Flexoelectricity in dielectrics: Materials, structures and characterizations

Huang, Shujin; Qi, Lu; Huang, Wenbin; Shu, Longlong; Zhou, Shenjie; Jiang, Xiaoning

doi:10.1142/s2010135x18300025

Cited by 46 publications

(27 citation statements)

References 87 publications

(102 reference statements)

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“…The flexoelectric coefficients of most dielectric solids, especially the simple ones, are estimated theoretically to be too small ,, to induce sufficient strain gradient for mechanical switching. Particularly, flexoelectricity can be omitted when other electromechanical responses (e.g., piezoelectricity) exist in the materials. , However, it was later found that in some dielectrics owning to high permittivity, their flexoelectricity is unexpectedly largely enhanced and possibly sufficient to induce polarization, , where the flexoelectric coefficients are in several or even tens of orders of higher magnitude. − These reported high permittivity dielectrics with giant flexoelectricity include paraelectric SrTiO 3 , and perovskite piezoelectrics, especially perovskite relaxors such as PMN, , perovskite ferroelectrics such as Pb-based systems like Pb(Zr,Ti)O 3 , , BaTiO 3 -based systems like BaTiO 3 , , Ba(Ti,Sn)O 3 , BaTiO 3 –Ba(Zr,Ti)O 3 , and (K,Na)NbO 3 -based systems, and perovskite relaxor ferroelectrics like PMN–PT ,,− and PIN–PMN–PT . According to Tagantsev’s flexoelectric theory, , the possible mechanisms of these enhanced flexoelectricity in bulks include four contributions: dynamic bulk flexoelectricity, static bulk flexoelectricity, surface flexoelectricity, and surface piezoelectricity. , The mechanisms of a barrier layer, inner microstrains resulted from macroscopic centric symmetry breaking, ferroelectricity, , and PNRs , are also proposed recently.…”

Section: Resultsmentioning

confidence: 99%

“…According to Tagantsev’s flexoelectric theory, , the possible mechanisms of these enhanced flexoelectricity in bulks include four contributions: dynamic bulk flexoelectricity, static bulk flexoelectricity, surface flexoelectricity, and surface piezoelectricity. , The mechanisms of a barrier layer, inner microstrains resulted from macroscopic centric symmetry breaking, ferroelectricity, , and PNRs , are also proposed recently. In relaxor ferroelectrics such as PMN–PT, PIN–PMN–PT single crystal, it is believed that polar nanodomain rotation polarization, , residual piezoelectricity, surface piezoelectricity, and surface flexoelectricity can give rise to these enhanced flexoelectric behaviors. Notably, the PNRs are reported to be one important source of the residual flexoelectricity. , Besides, PNRs are in dominant contribution (50–80%) to the room-temperature ultrahigh piezoelectricity in relaxor ferroelectric solid solution crystals, which can facilitate polarization rotation and enhance ferroelectricity/piezoelectricity and thus couple extrinsically , with their flexoelectricity.…”

Section: Resultsmentioning

confidence: 99%

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Mechanical-Induced Polarization Switching in Relaxor Ferroelectric Single Crystals

Bian

Wang

Zhu³

et al. 2019

ACS Appl. Mater. Interfaces

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Control of coupling between electric and elastic orders in ferroelectric bulks is vital to understand their nature and enrich the multifunctionality of polarization manipulation applied in domain-based electronic devices such as ferroelectric memories and data storage ones. Herein, taking (1 – x%)Pb(Mg1/3Nb2/3)O3–x%PbTiO3 (PMN–x%PT, x = 32, 40) as the prototype, we demonstrate the less-explored mechanical switching in relaxor ferroelectric single crystals using scanning probe microscopy. Low mechanical forces can induce metastable and electrically erasable polarization reversal clearly from electrical-created bipolar domains around the 180° domain wall in monoclinic PMN–32%PT and inside the c+ domain in tetragonal PMN–40%PT. The mechanical switching evolutions show force/time dependence and time-force equivalence. The time-dependent mechanical switching behavior stems from the participation and contribution of polar nanoregions. Flexoelectricity and bulk Vegard strain effect can account for the mechanical switching but notably, the former in the two has very different origins. These investigations exhibit the possibility of mechanical switching as a tool to manipulate polarization states in ferroelectric bulks, and provide the potential of these crystals as substrates in mechanical polarization control of future thin-film devices.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Mechanical-Induced Polarization Switching in Relaxor Ferroelectric Single Crystals

