All-Mechanical Polarization Control and Anomalous (Electro)Mechanical Responses in Ferroelectric Nanowires

Pappas, D.; Fthenakis, Zacharias G.; Ponomareva, I.

doi:10.1021/acs.nanolett.8b02818

Cited by 9 publications

(7 citation statements)

References 39 publications

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“…This Hamiltonian predicts phase transition from paraelectric cubic to ferroelectric tetragonal at 605 K which somewhat underestimates the experimental value of 763 K. [19] It correctly reproduces first-principles soft mode frequency and has been previously used to study dynamics of both PbTiO 3 , bulk and nanostructures. [20][21][22][23] The degrees of freedom for the Hamiltonian included local soft modes which were proportional to the local dipole moments and local strain variables that describe deformation of the unit cells. The Hamiltonian includes the interactions that are responsible for the ferroelectricity in PbTiO 3 : local mode self energy up to fourth order, harmonic short and long range interactions between the local modes, elastic deformations, and interactions responsible for the electrostriction.…”

Section: Computational Methodologymentioning

confidence: 99%

Insight into Pyroelectricity and Phase Transitions in Ferroelectrics from Nonequilibrium Approach: The Case of PbTiO₃

Lynch

Meng

Ponomareva

2022

Advcd Theory and Sims

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Computational methodology is proposed to simulate time dependent temperature variations via thermostat approach. The methodology is applied to study pyroelectricity under nonequilibrium conditions in prototypical ferroelectric PbTiO 3 . It is found that at room temperature the nonequilibrium effects in pyroelectricity begin manifesting above 1.0 THz and originate from the overlap with the intrinsic soft mode frequency. Therefore, the proposed computational methodology can be used to predict equilibrium pyroelectric response by choosing a frequency of temperature variation below the intrinsic polar mode frequencies for the material. Probing the dynamics of ferroelectric phase transition with the proposed methodology revealed that it takes about a nanosecond for the computational supercell to undergo phase transition. It is concluded that computational techniques capable of simulating picoseconds can be used to compute pyroelectric response from nonequilibrium dynamical approach while those that can reach nanoseconds are suitable for simulating phase transitions in ferroelectrics.

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Section: Computational Methodologymentioning

confidence: 99%

Insight into Pyroelectricity and Phase Transitions in Ferroelectrics from Nonequilibrium Approach: The Case of PbTiO₃

Lynch

Meng

Ponomareva

2022

Advcd Theory and Sims

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“…Such an approach has previously been used to simulate the dynamical and equilibrium properties of ferroelectrics and their nanostructures. 18,19,21,23 The dc electric field was applied and removed by a sequential increase and decrease, respectively, from 0 to 2000 kV/cm.…”

Section: ■ Conclusionmentioning

confidence: 99%

“…Experiments, ,− as well as many simulations, − have beautifully established the presence of multiple phases and polarization rotations in BTO-based compositions at the nanoscale. Our previous Bragg coherent diffractive imaging (BCDI) work, coupled with phase field simulations, has also identified the monoclinic phase and shown how the phase fractions change as the vortex is driven under the influence of an external field .…”

Section: Introductionmentioning

confidence: 96%

Enhanced Piezoelectric Response at Nanoscale Vortex Structures in Ferroelectrics

Shi,

Nazirkar,

Kashikar

et al. 2024

ACS Appl. Mater. Interfaces

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The piezoelectric response is a measure of the sensitivity of a material's polarization to stress or its strain to an applied field. Using in operando X-ray Bragg coherent diffraction imaging, we observe that topological vortices are the source of a 5-fold enhancement of the piezoelectric response near the vortex core. The vortices form where several low-symmetry ferroelectric phases and phase boundaries coalesce. Unlike bulk ferroelectric solid solutions in which a large piezoelectric response is associated with coexisting phases in the proximity of the triple point, the largest responses for pure BaTiO 3 at the nanoscale are in spatial regions of extremely small spontaneous polarization at vortex cores. The response decays inversely with polarization away from the vortex, analogous to the behavior in bulk ceramics as the cation compositions are varied away from the triple point. We use first-principlesbased molecular dynamics to augment our observations, and our results suggest that nanoscale piezoelectric materials with a large piezoelectric response can be designed within a parameter space governed by vortex cores. Our findings have implications for the development of next-generation nanoscale piezoelectric materials.

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“…As mechanical controls of physical properties, Ponomareva and co‐workers demonstrated all‐mechanical controls of ferroelectric nanowires. [ 43 ] Upon application of uniaxial compressive stress onto ferroelectric nanowires such as PbTiO 3 nanowires, their poor surface charge compensation results in reversible phase switching between macroscopically nonpolar flux‐closure phase and polar phase with axial polarization. The observed mechanical effect is hold up to GHz frequency regions.…”

Section: Mechanical Control Of Supramolecular Assemblies and Materialsmentioning

confidence: 99%

Mechano‐Nanoarchitectonics: Design and Function

Ariga

2022

Small Methods

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Mechanical stimuli have rather ambiguous and less‐specific features among various physical stimuli, but most materials exhibit a certain level of responses upon mechanical inputs. Unexplored sciences remain in mechanical responding systems as one of the frontiers of materials science. Nanoarchitectonics approaches for mechanically responding materials are discussed as mechano‐nanoarchitectonics in this review article. Recent approaches on molecular and materials systems with mechanical response capabilities are first exemplified with two viewpoints: i) mechanical control of supramolecular assemblies and materials and ii) mechanical control and evaluation of atom/molecular level structures. In the following sections, special attentions on interfacial environments for mechano‐nanoarchitectonics are emphasized. The section entitled iii) Mechanical Control of Molecular System at Dynamic Interface describes coupling of macroscopic mechanical forces and molecular‐level phenomena. Delicate mechanical forces can be applied to functional molecules embedded at the air–water interface where operation of molecular machines and tuning of molecular receptors upon macroscopic mechanical actions are discussed. Finally, the important role of the interfacial media are further extended to the control of living cells as described in the section entitled iv) Mechanical Control of Biosystems. Pioneering approaches on cell fate regulations at liquid–liquid interfaces are discussed in addition to well‐known mechanobiology.

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All-Mechanical Polarization Control and Anomalous (Electro)Mechanical Responses in Ferroelectric Nanowires

Cited by 9 publications

References 39 publications

Insight into Pyroelectricity and Phase Transitions in Ferroelectrics from Nonequilibrium Approach: The Case of PbTiO₃

Insight into Pyroelectricity and Phase Transitions in Ferroelectrics from Nonequilibrium Approach: The Case of PbTiO₃

Enhanced Piezoelectric Response at Nanoscale Vortex Structures in Ferroelectrics

Mechano‐Nanoarchitectonics: Design and Function

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All-Mechanical Polarization Control and Anomalous (Electro)Mechanical Responses in Ferroelectric Nanowires

Cited by 9 publications

References 39 publications

Insight into Pyroelectricity and Phase Transitions in Ferroelectrics from Nonequilibrium Approach: The Case of PbTiO3

Insight into Pyroelectricity and Phase Transitions in Ferroelectrics from Nonequilibrium Approach: The Case of PbTiO3

Enhanced Piezoelectric Response at Nanoscale Vortex Structures in Ferroelectrics

Mechano‐Nanoarchitectonics: Design and Function

Contact Info

Product

Resources

About

Insight into Pyroelectricity and Phase Transitions in Ferroelectrics from Nonequilibrium Approach: The Case of PbTiO₃

Insight into Pyroelectricity and Phase Transitions in Ferroelectrics from Nonequilibrium Approach: The Case of PbTiO₃