. A sizable tunneling magnetoresistance (TMR) has been observed in La0.7Sr0.3MnO3 (LSMO)/Hf0.5Zr0.5O2 (HZO)/Co magnetic tunnel junctions (MTJs)51. Interestingly, the TMR effect in these studies was reversed (i.e., the TMR changed from positive to negative) after a few tens of electric field cycling under the same DC bias. In addition, in a separate study, it was found that a CoOx layer formed at the Co/Hf0.5Zr0.5O2 interface after ~100 times of electric field cycling, leading to a high-resistance state in LSMO/HZO/Co multiferroic tunnel junctions53.
The latter results indicate that the effects of ferromagnetic metal oxidation play an important role in functional multiferroic devices. It is well known that oxygen ions in oxide materials can easily diffuse into the adjacent metal film under applied voltage causing oxidation of metal surface at the metal/oxide interfaces. The formation of an oxide layer produces a significant effect on magnetic properties, such as the interface magnetization, the magnetocrystalline anisotropy, the spin-orbit torque, and the TMR effect54,55,56,57,58,59. For example, it has been shown that the oxidation of the Co metal surface results in the formation of the Co−O bonding or antibonding states, which modifies the electronic and magnetic structure and leads to the reversal of the TMR effect60,61.
Since oxidation of a ferromagnetic metal is expected to occur in realistic devices based on ferromagnet/ferroelectric HfO2 interfaces52, in this work, we systematically explore the effects of interfacial oxygen stoichiometry on magnetoelectric properties. We consider a Ni/HfO2 heterostructure as a prototype model and, using first-principles DFT calculations, study the influence of metal oxidation and oxygen deficiency in HfO2 on the magnetoelectric coupling. Consistent with our previous work49, we find that the pristine Ni/HfO2 interface exhibits a “conventional” magnetoelectric effect driven by the depletion (accumulation) of the screening electronic charges, where the interfacial magnetization is enhanced (reduced) for ferroelectric polarization of HfO2 pointing away from (into) the ferromagnetic Ni layer (Fig. 1a, b). When the oxygen deficiency at the interface increases, the reduced charge transfer between Ni and O atoms reduces the magnetoelectric coupling due to a smaller contribution to it from the Ni−O hybridization at the interface. Surprisingly, we find that the polarization-induced interfacial magnetoelectric effect is reversed when the interfacial Ni layer is oxidized by diffused oxygen ions from HfO2 (Fig. 1c, d). We demonstrate that the reversed interface magnetoelectric effect is driven by the formation of the exchange-split Ni−O antibonding states, which are sensitive to ferroelectric polarization.
The ferroelectric-induced interfacial magnetoelectric effect at the pristine defect-free (a, b) and oxidized-metal (c, d) Ni/HfO2 interface. The vertical arrows represent ferroelectric polarization of the HfO2 layer. Red and green colors at the Ni/HfO2 interfaces denote an increase or decrease of the interface magnetization induced by the ferroelectric polarization, respectively. Red solid and open spheres at the Ni/HfO2 interfaces in c and d indicate the diffused oxygen atoms and the remaining oxygen vacancies (Vo), respectively, which are amplified in the insert.
Results
Interface structures and magnetic properties
To explore magnetoelectric properties of the Ni/HfO2 interfaces, we follow our previous work49 and consider Ni/HfO2/Ni heterostructures by stacking 5.75 unit cell layers of HfO2 and 9 monolayers of Ni along the (001) direction. Here, one unit cell layer of HfO2 consists of 2 Hf monolayers and 2 O monolayers. We assume symmetric Ni/O interface terminations, which allows us to examine magnetic properties of the Ni/HfO2 (001) interface for polarization pointing into the Ni layer or away from the Ni layer, using the same structural model with unidirectional polarization of HfO2 (Fig. 2a). The in-plane lattice constant of the Ni/HfO2/Ni heterostructure is fixed to the experimental value of yttrium-stabilized zirconia (a = 5.185 Å) which is a common substrate to grow HfO2-based ferroelectric thin films62,63.
