Structure, Ferroelectricity, and Magnetism in Self‐Assembled BiFeO3–CoFe2O4 Nanocomposites on (110)‐LaAlO3 Substrates

Tian, Guo; Ojha, Shuchi; Ning, Shuai; Gao, Xingsen; Ross, Caroline A.

doi:10.1002/aelm.201900012

Cited by 15 publications

(20 citation statements)

References 42 publications

(62 reference statements)

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“…47 Meanwhile, advanced probe microscopes have been employed to directly observe and verify these phase/polarization distributions (with/without fields) of each domain at the micron/nanoscale. [48][49][50] It has been reported that the pillar size plays a critical role in controlling ME coupling in BTO-CFO VANs as it is determined by the competition between the vertical interface coupling effect and the bulk volume conservation effect. 51,52 Moreover, experiments have also been widely performed to improve the phase distribution morphologies and to enhance the properties of ME VANs.…”

Section: Understanding What Controls Me Vans and Rich Approaches To Adjustments Via Film Growthmentioning

confidence: 99%

Magnetoelectricity in vertically aligned nanocomposites: Past, present, and future

et al. 2021

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Vertically aligned magnetoelectric nanocomposites (ME VANs) self-assembled from piezoelectric perovskite and magnetostrictive spinel phases are appealing due to their unique pillar-array-like morphologies and enhanced ME properties. The strain-mediated ME effect leads to various field-dependent characteristics that are tunable, which provides application pathways in microelectronics. The microstructure formation mechanisms of ME VANs have been explored by phase field simulations. Several effective approaches to modify and improve the ME properties of VANs are discussed, including orientations, deposition conditions, and substrate types. Potential applications are also discussed, such as field tunable "adaptive" microelectronics and multistate memory devices.

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Section: Understanding What Controls Me Vans and Rich Approaches To Adjustments Via Film Growthmentioning

confidence: 99%

Magnetoelectricity in vertically aligned nanocomposites: Past, present, and future

et al. 2021

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“…[34][35][36] Doing so, BFO structure and properties can be widely modified, adapting and designing the material to different situations/use/working conditions and recent works have been focused on BFO A-site doping. BFO systems have been deposited on various substrates using pulsed laser deposition (PLD), [37,38] metal organic chemical vapor deposition (MOCVD), [39][40][41][42][43] sputtering, [44] sol-gel, [45,46] and chemical solution deposition. [38,47] In this study, we report on the promising pyroelectric properties of pure BFO and Dy-doped BFO (BDFO) films deposited, through a simple, easily scalable MOCVD approach, on Nb doped SrTiO 3 (STO:Nb) (001) single crystal substrates.…”

Section: Introductionmentioning

confidence: 99%

Self‐Poled Heteroepitaxial Bi₍₁₋_x₎Dy_xFeO₃ Films with Promising Pyroelectric Properties

Micard

Clementi

Bartasyte

et al. 2022

Adv Materials Inter

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Pyroelectric materials are very promising for thermal energy harvesting applications. To date, lead‐based systems are the foremost studied materials in this field. A facile and simple metal organic chemical vapor deposition route is applied for the fabrication of lead‐free, high quality, epitaxial Bi(1−x)DyxFeO3 (x = 0, 0.06, 0.08, 0.11) thin films deposited on conductive SrTiO3:Nb (100) single crystal substrates. The films are studied by structural, morphological, compositional, and functional characterization. The correlation between the Dy‐doping amount and the dielectric properties is thoroughly investigated. Unipolar polarization–electric field loops and permittivity measurements show the important impact of Dy on ferroelectric, dielectric, and pyroelectric properties. Dy doping increases considerably the dielectric response, but much more the pyroelectric coefficient, up to a concentration of 8% Dy. The films are self‐poled, which is an ideal situation for pyroelectric applications. The best figure of merit for pyroelectric energy harvesting, FE, is 82 J m−3 K−2, showing a factor increase of 2.6 as compared to the undoped film of the sample series. It constitutes a factor 4.5 improvement as compared to previous results obtained on BiFeO3 based thin films.