Bian

Wang

Zhu³

et al. 2019

ACS Appl. Mater. Interfaces

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“…The flexoelectric effect is a phenomenon in which the gradient of material alignment induces electric polarization . The piezoelectric effect differs from the flexoelectric effect as polarization is induced by uniform displacement in the piezoelectric effect. , The flexoelectric effect appears in various materials, such as ceramics, polymers, biological thin films, and liquid crystals (LCs). ,− There have been studies using this effect for electrical energy harvesting, actuators, and sensors.…”

Section: Introductionmentioning

confidence: 99%

Electrical Energy Harvesting from the Flexible Liquid Crystal Cells

Lee

et al. 2021

J. Phys. Chem. C

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Electrical energy was harvested by the flexoelectric effect of the nematic liquid crystal. Nematic liquid crystal cells with vertical and planar alignment were fabricated with ITOcoated flexible substrates. With the bending of the cells, liquid crystal deformation is formed, and electric polarization is induced by the splay and bend mode in the flexoelectric effect. Electric charge is generated at the substrate electrode, and electromotive force occurs between both electrodes. An energy of 10 −10 J was obtained with moderate bending in a 2 × 1 cm 2 cell used. The electromotive force was dependent on the bending, cell gap, and alignment. The electricitygenerating process was explained using a model. Even though the harvested energy is currently limited, various applications may be possible owing to the flexibility and softness of the liquid crystal.

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“…Furthermore, only a few polymers exhibit significant piezoelectricity (Bauer and Bauer, 2008). Thus, quantifying flexoelectricity at large deformations may enable the design of efficient electromechanical elastomeric devices, such as sensors, actuators and energy harvesters, based on the flexoelectric effect (Jiang et al, 2013, Huang et al, 2018, Wang et al, 2019.…”

Section: Introductionmentioning

confidence: 99%

Modeling flexoelectricity in soft dielectrics at finite deformation

Codony,

Gupta,

Marco

et al. 2020

Preprint

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This paper develops the equilibrium equations describing the flexoelectric effect in soft dielectrics under large deformations. Previous works have developed related theories using a flexoelectric coupling tensor of mixed material-spatial character. Here, we formulate the model in terms of a flexoelectric tensor completely defined in the material frame, with the same symmetries of the small-strain flexocoupling tensor and leading naturally to objective flexoelectric polarization fields. The energy potential and equilibrium equations are first expressed in terms of deformation and polarization, and then rewritten in terms of deformation and electric potential, yielding an unconstrained system of fourth order partial differential equations (PDE). We further develop a theory of geometrically nonlinear extensible flexoelectric rods under open and closed circuit conditions, with which we examine cantilever bending and buckling under mechanical and electrical actuation. Besides being a simple and explicit model pertinent to slender structures, this rod theory also allows us to test our general theory and its numerical implementation using B-Splines. This numerical implementation is robust as it handles the electromechanical instabilities in soft flexoelectric materials.

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Flexoelectricity in dielectrics: Materials, structures and characterizations

Cited by 46 publications

References 87 publications

Mechanical-Induced Polarization Switching in Relaxor Ferroelectric Single Crystals

Mechanical-Induced Polarization Switching in Relaxor Ferroelectric Single Crystals

Electrical Energy Harvesting from the Flexible Liquid Crystal Cells

Modeling flexoelectricity in soft dielectrics at finite deformation

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