The interfaces with polarization pointing away from (into) the Ni layer are displayed on bottom (top) panels and derived from respective Ni/HfO2/Ni heterostructures with polarization pointing up (indicated by black arrow). a The defect-free Ni/HfO2 interfaces (SDF). The oxygen atoms at the two interfaces are labeled by O1−O8. O1, O3, O5, and O7 belong to the O atoms which are three-fold coordinated in HfO2 bulk and responsible for the ferroelectric displacements. O2, O4, O6, and O8 belong to the O atoms which are four-fold coordinated in HfO2 bulk. b−e The most stable structures with one oxygen vacancy at each interface (SV-1), with two oxygen vacancies at each interface (SV-2), with one interfacial oxygen atom diffused into Ni (SD-1) and with two interfacial oxygen atoms diffused into Ni (SD-2), respectively. Red dashed circles indicate the sites of oxygen vacancies.
The atomic structure of the defect-free (SDF) Ni/HfO2/Ni heterostructure is optimized with the two interfaces shown in Fig. 2a. The ferroelectric polarization of HfO2 is pointing into (Pin) and away from (Pout) the Ni layer for the top and bottom interfaces, respectively. The average magnetic moments of the interfacial Ni atoms for the Pin and Pout interfaces are calculated to be 0.97 μB (min) and 1.24 µB (mout), respectively (Table 1). Therefore, the magnetization difference Δm at the Ni/HfO2 interface caused by ferroelectric polarization switching is 0.27 µB (0.04 µB/Å2).
First, we study the effect of oxygen deficiency on the magnetoelectric coupling at the Ni/HfO2 interface. Figure 2b shows the Ni/HfO2 atomic structure with one oxygen vacancy at each interface (labeled SV-1). Another structure with one oxygen vacancy (labeled SV-1′) at the interface is shown in Supplementary Fig. 1b. We find that the SV-1′ interface is 0.42 eV higher in the total energy than the SV-1 interface. The average magnetic moments for the SV-1 and SV-1′ structures are 0.71 µB and 0.93 µB for the Pin and Pout interfaces, respectively, resulting in a Δm of 0.22 µB (Table 1). Figure 2c shows the Ni/HfO2 atomic structure with two oxygen vacancies at each interface (labeled SV-2), and another structure with two oxygen vacancies (labeled SV-2′) is shown in Supplementary Fig. 1c. The SV-2′ interface has the total energy of 0.31 eV higher than the SV-2 interface. As seen from Table 1, the magnetization change driven by polarization reversal is slightly reduced for the SV-2 (Δm = 0.12 µB) and SV-2′ (Δm = 0.18 µB) structures as compared to that for the SDF, SV-1, and SV-1′ structures.
Next, we explore the effect of Ni surface oxidation on the magnetoelectric coupling by constructing the structures, where the O atoms are moved inside the interfacial Ni layers forming a NiO layer. SD-1 (Fig. 2d) and SD-1′ (Supplementary Fig. 1d) structures are formed by moving one O atom inside the interfacial Ni layers. For the SD-1 interface, we find min = 0.58 µB and mout = 0.90 µB, resulting in Δm = 0.32 µB. For the SD-1′ interface, which is 0.2 eV higher in energy than the SD-1 interface, min and mout are 0.59 and 0.70 µB, respectively, resulting in Δm of 0.11 µB (Table 1). SD-2 (Fig. 2e) and SD-2’ (Supplementary Fig. 1e) structures are obtained by moving two O atoms inside the interfacial Ni layers. We find that the SD-2 interface is 0.17 eV lower in energy than the SD-2’ interface. From Table 1, it is seen that the interfacial magnetic moments for the SD-2 and SD-2′ structures are significantly reduced with mout for the SD-2 interface being diminished nearly to zero. The calculated Δm for the SD-2 or SD-2′ structures is negative, indicating the reversal of the magnetoelectric effect with oxidation of Ni.
Interface electronic properties
The difference in the magnetoelectric effect depending on the interfacial oxygen stoichiometry can be understood from the analysis of the electronic structure. Figure 3 shows the spin-resolved density of states (DOS) projected onto the interfacial Ni atoms and diffused O for the Ni/HfO2/Ni heterostructures shown in Fig. 2. For the pristine defect-free structure (Fig. 3a), ferroelectric polarization of HfO2 shifts the DOS of the interfacial Ni atoms at the Pout (Pin) interface to high (low) energies (compare red and blue lines in Fig. 3a). Since around the Fermi energy the minority-spin DOS of Ni is much larger than the majority-spin DOS (compare top and bottom panels in Fig. 3a), this shift of the Ni DOS results in the depletion (accumulation) of the minority-spin electrons and hence an enhanced (reduced) magnetic moment of the Ni atoms at the Pout (Pin) interface.
