Ferroelectricity in ultrathin perovskite films

Sai, Na; Kolpak, Alexie M.; Rappe, Andrew M.

doi:10.1103/physrevb.72.020101

Cited by 255 publications

(135 citation statements)

References 17 publications

(20 reference statements)

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“…The presence of interfaces imposes restrictions on the atomic displacements since the atoms at the boundary of the FE are bonded to the electrodes. This effect was demonstrated in KNbO 3 FE films placed between SrRuO 3 or Pt electrodes [160], as well as BaTiO 3 with SrRuO 3 [161,162], Fe [116] and Pt [163] electrodes. First-principles transport calculations for Pt/BaTiO 3 /Pt FTJs show that the interface transmission function [164] of the Pt/BaTiO 3 interface differs by a factor of three depending on the polarization direction [159].…”

Section: (A) Ferroelectric Tunnel Junctionsmentioning

confidence: 93%

Multi-ferroic and magnetoelectric materials and interfaces

Velev

Jaswal

Tsymbal

2011

Phil. Trans. R. Soc. A.

204

144

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The existence of multiple ferroic orders in the same material and the coupling between them have been known for decades. However, these phenomena have mostly remained the theoretical domain owing to the fact that in single-phase materials such couplings are rare and weak. This situation has changed dramatically recently for at least two reasons: first, advances in materials fabrication have made it possible to manufacture these materials in structures of lower dimensionality, such as thin films or wires, or in compound structures such as laminates and epitaxial-layered heterostructures. In these designed materials, new degrees of freedom are accessible in which the coupling between ferroic orders can be greatly enhanced. Second, the miniaturization trend in conventional electronics is approaching the limits beyond which the reduction of the electronic element is becoming more and more difficult. One way to continue the current trends in computer power and storage increase, without further size reduction, is to use multi-functional materials that would enable new device capabilities. Here, we review the field of multi-ferroic (MF) and magnetoelectric (ME) materials, putting the emphasis on electronic effects at ME interfaces and MF tunnel junctions.

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Section: (A) Ferroelectric Tunnel Junctionsmentioning

confidence: 93%

Multi-ferroic and magnetoelectric materials and interfaces

Velev

Jaswal

Tsymbal

2011

Phil. Trans. R. Soc. A.

204

144

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“…Correspondingly, in the beginning of XXI century the main model for ferroelectric screening has become external screening by surface ionic charges, as explored by SPM, 74,76 X-ray 78,228 and density functional theory. 235 The direct visualization of the mobile surface charges was performed using time-resolved Kelvin Probe Microscopy. 236,237 The necessary consequence of the ionic screening model is that polarization switching necessitates the redistribution of the screening charges, and overall polarization dynamics is now controlled both by ferroelectric and ionic subsystems.…”

Section: A Surface Ionic Screeningmentioning

confidence: 99%

Ferroelectric or non-ferroelectric: Why so many materials exhibit “ferroelectricity” on the nanoscale

Vasudevan

Balke

Maksymovych

et al. 2017

Applied Physics Reviews

264

206

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Ferroelectric materials have remained one of the foci of condensed matter physics and materials science for over 50 years. In the last 20 years, the development of voltage-modulated scanning probe microscopy techniques, exemplified by Piezoresponse force microscopy (PFM) and associated time-and voltage spectroscopies, opened a pathway to explore these materials on a single-digit nanometer level. Consequently, domain structures, walls and polarization dynamics can now be imaged in real space. More generally, PFM has allowed studying electromechanical coupling in a broad variety of materials ranging from ionics to biological systems. It can also be anticipated that the recent Nobel prize 1 in molecular electromechanical machines will result in rapid growth in interest in PFM as a method to probe their behavior on single device and device assembly levels. However, the broad introduction of PFM also resulted in a growing number of reports on nearly-ubiquitous presence of ferroelectric-like phenomena including remnant polar states and electromechanical hysteresis loops in materials which are non-ferroelectric in the bulk, or in cases where size effects are expected to suppress ferroelectricity. While in certain cases plausible physical mechanisms can be suggested, there is remarkable similarity in observed behaviors, irrespective of the materials system. In this review, we summarize the basic principles of PFM, briefly discuss the features of ferroelectric surfaces salient to PFM imaging and spectroscopy, and summarize existing reports on ferroelectric-like responses in non-classical ferroelectric materials. We further discuss possible mechanisms behind observed behaviors, and possible experimental strategies for their identification.3

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“…1 A FTJ consists of two metal electrodes separated by a nm-thick ferroelectric barrier which allows electron tunneling through it. Recent experimental 2-4 and theoretical [5][6][7][8] studies of perovskite ferroelectric oxide thin films have demonstrated that ferroelectricity persists down to a nanometer scale, which makes it possible to use ferroelectrics as functional tunnel barriers in FTJs. Contrary to ferroelectric capacitors where leakage currents are detrimental to the device performance, 9 the conductance of a FTJ is the functional characteristic of the device.…”

Section: Introductionmentioning

confidence: 99%

Effect of spin-dependent screening on tunneling electroresistance and tunneling magnetoresistance in multiferroic tunnel junctions

2010

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Zhuravlev, M. Ye.; Maekawa, S.; and Tsymbal, Evgeny Y., "Effect of spin-dependent screening on tunneling electroresistance and tunneling magnetoresistance in multiferroic tunnel junctions" (2010 Using a ferroelectric barrier as a functional material in a ͑magnetic͒ tunnel junction has recently attracted significant interest due to new functionalities not available in conventional tunnel junctions. Switching a ferroelectric polarization of the barrier alters conductance resulting in a tunneling electroresistance ͑TER͒ effect. Using a ferroelectric barrier in a magnetic tunnel junction makes it mutiferroic where TER coexists with tunneling magnetoresistance ͑TMR͒. Here we develop a simple model for a multiferroic tunnel junction ͑MFTJ͒ which consists of two ferromagnetic electrodes separated by a ferroelectric barrier layer. The model explicitly includes the spin-dependent screening potential and thus extends previously developed models for FTJs and MFTJs. Our results demonstrate that the effect of spin-dependent screening may be sizable and may provide significant contributions to TMR and TER in MFTJs. We find that, similar to FTJs with a composite ͑ferroelectric/dielectric͒ barrier layer, the TER in a MFTJ with such a barrier is dramatically enhanced indicating that the resistance ratio between the states corresponding to the opposite polarization orientations may be as high as 10 4 and even higher. Our results demonstrate the possibility of four resistance states in MFTJs with a pronounced difference in resistance and a possibility to control these resistance by an electric field ͑through ferroelectric polarization of the barrier͒ and by a magnetic field ͑through magnetization configuration of the electrodes͒. These functionalities may be interesting to device applications of MFTJs.

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Ferroelectricity in ultrathin perovskite films

Cited by 255 publications

References 17 publications

Multi-ferroic and magnetoelectric materials and interfaces

Multi-ferroic and magnetoelectric materials and interfaces

Ferroelectric or non-ferroelectric: Why so many materials exhibit “ferroelectricity” on the nanoscale

Effect of spin-dependent screening on tunneling electroresistance and tunneling magnetoresistance in multiferroic tunnel junctions

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