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“…Piezoresponse force microscopy (PFM) is an essential tool for studying ferroelectric properties of such systems with nanoscale spatial variations. [1,2,[4][5][6][7][8][9]14,[16][17][18][19][20][21]38,39,43,44] For ferroelectric switching of BFO-CFO VAN systems, however, only one or a few local hysteresis loops are typically measured, usually by "parking" a conductive atomic force microscopy (AFM) probe at single or arrayed points in BFO, sweeping the tip-sample bias, and recording the resulting changes in the piezoresponse. [2,4,11,[15][16][17][18]28,38] Single-point hysteresis measurements can be challenging to interpret, though, due to the superposition of piezoelectric effects and electrostatics [45] or ionic motion.…”

Section: Introductionmentioning

confidence: 99%

“…[1,2,[4][5][6][7][8][9]14,[16][17][18][19][20][21]38,39,43,44] For ferroelectric switching of BFO-CFO VAN systems, however, only one or a few local hysteresis loops are typically measured, usually by "parking" a conductive atomic force microscopy (AFM) probe at single or arrayed points in BFO, sweeping the tip-sample bias, and recording the resulting changes in the piezoresponse. [2,4,11,[15][16][17][18]28,38] Single-point hysteresis measurements can be challenging to interpret, though, due to the superposition of piezoelectric effects and electrostatics [45] or ionic motion. [46] Topographic crosstalk is another persistent concern due to sensitivities to the tip-sample contact area, especially when the surface morphology exhibits changes in slope or curvature with length scales equivalent to the dimensions of the tip apex.…”

Section: Introductionmentioning

confidence: 99%

Interfacial‐Strain‐Controlled Ferroelectricity in Self‐Assembled BiFeO₃ Nanostructures

Song

Zhuang

Martin

et al. 2021

Adv Funct Materials

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Self‐assembled BiFeO3‐CoFe2O4 (BFO‐CFO) vertically aligned nanocomposites are promising for logic, memory, and multiferroic applications, primarily due to the tunability enabled by strain engineering at the prodigious epitaxial vertical interfaces. However, local investigations directly revealing functional properties in the vicinity of such critical interfaces are often hampered by the size, geometry, microstructure, and concomitant experimental artifacts. Ferroelectric switching in the presence of lateral distributions of vertical strain thus remains relatively unexplored, with broader implications for all strain‐engineered functional devices. By implementing tomographic atomic force microscopy, 3D domain orientation mapping, and spatially‐resolved ferroelectric switching movies, local tensile strain significantly impacts the ferroelectric switching, principally by retarding domain nucleation in the BFO nearest to the vertically epitaxial tensile‐strained interfaces. The relaxed centers of the BFO pillars become preferred domain nucleation and growth sites for low biases, with up to an order of magnitude change in the edge:center switching ratio for high biases. The new, multi‐dimensional imaging approach—and its corresponding insights especially for directly strained interface effects on local properties—thereby advances the fundamental understanding of polarization switching and provides design principles for optimizing functional response in confined nanoferroic systems.

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Structure, Ferroelectricity, and Magnetism in Self‐Assembled BiFeO₃–CoFe₂O₄ Nanocomposites on (110)‐LaAlO₃ Substrates

Cited by 15 publications

References 42 publications

Magnetoelectricity in vertically aligned nanocomposites: Past, present, and future

Magnetoelectricity in vertically aligned nanocomposites: Past, present, and future

Self‐Poled Heteroepitaxial Bi₍₁₋_x₎Dy_xFeO₃ Films with Promising Pyroelectric Properties

Interfacial‐Strain‐Controlled Ferroelectricity in Self‐Assembled BiFeO₃ Nanostructures

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Structure, Ferroelectricity, and Magnetism in Self‐Assembled BiFeO3–CoFe2O4 Nanocomposites on (110)‐LaAlO3 Substrates

Cited by 15 publications

References 42 publications

Magnetoelectricity in vertically aligned nanocomposites: Past, present, and future

Magnetoelectricity in vertically aligned nanocomposites: Past, present, and future

Self‐Poled Heteroepitaxial Bi(1−x)DyxFeO3 Films with Promising Pyroelectric Properties

Interfacial‐Strain‐Controlled Ferroelectricity in Self‐Assembled BiFeO3 Nanostructures

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Structure, Ferroelectricity, and Magnetism in Self‐Assembled BiFeO₃–CoFe₂O₄ Nanocomposites on (110)‐LaAlO₃ Substrates

Self‐Poled Heteroepitaxial Bi₍₁₋_x₎Dy_xFeO₃ Films with Promising Pyroelectric Properties

Interfacial‐Strain‐Controlled Ferroelectricity in Self‐Assembled BiFeO₃ Nanostructures