a−e Spin-resolved density of states (DOS) of the interfacial Ni atoms at the Ni/HfO2 interfaces for polarization pointing into the Ni layer (Pin) or away from it (Pout) for a SDF, b SV-1, c SV-2, d SD-1, and e SD-2 structures. f DOS of diffused O atoms at the SD-2 interfaces for Pin and Pout. DOS of Ni and O atoms under the considered energy range are mainly contributed by the Ni 3d and O 2p orbitals, respectively. Each curve represents an averaged DOS per atom. The majority- and minority-spin DOS are plotted on top (positive) and bottom (negative) panels, respectively. The red and blue lines denote DOS at the Pout and Pin interfaces, respectively. The gray-filled curves correspond to the bulk-like DOS of Ni atoms at the central Ni layer a−e or O atoms at the central HfO2 layer (f). The vertical dashed line indicates the position of Fermi energy (EF).
In addition to the electrostatic doping, there is another contribution to the magnetoelectric effect resulting from the electronic hybridization between the interfacial Ni and O atoms dependent on polarization orientation. As was explained in our previous work49, the weaker (stronger) hybridization between the O 2p and Ni 3d orbitals at the Pin (Pout) interface, due to the longer (shorter) Ni−O bonds induced by polar displacements of oxygen atoms at the interface, reduces (enhances) the electron charge transfer from Ni to O atoms resulting in the reduced (enhanced) magnetic moments of the interfacial Ni atoms (Supplementary Fig. 2). This effect is largely responsible for the change in the magnetoelectric coupling at the interfaces with one (SV-1 and SV-1′) or two oxygen vacancies (SV-2 and SV-2′) compared to the defect-free (SDF) interface. As seen from Table 1 and Supplementary Table 1, removing one or two O atoms from the interface, gradually decreases the magnetic moments of the Ni atoms at both Pin and Pout interfaces. This decrease is due to the reduced electron charge transfer from the interfacial Ni to O atoms (not related to ferroelectricity) reflected in the diminished overall rightward energy shift of the interfacial Ni DOS relative to the bulk Ni DOS (compare Fig. 3a and b, c which elevates the minority-spin population. The reduced charge transfer between Ni and O atoms with the decreased number of interfacial O atoms reduces the magnitude of the magnetoelectric coupling due to a smaller contribution to it from the Ni−O hybridization at the interface.
Diffusion of O atoms into the Ni layer affects differently the magnetoelectric coupling depending on the degree of the Ni layer oxidation. For the SD-1 and SD-1′ structures, where only one O atom per unit cell is diffused underneath the top Ni monolayer (Fig. 2d and Supplementary Fig. 1d), the interfacial Ni DOS (Fig. 3d and Supplementary Fig. 3d) are like those for the structures with one oxygen vacancy at the interface (Fig. 3b and Supplementary Fig. 3b), resulting in qualitatively similar magnetoelectric effects. However, the interfacial Ni DOS changes dramatically for the SD-2 and SD-2′ structures where two O atoms are diffused into the Ni layer resulting in the formation of the NiO interfacial monolayer. As seen from Fig. 3e and Supplementary Fig. 3e, the minority-spin DOS around the Fermi energy is significantly reduced for the interfacial Ni monolayer as compared to the bulk Ni (gray background in Fig. 3e and Supplementary Fig. 3e) and the pristine interface (Fig. 3a). This effect stems from the broken bonds between the interfacial and bulk Ni atoms and the formation of the Ni−O antibonding states near the Fermi energy. The antibonding states are clearly seen from the DOS projected onto the diffused O atoms shown in Fig. 3f. While the bonding states are located at energies around and below E = −5 eV, the exchange-split antibonding states appear in the energy window −1 eV < E< +1 eV around the Fermi energy. The reduced minority-spin DOS is responsible for the sizable reduction of the magnetic moment of the Ni atoms at the interface compared to the pristine SDF structure (Table 1).
