Beyond Substrates: Strain Engineering of Ferroelectric Membranes

Pesquera, David; Parsonnet, Eric; Qualls, Alexander; Xu, Ruijuan; Gubser, A.J.; Kim, Jieun; Jiang, Yizhe; Velarde, Gabriel; Huang, Ying; Hwang, Harold Y.; Ramesh, R.; Martin, Lane W.

doi:10.1002/adma.202003780

Cited by 71 publications

(76 citation statements)

References 69 publications

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“…All these synthesis processes avoid strong bonding of the films with the substrate, thus expanding the combinatorial approaches to fabricate multifunctional devices. Beyond this, the film-transfer methods also provide opportunities to explore new phases/properties when approaching the two-dimensional limit [75,76], target enhancement of properties typically clamped by the substrate in epitaxial systems [72], and provide mechanical control of properties and domain structures beyond the current limitations of heteroepitaxy [77,78]. These processing techniques are a "hot" field of work and new exciting studies are expected to appear in the next few years.…”

Section: Device Integration Via Epitaxial Lift-offmentioning

confidence: 99%

Beyond Expectation: Advanced Materials Design, Synthesis, and Processing to Enable Novel Ferroelectric Properties and Applications

et al. 2020

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Ferroelectrics and related materials (e.g., non-traditional ferroelectrics such as relaxors) have long been used in a range of applications, but with the advent of new ways of modeling, synthesizing, and characterizing these materials, continued access to astonishing breakthroughs in our fundamental understanding come each year. While we still rely on these materials in a range of applications, we continue to re-write what is possible to be done with them. In turn, assumptions that have underpinned the use and design of certain materials are progressively being revisited. This perspective aims to provide an overview of the field of ferroelectric/relaxor/polar-oxide thin films in recent years, with an emphasis on emergent structure and function enabled by advanced synthesis, processing, and computational modeling.

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Section: Device Integration Via Epitaxial Lift-offmentioning

confidence: 99%

Beyond Expectation: Advanced Materials Design, Synthesis, and Processing to Enable Novel Ferroelectric Properties and Applications

et al. 2020

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“…Further, BFO follows a two-step switching pathway consisting of out-of-plane (109º) and in-plane (71º) steps, thereby, offering an ideal system to study how substrate constraints impact switching. These measurements are also complemented by similar measurements in the literature [26] on thin films of ferroelectric BTO, a prototypical tetragonal ferroelectric, which is used to highlight how substrate clamping impacts a variety of ferroelectric materials. The data reveal a clear impact on the switching voltage (a measure of the barrier energy) as well as the switching dynamics (as manifested by changes in the switching time).…”

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confidence: 95%

“…While there have been a large number of studies of quasi-static switching behavior and equilibrium properties of thin films [16]- [20], there have been fewer studies of the limits and timescales of ultrafast switching [21]- [25], and even fewer on the role of lattice dynamics in influencing ferroelectric switching [26]. A key question is how to quantify the role of the substrate in dictating the switching process and whether switching can be studied experimentally without the influence of the substrate.…”

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confidence: 99%

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The role of lattice dynamics in ferroelectric switching

Shi

Parsonnet

Chen

et al. 2021

Preprint

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Reducing the switching energy of ferroelectric thin films remains an important goal in the pursuit of ultralow power ferroelectric memories and magnetoelectric spin-orbit logic devices. Here, we elucidate the fundamental role of lattice dynamics in ferroelectric switching by combining thermodynamic calculations, experiments, and phase-field simulations on both freestanding BiFeO3 membranes and films clamped to a substrate. We observe a distinct evolution of the ferroelectric domain pattern, from striped, 71° ferroelastic domains (spacing of ~100 nm) in clamped BiFeO3 films, to large (10’s of micrometers) 180° domains or even single domain structures, in freestanding films. Through the use of piezoresponse force microscopy, X-ray diffraction, polarization-electric field hysteresis loops, and high-speed pulsed ferroelectric switching experiments, it is found that removing the constraints imposed by the requirement of macroscopic continuity of deformation (also known as the von Mises criterion in the deformation of solids)[1]–[3] to the substrate, we can realize a ~40% reduction of the switching voltage and a consequent ~60% gain in the switching speed. The work highlights the critical role of mechanics and the clamping effect from the substrate in setting the energetics and dynamics of switching in ferroelectrics.

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“…Recently, more approaches for strain engineering have come to the fore. Examples include mechanically straining free-standing single-crystalline membranes [ 8 , 14 ] grown on the buffered substrate where the buffer layer can be etched off thereafter, and the ion implantation of species such as helium [ 15 ] and nitrogen [ 16 ] to strain the lattice. Perovskite materials have also garnered interest in a wide range of applications such as solar cells, photo/electrocatalysis, photopolymerization, thermoelectrics, resistive switching devices, etc.…”

Section: Introductionmentioning

confidence: 99%

Strain Engineering: A Pathway for Tunable Functionalities of Perovskite Metal Oxide Films

et al. 2022

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Perovskite offers a framework that boasts various functionalities and physical properties of interest such as ferroelectricity, magnetic orderings, multiferroicity, superconductivity, semiconductor, and optoelectronic properties owing to their rich compositional diversity. These properties are also uniquely tied to their crystal distortion which is directly affected by lattice strain. Therefore, many important properties of perovskite can be further tuned through strain engineering which can be accomplished by chemical doping or simply element substitution, interface engineering in epitaxial thin films, and special architectures such as nanocomposites. In this review, we focus on and highlight the structure–property relationships of perovskite metal oxide films and elucidate the principles to manipulate the functionalities through different modalities of strain engineering approaches.

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Beyond Substrates: Strain Engineering of Ferroelectric Membranes

Cited by 71 publications

References 69 publications

Beyond Expectation: Advanced Materials Design, Synthesis, and Processing to Enable Novel Ferroelectric Properties and Applications

Beyond Expectation: Advanced Materials Design, Synthesis, and Processing to Enable Novel Ferroelectric Properties and Applications

The role of lattice dynamics in ferroelectric switching

Strain Engineering: A Pathway for Tunable Functionalities of Perovskite Metal Oxide Films

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