Ferroelectricity in Ultrathin Perovskite Films

Fong, Dillon D.; Stephenson, G. B.; Streiffer, S. K.; Eastman, J. A.; Auciello, O.; Fuoss, P. H.; Thompson, Carol

doi:10.1126/science.1098252

Cited by 1,224 publications

(881 citation statements)

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“…This is consistent with experimental XRD results for PbTiO 3 films of similar thickness [31,32] and PbTiO 3 /SrTiO 3 superlattices [19,33,34]. Morphologically, these are LandauLifshitz domains having 90 • closure domain caps at the surface as previously observed in theoretical studies of PbTiO 3 films using interatomic potentials [11,35].…”

Section: Aa Domainssupporting

confidence: 80%

“…For films using a s = 3.99Å at 25 K the law is satisfied for N z ≥ 5 (001)PbO layers (2 nm) which returns a periodicity of 4.0 nm in agreement with experiment [31]. For thinner films the out-of-plane components of polarisation vanishes [32] but we observe that ferroelectricity is maintained with the polarisation reorientated in-plane (a-domain). Such reorientation has also been shown for PbTiO 3 films using DFT [36].…”

Section: Aa Domainssupporting

confidence: 66%

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Novel high-temperature ferroelectric domain morphology in PbTiO₃ ultrathin films

Chapman

Kimmel

Duffy

2017

Phys. Chem. Chem. Phys.

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Exotic domain morphologies in ferroic materials are an exciting avenue for the development of novel nanoelectronics. In this work we have used large scale molecular dynamics to construct a strain-temperature phase diagram of the domain morphology of PbTiO3 ultrathin films. Sampling a wide interval of strain values over a temperature range up to the Curie temperature Tc, we found that epitaxial strain induces the formation of a variety of closure-and in-plane domain morphologies. The local strain and ferroelectric-antiferrodistortive coupling at the film surface vary for the strain mediated transition sequence and this could offer a route for experimental observation of the morphologies. Remarkably, we identify a new nanobubble domain morphology that is stable in the high-temperature regime for compressively strained PbTiO3. We demonstrate that the formation mechanism of the nanobubble domains morphology is related to the wandering of flux closure domain walls, which we characterise using the hypertoroidal moment. These results provide insight into the local behaviour and dynamics of ferroelectric domains in ultrathin films to open up potential applications for bubble domains in new technologies and pathways to control and exploit novel phenomena in dimensionally constrained materials.

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Section: Aa Domainssupporting

confidence: 80%

Section: Aa Domainssupporting

confidence: 66%

Novel high-temperature ferroelectric domain morphology in PbTiO₃ ultrathin films

Chapman

Kimmel

Duffy

2017

Phys. Chem. Chem. Phys.

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“…6,7,8 Furthermore, Fong et al showed that ferroelectric phases can be stable down to ∼12Å (three unit cells) in PbTiO 3 films by forming 180 • stripe domains, suggesting that no fundamental thickness limit is imposed by the intrinsic size effect in thin films. 9 This idea has been corroborated by ab initio calculations carried out on perovskite films, which tell that no critical thickness exists for polarization parallel to the surface 10 and that polarization perpendicular to the surface can exist in films three unit-cells thick if the depolarization field is artificially removed. 11,12 On the other hand, it has been found that the depolarization field plays a dominant role in reducing polarization normal to the surface and depressing ferroelectric transition temperatures in thin films.…”