The effect of Ni oxidation resulting in the formation of the Ni−O antibonding states leads to the reversal of the magnetoelectric effect. This is due to the exchange-split Ni−O antibonding states which cross the Fermi energy with reversal of the ferroelectric polarization of HfO2. The effect is clearly seen from Fig. 3f displaying the portion of the antibonding states near the Fermi energy projected onto the diffused O atoms. While the minority-spin DOS corresponding to the Ni−O antibonding states is largely located above the Fermi energy independent of ferroelectric polarization orientation, the antibonding peak in the majority-spin DOS crosses the Fermi energy when the polarization is reversed. The same effect can be seen from the DOS projected onto the interfacial Ni atoms (Fig. 3e), though less pronounced due to the overlap in DOS between the antibonding and non-bonding Ni states. As a result, when the ferroelectric polarization of HfO2 is pointing into the Ni layer (Pin), the accumulation of the majority-spin electrons (blue line) in the Ni−O antibonding states enhances the magnetic moments of the interfacial Ni and O atoms. Whereas, when the polarization of HfO2 layer is pointing away from the Ni layer (Pout), the depletion of the majority-spin antibonding states (red line) reduces the magnetic moments of the interfacial Ni and O atoms. Therefore, the magnetoelectric effect of the oxidized Ni/HfO2 interface is reversed compared to the pristine defect-free Ni/HfO2 interface.
The effects of the interface stoichiometry on the interface magnetoelectric effect are visualized using spin-density plots shown in Fig. 4 (see also Supplementary Fig. 4). For the SDF structure (Fig. 4a), the depletion (accumulation) of the minority-spin electrons due to the polarization screening charge and the stronger (weaker) hybridization between the interfacial O and Ni atoms induced by O polar displacements at the Pout (Pin) interface leads to a larger spin density on the interfacial Ni and O atoms at the Pout interface than at the Pin interface. For the SV-2 structure (Fig. 4b), the electron charge transfer from the interfacial Ni to O atoms is reduced due to the reduced number of O atoms at the interface, raising the minority-spin population and thus lowering the spin density as compared to the SDF structure. At the same time, the decreased number of the interfacial O atoms reduces the contribution to the magnetoelectric coupling from the Ni−O hybridization at the interface, although the spin density and thus the magnetization at the Pout interface still remain larger than those at the Pin interface. For the SD-2 structure (Fig. 4c), the spin density at both interfaces decreases significantly due to the formation of the NiO layer at the interface. It is seen that the spin density and thus the magnetization are larger at the Pin interface than at the Pout interface, implying that the magnetoelectric effect is reversed at the SD-2 interface compared to the SDF and SV-2 interfaces. The spin densities of the interfaces with other interface stoichiometries demonstrate similar trends (see Supplementary Fig. 4).
The spin densities of the Ni/HfO2 interfaces defined as the difference between the majority- and minority-spin charge densities, at the Pin (top panels) and Pout (bottom panels) interfaces for a SDF, b SV-2, and c SD-2 interfaces. The spin densities are shown within the yz-plane and averaged along the x-direction.
Discussion
We would like to note that the predicted effects of the interface stoichiometry on the magnetoelectric effect at the interfaces between a ferromagnetic metal and an oxide ferroelectric are expected to be not only limited to the considered Ni/HfO2 interface but may have more general occurrence. In particular, the conventional magnetoelectric effect, where depletion (accumulation) of the screening electronic charges induced by ferroelectric polarization pointing away from (into) the ferromagnetic metal layer leads to enhancement (reduction) of the interfacial magnetization, is expected to be typical for all elemental 3d metals, such as Fe, Co, and Ni, where the majority 3d bands are fully populated resulting in higher minority-spin DOS at the Fermi energy (Fig. 5a). On the other hand, oxidation of these metals at the interface in a metal/ferroelectric heterostructure due to the diffusion of oxygen atoms from the oxide ferroelectric into the ferromagnetic metal forms metal-oxygen bonding and antibonding states with the latter being positioned at the Fermi energy. This may lead to the reversal of the magnetoelectric effect at the interfaces between 3d ferromagnetic metals and ferroelectric oxides due to majority-spin antibonding states controlling the polarization charge screening (Fig. 5b). For example, it has been shown that at the Co surface, the exchange-split Co−O antibonding states reverse the spin polarization compared to that in bulk Co60,61. The effects discussed here may be responsible for the reversal of TMR in LSMO/HZO/Co MTJs after electric field cycling51.
