Strain-induced ferroelectricity and lattice coupling in BaSnO<sub>3</sub>and SrSnO<sub>3</sub>

Zhang, Yajun; Wang, Jie; Sahoo, M.P.K.; Shimada, Takahiro; Kitamura, Takayuki

doi:10.1039/c7cp03952b

Cited by 23 publications

(15 citation statements)

References 47 publications

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“…Meanwhile, the bandgap of the KNbO 3 was further reduced by 0.6 eV when subject to a −2% in‐plane strain . Similar phenomena were also observed in other compositions such as BaSnO 3 and SrSnO 3 , where tensile strain induced a significant bandgap narrowing effect (from 3 to 2–2.8 eV) …”

Section: Multifunctional Materials For Multisource Energy Harvestingsupporting

confidence: 78%

“…Apart from the effort made to reduce the BFO's bandgap, bandgap engineering has also been applied to other compositions. There are two effective methods reported for bandgap engineering of the ferroelectric materials—polarization rotation associated with phase change or strain and compositional modification via, for example, doping . Wang et al studied the bandgap engineering of seven types of ferroelectric crystals including LaScO 3 , BT, BaZrO 3 , PbTiO 3 , KTaO 3 , KNbO 3 , and WO 3 .…”

Section: Multifunctional Materials For Multisource Energy Harvestingmentioning

confidence: 99%

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Energy Harvesting Research: The Road from Single Source to Multisource

2018

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Energy harvesting technology may be considered an ultimate solution to replace batteries and provide a long-term power supply for wireless sensor networks. Looking back into its research history, individual energy harvesters for the conversion of single energy sources into electricity are developed first, followed by hybrid counterparts designed for use with multiple energy sources. Very recently, the concept of a truly multisource energy harvester built from only a single piece of material as the energy conversion component is proposed. This review, from the aspect of materials and device configurations, explains in detail a wide scope to give an overview of energy harvesting research. It covers single-source devices including solar, thermal, kinetic and other types of energy harvesters, hybrid energy harvesting configurations for both single and multiple energy sources and single material, and multisource energy harvesters. It also includes the energy conversion principles of photovoltaic, electromagnetic, piezoelectric, triboelectric, electrostatic, electrostrictive, thermoelectric, pyroelectric, magnetostrictive, and dielectric devices. This is one of the most comprehensive reviews conducted to date, focusing on the entire energy harvesting research scene and providing a guide to seeking deeper and more specific research references and resources from every corner of the scientific community.

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Section: Multifunctional Materials For Multisource Energy Harvestingsupporting

confidence: 78%

Section: Multifunctional Materials For Multisource Energy Harvestingmentioning

confidence: 99%

Energy Harvesting Research: The Road from Single Source to Multisource

2018

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“…Thus, the population structure can be captured by looking at the pairwise interactions between neurons. Many functional oxide properties (ferroelectricity in particular) depends precisely either in nanoscale correlation and atomic collective behavior which may also be induced by/to adjacent materials and interfaces [889] , [890] , [891] , [892] , [893] . In a Hebbian view [894] , synaptic efficacy arises from a presynaptic cell's repeated and persistent stimulation of a postsynaptic cell.…”

Section: Neural Codesmentioning

confidence: 99%

Functional Oxides for Photoneuromorphic Engineering: Toward a Solar Brain

Pérez‐Tomás

2019

Adv Materials Inter

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New device concepts and new computing principles are needed to balance our ever-growing appetite for data and information with the realization of the goals of increased energy efficiency, reduction in CO 2 emissions and the circular economy. Neuromorphic or synaptic electronics is an emerging field of research aiming to overcome the current computer's Von-Neumann bottleneck by building artificial neuronal systems to mimic the extremely energy efficient biological synapses. The introduction of photovoltaic and/or photonic aspects into these neuromorphic architectures will produce self-powered adaptive electronics but may also open up new possibilities in artificial neuroscience, artificial neural communications, sensing and machine learning which would enable, in turn, a new era for computational systems owing to the possibility of attaining high bandwidths with much reduced power consumption. This perspective is focused on recent progress in the implementation of functional oxide thinfilms into photovoltaic and neuromorphic applications towards the envisioned goal of selfpowered photovoltaic neuromorphic systems or a solar brain.

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“…A similar enhancement in piezoelectric properties is well-known for ferroelectric perovskites near to the phase-transition region 37,38 . We also mentioned that epitaxial strain has been intensively studied both theoretically and experimentally for inducing ferroelectricity in paraelectric perovskites 39,40 and rock-salt non-ferroelectric materials 41 .…”

mentioning

confidence: 99%

Ferroelectricity and Large Piezoelectric Response of AlN/ScN Superlattice

Noor‐A‐Alam

Olszewski

Nolan

2019

ACS Appl. Mater. Interfaces

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Based on density functional theory, we investigate the ferroelectric and piezoelectric properties of the AlN/ScN superlattice, consists of ScN and AlN buckled monolayers alternating along crystallographic c-direction. We nd that the polar wurtzite (w-ScAlN) structure is mechanically and dynamically stable, and is more stable than the nonpolar hexagonal at conguration. We show that ferroelectric polarization switching can be possible for epitaxially tensile strained superlattice. Due to the elastic constant C 33 softening along with an increase in e 33 , the piezoelectric coecient d 33 of the superlattice is doubled compared to pure w-AlN. The combined enhancement of Born eective charges (Z 33) and the sensitivity of the atomic coordinates to external strain (∂u 3 ∂η 3) is the origin of large piezoelectric constant e 33. Moreover, we show that epitaxial biaxial tensile strain signicantly enhances the piezo-response, so that d 33 becomes seven times larger than that of w-AlN at 4% strain. The tensile strain results in a huge enhancement in e 33 by increasing Z 33 and ∂u 3 ∂η 3 , which boosts the piezoelectric coecient. As short-period superlattice growth and epitaxial strain are already experimentally demonstrated in wurtzite nitrides, our results show a new more controlled approach

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Strain-induced ferroelectricity and lattice coupling in BaSnO₃and SrSnO₃

Cited by 23 publications

References 47 publications

Energy Harvesting Research: The Road from Single Source to Multisource

Energy Harvesting Research: The Road from Single Source to Multisource

Functional Oxides for Photoneuromorphic Engineering: Toward a Solar Brain

Ferroelectricity and Large Piezoelectric Response of AlN/ScN Superlattice

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Strain-induced ferroelectricity and lattice coupling in BaSnO3and SrSnO3

Cited by 23 publications

References 47 publications

Energy Harvesting Research: The Road from Single Source to Multisource

Energy Harvesting Research: The Road from Single Source to Multisource

Functional Oxides for Photoneuromorphic Engineering: Toward a Solar Brain

Ferroelectricity and Large Piezoelectric Response of AlN/ScN Superlattice

Contact Info

Product

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Strain-induced ferroelectricity and lattice coupling in BaSnO₃and SrSnO₃