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confidence: 60%

Ferroelectricity in ultrathin perovskite films

2005

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We report studies of ferroelectricity in ultra-thin perovskite films with realistic electrodes. The results reveal stable ferroelectric states in thin films less than 10Å thick with polarization normal to the surface. Under short-circuit boundary conditions, the screening effect of realistic electrodes and the influence of real metal/oxide interfaces on thin film polarization are investigated. Our studies indicate that metallic screening from the electrodes is affected by the difference in work functions at oxide surfaces. We demonstrate this effect in ferroelectric PbTiO3 and BaTiO3 films.The effect of size on thin-film ferroelectricity has been known for a long time, but has not been completely understood. Initial experiments and mean field calculations based on the Landau theory suggested that below a critical correlation volume 1 of electrical dipoles between 10-100 nm 3 , ferroelectricity vanishes due to intrinsic size effects. 2,3 For thin films with the polar axis perpendicular to the surface, incomplete compensation of surface charges creates a depolarizing field that has been shown to further reduce the polarization stability. 4,5 Recently, however, monodomain ferroelectric phases have been observed in very thin films, below ten unitcells thick. 6,7,8 Furthermore, Fong et al. showed that ferroelectric phases can be stable down to ∼12Å (three unit cells) in PbTiO 3 films by forming 180 • stripe domains, suggesting that no fundamental thickness limit is imposed by the intrinsic size effect in thin films. 9 This idea has been corroborated by ab initio calculations carried out on perovskite films, which tell that no critical thickness exists for polarization parallel to the surface 10 and that polarization perpendicular to the surface can exist in films three unit-cells thick if the depolarization field is artificially removed. 11,12 On the other hand, it has been found that the depolarization field plays a dominant role in reducing polarization normal to the surface and depressing ferroelectric transition temperatures in thin films. In a continuum model by Batra et al. 4 which includes the depolarization effect, a critical thickness of 100Å for perovskite films was analytically derived, assuming a Thomas-Fermi screening length of 1Å for the metal electrodes. Also, a recent first-principles calculation revealed that BaTiO 3 films with SrRuO 3 electrodes lose ferroelectricity below ∼24Å (6 unit cells), 13 thus suggesting that a minimum thickness limit exists for useful ferroelectric films. While indeed a minimum film thickness must be influenced by the polarization of the ferroelectrics and the screening length of the electrodes, 14 it is not yet clear whether the depolarizing field can ever be completely removed by realistic electrodes on ultrathin films, nor how monodomain thin film ferroelectricity is affected by the choice of electrodes and by the interactions at the metal/oxide interface.In this paper, we provide answers to these questions.In particular, we investigate how the critical thickness varies ...

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“…[[qv: 166c]],170 However, most studies are focused on thin‐film ferroelectric materials. As predicted, 1D ferroelectric nanostructures, where the unit cell and its corresponding ferroelectric/piezoelectric properties are supposed to be significantly influenced by the surface effect,171 might bring considerable advances to the research of FE‐PV devices. In 2015, Fei at al 71.…”

Section: Properties and Applicationsmentioning

confidence: 83%

One‐Dimensional Ferroelectric Nanostructures: Synthesis, Properties, and Applications

et al. 2016

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One‐dimensional (1D) ferroelectric nanostructures, such as nanowires, nanorods, nanotubes, nanobelts, and nanofibers, have been studied with increasing intensity in recent years. Because of their excellent ferroelectric, ferroelastic, pyroelectric, piezoelectric, inverse piezoelectric, ferroelectric‐photovoltaic (FE‐PV), and other unique physical properties, 1D ferroelectric nanostructures have been widely used in energy‐harvesting devices, nonvolatile random access memory applications, nanoelectromechanical systems, advanced sensors, FE‐PV devices, and photocatalysis mechanisms. This review summarizes the current state of 1D ferroelectric nanostructures and provides an overview of the synthesis methods, properties, and practical applications of 1D nanostructures. Finally, the prospects for future investigations are outlined.

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Ferroelectricity in Ultrathin Perovskite Films

Cited by 1,224 publications

References 26 publications

Novel high-temperature ferroelectric domain morphology in PbTiO₃ ultrathin films

Novel high-temperature ferroelectric domain morphology in PbTiO₃ ultrathin films

Ferroelectricity in ultrathin perovskite films

One‐Dimensional Ferroelectric Nanostructures: Synthesis, Properties, and Applications

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Ferroelectricity in Ultrathin Perovskite Films

Cited by 1,224 publications

References 26 publications

Novel high-temperature ferroelectric domain morphology in PbTiO3 ultrathin films

Novel high-temperature ferroelectric domain morphology in PbTiO3 ultrathin films

Ferroelectricity in ultrathin perovskite films

One‐Dimensional Ferroelectric Nanostructures: Synthesis, Properties, and Applications

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Novel high-temperature ferroelectric domain morphology in PbTiO₃ ultrathin films

Novel high-temperature ferroelectric domain morphology in PbTiO₃ ultrathin films