a Conventional magnetoelectric effect, where accumulation (depletion) of the screening minority-spin electronic charges induced by ferroelectric polarization pointing into, Pin, (away from, Pout) the ferromagnetic metal (M) layer leads to reduction (enhancement) of the interfacial magnetic moment (m); b Reversed magnetoelectric effect due to the interface metal oxidation forming M-3d/O-2p bonding and antibonding states, with the latter being positioned at the Fermi energy and controlling the polarization charge screening through accumulation or depletion of the antibonding majority-spin electrons. DOS stays for the density of states and EF for the Fermi energy. Arrows denote majority (spin-up) and minority (spin-down) DOS.
From the experimental perspective, the determination of the interface stoichiometry is not a simple problem, especially for the interfaces which are not epitaxial (see, e.g., ref. 52). In this regard, a comparison with the results of DFT calculations, such as those presented here, may be challenging. A valuable approach (though not direct) is to measure a band alignment between a ferromagnetic metal and a ferroelectric oxide using, e.g., X-ray photoelectron spectroscopy64 and compare the results with the DFT calculations. Since the valence band offset is very sensitive to the interface termination it can provide valuable information about the interface structure. Valence band offsets for different interface structures are calculated in Supplementary Fig. 5 and Table 2, which may be useful for the experimentalists working in this field.
In conclusion, the magnetoelectric effects at the Ni/HfO2 interfaces where ferroelectric polarization of HfO2 controls the interfacial magnetization of ferromagnetic Ni have been studied based on the DFT calculations for different interface stoichiometries. Consistent with the previous studies, it was found that for the ideal fully oxygen terminated Ni/HfO2 interface, the interfacial magnetization is increased (decreased) when the ferroelectric polarization of HfO2 points away from (into) the Ni layer by resulting in depletion (accumulation) of the minority-spin electrons of Ni. This conventional interfacial magnetoelectric effect is maintained with reducing the oxygen concentration at the Ni/HfO2 interface, although its magnitude is diminished. However, when a NiO monolayer is formed at the Ni/HfO2 interface due to diffusion of oxygen atoms from the HfO2 surface into the Ni layer, the ferroelectric-induced magnetoelectric effect is reversed. This reversal is driven by the formation of the exchange-split Ni−O antibonding states resulting from the Ni oxidation. Due to the majority-spin Ni−O antibonding states controlling the ferroelectric polarization charge screening, the electron accumulation (depletion) enhances (reduces) the interface magnetization, leading to the reversed magnetoelectric effect as compared with that at the unoxidized Ni/HfO2 interface. The predicted effect of the ferromagnetic metal oxidation on the interfacial magnetoelectric coupling is of general significance, and therefore we expect similar behaviors occurring at other ferromagnetic metal/ferroelectric oxide interfaces. We, therefore, hope that our theoretical predictions will stimulate further experimental studies of the ferroelectrically-induced interfacial magnetoelectric effect and will improve the understanding of this phenomenon.
Methods
DFT calculations
DFT calculations are performed using the Vienna Ab Initio Simulation Package (VASP) using the projector-enhanced wave (PAW) method65. The generalized gradient approximation (GGA) within the Perdew-Burke-Ernzerhof (PBE) functional66 is used to describe the exchange and correlation effects. A 450 eV plane-wave cutoff and a 6 × 6 × 1 Monkhorst-Pack k-point mesh67 are used for structural relaxations of the Ni/HfO2/Ni heterostructures and a 10 × 10 × 1 Monkhorst-Pack k-point mesh is then used in the self-consistent electronic structure calculation.
Data availability
The data that support the findings of the work is in the manuscript’s main text and Supplementary Information. Additional data are available from the corresponding author upon reasonable request.
References
Eerenstein, W., Mathur, N. & Scott, J. F. Multiferroic and magnetoelectric materials. Nature 442, 759–765 (2006).
Spaldin, N. A. & Ramesh, R. Advances in magnetoelectric multiferroics. Nat. Mater. 18, 203–212 (2019).
Tsymbal, E. Y. Spintronics Electric toggling of magnets. Nat. Mater. 11, 12–13 (2012).
Manipatruni, S., Nikonov, D. E. & Young, I. A. Beyond CMOS computing with spin and polarization. Nat. Phys. 14, 338–343 (2018).
Meisenheimer, P. B., Novakov, S., Vu, N. M. & Heron, J. T. Perspective: magnetoelectric switching in thin film multiferroic heterostructures. J. Appl. Phys. 123, 240901 (2018).
Scott, J. F. Data storage: multiferroic memories. Nat. Mater. 6, 256–257 (2007).
Bibes, M. & Barthélémy, A. Multiferroics: towards a magnetoelectric memory. Nat. Mater. 7, 425–426 (2008).
Martin, L. W. et al. Multiferroics and magnetoelectrics: thin films and nanostructures. J. Phys.: Condens. Matter 20, 434220 (2008).
Velev, J. P., Jaswal, S. S. & Tsymbal, E. Y. Multi-ferroic and magnetoelectric materials and interfaces. Philos. Trans. R. Soc. A 369, 3069 (2011).
Vaz, C. A. F. Electric field control of magnetism in multiferroic heterostructures. J. Phys.: Condens. Matter 24, 333201 (2012).
Hu, J.-M., Duan, C.-G., Nan, C.-W. & Chen, L.-Q. Understanding and designing magnetoelectric heterostructures guided by computation: progresses, remaining questions, and perspectives. npj Comp. Mater. 3, 18 (2017).
Nan, C.-W., Bichurin, M. I., Dong, S., Viehland, D. & Srinivasan, G. Multiferroic magnetoelectric composites: historical perspective, status, and future directions. J. Appl. Phys. 103, 031101 (2008).
Nan, T. X. et al. Voltage impulse induced bistable magnetization switching in multiferroic heterostructures. Appl. Phys. Lett. 100, 132409 (2012).
Franke, K. J. A., López González, D., Hämäläinen, S. J. & van Dijken, S. Size dependence of domain pattern transfer in multiferroic heterostructures. Phys. Rev. Lett. 112, 017201 (2014).
Wang, Q. et al. Strain-mediated 180° switching in CoFeB and Terfenol-D nanodots with perpendicular magnetic anisotropy. Appl. Phys. Lett. 110, 102903 (2017).
Motti, F. et al. Strain-induced magnetization control in an oxide multiferroic heterostructure. Phys. Rev. B 97, 094423 (2018).
Duan, C. G., Jaswal, S. S. & Tsymbal, E. Y. Predicted magnetoelectric effect in Fe/BaTiO3 multilayers: ferroelectric control of magnetism. Phys. Rev. Lett. 97, 047201 (2006).
Yamauchi, K., Sanyal, B. & Picozzi, S. Interface effects at a half-metal/ferroelectric junction. Appl. Phys. Lett. 91, 062506 (2007).
Molegraaf, H. J. A. et al. Magnetoelectric effects in complex oxides with competing ground states. Adv. Mater. 21, 3470 (2009).
Radaelli, G. et al. Electric control of magnetism at the Fe/BaTiO3 interface. Nat. Commun. 5, 3404 (2014).
Zhou, Z. et al. Interfacial charge-mediated non-volatile magnetoelectric coupling in Co0.3Fe0.7/Ba0.6Sr0.4TiO3/Nb:SrTiO3 multiferroic heterostructures. Sci. Rep. 5, 7740 (2015).
Rajapitamahuni, A. et al. Ferroelectric polarization control of magnetic anisotropy in PbZr0.2Ti0.8O3/La0.8Sr0.2MnO3 heterostructures. Phys. Rev. Mater. 3, 021401 (2019).
Bocirnea, A. E. et al. Polarization-dependent magnetism of the Ni/BaTiO3 interface. Phys. Rev. Mater. 4, 034402 (2020).
Velev, J. P. et al. Magnetic tunnel junctions with ferroelectric barriers: prediction of four resistance states from first-principles. Nano Lett. 9, 427 (2009).
Zhuravlev, M. Y., Maekawa, S. & Tsymbal, E. Y. Effect of spin-dependent screening on tunneling electroresistance and tunneling magnetoresistance in multiferroic tunnel junctions. Phys. Rev. B 81, 104419 (2010).
Pantel, D., Goetze, S., Hesse, D. & Alexe, M. Reversible electrical switching of spin polarization in multiferroic tunnel junctions. Nat. Mater. 11, 289–293 (2012).
Velev, J. P., Burton, J. D., Zhuravlev, M. Y. & Tsymbal, E. Y. Predictive modelling of ferroelectric tunnel junctions. npj Comp. Mater. 2, 16009 (2016).
Huang, W. et al. Solid-state synapse based on magnetoelectrically coupled memristor. ACS Appl. Mater. Interfaces 10, 5649–5656 (2018).
Fang, M. et al. Nonvolatile multilevel states in multiferroic tunnel junctions. Phys. Rev. Appl. 12, 044049 (2019).
Vopson, M. M. Fundamentals of multiferroic materials and their possible applications. Crit. Rev. Solid State 40, 223–250 (2015).
Böscke, T. S., Müller, J., Bräuhaus, D., Schröder, U. & Böttger, U. Ferroelectricity in hafnium oxide thin films. Appl. Phys. Lett. 99, 102903 (2011).
Müller, J. et al. Ferroelectricity in simple binary ZrO2 and HfO2. Nano Lett. 12, 4318–4323 (2012).
Huan, T. D., Sharma, V., Rossetti, G. A. Jr. & Ramprasad, R. Pathways towards ferroelectricity in hafnia. Phys. Rev. B 90, 064111 (2014).
Sang, X., Grimley, E. D., Schenk, T., Schroeder, U. & LeBeau, J. M. On the structural origins of ferroelectricity in HfO2 thin films. Appl. Phys. Lett. 106, 162905 (2015).
Jiang, P. et al. Wake-up effect in HfO2-based ferroelectric films. Adv. Electron. Mater. 7, 2000728 (2020).
Khan, A. I., Keshavarzi, A. & Datta, S. The future of ferroelectric field-effect transistor technology. Nat. Electron. 3, 588–597 (2020).
Chouprik, A., Negrov, D., Tsymbal, E. Y. & Zenkevich, A. Defects in ferroelectric HfO2. Nanoscale 13, 11635 (2021).
Francois, T. et al. Demonstration of BEOL-compatible ferroelectric Hf0.5Zr0.5O2 scaled FeRAM co-integrated with 130 nm CMOS for embedded NVM applications. IEEE IEDM (2019). https://doi.org/10.1109/IEDM19573.2019.8993485.
Mueller, S. et al. From MFM capacitors toward ferroelectric transistors: endurance and disturb characteristics of HfO2-based FeFET devices. IEEE T. Electron Dev. 60, 4199–4205 (2013).
Seo, M. et al. First demonstration of a logic-process compatible junctionless ferroelectric FinFET synapse for neuromorphic applications. IEEE Electr. Device Lett. 39, 1445–1448 (2018).
Ambriz-Vargas, F. et al. A complementary metal oxide semiconductor process-compatible ferroelectric tunnel junction. ACS Appl. Mater. Interfaces 9, 13262–13268 (2017).
Chouprik, A. et al. Electron transport across ultrathin ferroelectric Hf0.5Zr0.5O2 films on Si. Microelectron. Eng. 178, 250–253 (2017).
Goh, Y. & Jeon, S. Enhanced tunneling electroresistance effects in HfZrO-based ferroelectric tunnel junctions by high-pressure nitrogen annealing. Appl. Phys. Lett. 113, 052905 (2018).
Yoong, H. Y. et al. Epitaxial ferroelectric Hf0.5Zr0.5O2 thin films and their implementations in memristors for brain‐inspired computing. Adv. Funct. Mater. 28, 1806037 (2018).
Chen, L. et al. Ultra-low power Hf0.5Zr0.5O2 based ferroelectric tunnel junction synapses for hardware neural network applications. Nanoscale 10, 15826–15833 (2018).
Mikheev, V. et al. Ferroelectric second-order memristor. ACS Appl. Mater. Interfaces 11, 32108–32114 (2019).
Cao, W. & Banerjee, K. Is negative capacitance FET a steep-slope logic switch? Nat. Commun. 11, 1196 (2020).
Hoffmann, M. et al. Unveiling the double-well energy landscape in a ferroelectric layer. Nature 565, 464–467 (2019).
Yang, Q. et al. Magnetoelectric effect at the Ni/HfO2 interface induced by ferroelectric polarization. Phys. Rev. Appl. 12, 024044 (2019).
Vermeulen, B. F. et al. Ferroelectric control of magnetism in ultrathin HfO2/Co/Pt layers. ACS Appl. Mater. Interfaces 11, 34385–34393 (2019).
Wei, Y. et al. Magneto-ionic control of spin polarization in multiferroic tunnel junctions. npj Quantum Mater. 4, 62 (2019).
Dmitriyeva, A. et al. Magnetoelectric coupling at the Ni/Hf0.5Zr0.5O2 interface. ACS Nano 15, 14891–14902 (2021).
Nukala, P. et al. Reversible oxygen migration and phase transitions in hafnia-based ferroelectric devices. Science 372, 630–635 (2021).
Rodmacq, B., Manchon, A., Ducruet, C., Auffret, S. & Dieny, B. Influence of thermal annealing on the perpendicular magnetic anisotropy of Pt/Co/AlOx trilayers. Phys. Rev. B 79, 024423 (2009).
Bi, C. et al. Reversible control of Co magnetism by voltage-induced oxidation. Phys. Rev. Lett. 113, 267202 (2014).
Bauer, U. et al. Magneto-ionic control of interfacial magnetism. Nat. Mater. 14, 174–181 (2015).
Qiu, X. et al. Spin-orbit-torque engineering via oxygen manipulation. Nat. Nanotechnol. 10, 333–338 (2015).
Hibino, Y., Hirai, T., Hasegawa, K., Koyama, T. & Chiba, D. Enhancement of the spin-orbit torque in a Pt/Co system with a naturally oxidized Co layer. Appl. Phys. Lett. 111, 132404 (2017).
Feng, J. et al. Effects of oxidation of top and bottom interfaces on the electric, magnetic, and spin-orbit torque properties of Pt/Co/AlOx trilayers. Phys. Rev. Appl. 13, 044029 (2020).
Belashchenko, K. D. et al. Effect of interface bonding on spin-dependent tunneling from the oxidized Co surface. Phys. Rev. B 69, 174408 (2004).
Belashchenko, K. D., Tsymbal, E. Y., Oleynik, I. I. & van Schilfgaarde, M. Positive spin polarization in Co/Al2O3/Co tunnel junctions driven by oxygen adsorption. Phys. Rev. B 71, 224422 (2005).
Katayama, K. et al. Orientation control and domain structure analysis of {100}-oriented epitaxial ferroelectric orthorhombic HfO2-based thin films. J. Appl. Phys. 119, 134101 (2016).
Shimizu, T. et al. Ferroelectricity mediated by ferroelastic domain switching in HfO2-based epitaxial thin films. Appl. Phys. Lett. 113, 212901 (2018).
Jenkins, M. A. et al. Determination of hafnium zirconium oxide interfacial band alignments using internal photoemission spectroscopy and x-ray photoelectron spectroscopy. ACS Appl. Mater. Interfaces 13, 14634–14643 (2021).
Kresse, G. & Joubert, D. From ultrasoft pseudopotentials to the projector augmented-wave method. Phys. Rev. B 59, 1758 (1999).
Perdew, J. P., Burke, K. & Ernzerhof, M. Generalized gradient approximation made simple. Phys. Rev. Lett. 77, 3865–3868 (1996).
Monkhorst, H. J. & Pack, J. D. Special points for Brillouin-zone integrations. Phys. Rev. B 13, 5188 (1976).
Acknowledgements
The authors thank Dr. Andrei Zenkevich for helpful discussions. This work was supported by the National Natural Science Foundation of China (Grant No. 12072307) and the Outstanding Youth Science Foundation of Hunan Province, China (Grant No. 2021JJ20041). The research at University of Nebraska-Lincoln was supported by the National Science Foundation (NSF) through Materials Research Science and Engineering Center (MRSEC) (NSF Grant No. DMR-1420645).
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Q.Y., L.L.T., and E.Y.T. designed the research. Z.J.C. and Q.Y. performed the first-principle calculations and wrote the manuscript. All authors discussed the results and reviewed the manuscript. E.Y.T. supervised the project.
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Chen, Z., Yang, Q., Tao, L. et al. Reversal of the magnetoelectric effect at a ferromagnetic metal/ferroelectric interface induced by metal oxidation. npj Comput Mater 7, 204 (2021). https://doi.org/10.1038/s41524-021-00679-2
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DOI: https://doi.org/10.1038/s41524-021-00679-2
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