Determination of ferroelectric contributions to electromechanical response by frequency dependent piezoresponse force microscopy

Seol, Daehee; Park, Seongjae; Varenyk, O.V.; Lee, Shinbuhm; Lee, Ho Nyung; Morozovska, Anna N.; Kim, Yunseok

doi:10.1038/srep30579

Cited by 40 publications

(42 citation statements)

References 49 publications

(69 reference statements)

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“…Reprinted from Strelcov et al 334 with the permission of AIP Publishing. Another method to determine whether a material is piezoelectric is to determine the frequency dispersion, as shown by Seol et al 336 Reproduced from Seol et al 336 . A similar example is indicated by Chen et al 118 (e-h) Comparison of soda-lime glass (e,f) and PZT sample (g,h) hysteresis loops as a function of voltage window and frequency of the applied DC switching waveform.…”

Section: Resultsmentioning

confidence: 99%

“…This technique is shown in Figure 10 (a,b). 335 Alternatively, one can also explore the frequency dependence of the signal, a technique explored recently by Kim et al 336 Here, the authors exploit the fact that across a frequency range of a few hundred kHz, the (intrinsic) piezoelectric properties of ferroelectrics are not heavily dependent on the probing frequency, whereas they are likely heavily frequency dependent for ionic redistribution. The surface displacement induced by ionic motion can be modeled as process is contributing to the observed electromechanical response.…”

Section: Via Means To Distinguish Piezoelectric From Non-piezoelectmentioning

confidence: 99%

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Ferroelectric or non-ferroelectric: Why so many materials exhibit “ferroelectricity” on the nanoscale

Vasudevan

Balke

Maksymovych

et al. 2017

Applied Physics Reviews

262

206

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Ferroelectric materials have remained one of the foci of condensed matter physics and materials science for over 50 years. In the last 20 years, the development of voltage-modulated scanning probe microscopy techniques, exemplified by Piezoresponse force microscopy (PFM) and associated time-and voltage spectroscopies, opened a pathway to explore these materials on a single-digit nanometer level. Consequently, domain structures, walls and polarization dynamics can now be imaged in real space. More generally, PFM has allowed studying electromechanical coupling in a broad variety of materials ranging from ionics to biological systems. It can also be anticipated that the recent Nobel prize 1 in molecular electromechanical machines will result in rapid growth in interest in PFM as a method to probe their behavior on single device and device assembly levels. However, the broad introduction of PFM also resulted in a growing number of reports on nearly-ubiquitous presence of ferroelectric-like phenomena including remnant polar states and electromechanical hysteresis loops in materials which are non-ferroelectric in the bulk, or in cases where size effects are expected to suppress ferroelectricity. While in certain cases plausible physical mechanisms can be suggested, there is remarkable similarity in observed behaviors, irrespective of the materials system. In this review, we summarize the basic principles of PFM, briefly discuss the features of ferroelectric surfaces salient to PFM imaging and spectroscopy, and summarize existing reports on ferroelectric-like responses in non-classical ferroelectric materials. We further discuss possible mechanisms behind observed behaviors, and possible experimental strategies for their identification.3

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Section: Resultsmentioning

confidence: 99%

Section: Via Means To Distinguish Piezoelectric From Non-piezoelectmentioning

confidence: 99%

Ferroelectric or non-ferroelectric: Why so many materials exhibit “ferroelectricity” on the nanoscale

Vasudevan

Balke

Maksymovych

et al. 2017

Applied Physics Reviews

262

206

View full text Add to dashboard Cite

show abstract

“…For instance, Seol et al reported that it is two orders of magnitudes smaller than the electrochemical strain. [112] However, flexoelectricity is still poorly understood and, furthermore, its contribution cannot be clearly discriminated from the ionically induced chemical effect, e.g., the electrochemical strain. [114] Further investigation will be necessary to clarify the contribution of the flexoelectricity to the observed PFM response explicitly.…”

Section: Electrochemical Strainmentioning

confidence: 99%

“…In order to differentiate a ferroelectric contribution from the EM response, several approaches have been suggested, based on observed variations in the EM response due to experimental conditions. [96,97,112] We here introduce several approaches that can be readily implemented using PFM. frequency-dependent amplitude sweep was employed, as schematically depicted in Fig.…”

Section: Differentiation Of the Ferroelectric Contribution From The Ementioning

confidence: 99%

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Non-piezoelectric effects in piezoresponse force microscopy

Seol¹,

Kim²,

Kim³

2017

Current Applied Physics

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130

114

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Piezoresponse force microscopy (PFM) has been used extensively for exploring nanoscale ferro/piezoelectric phenomena over the past two decades. The imaging mechanism of PFM is based on the detection of the electromechanical (EM) response induced by the inverse piezoelectric effect through the cantilever dynamics of an atomic force microscopy. However, several non-piezoelectric effects can induce additional contributions to the EM response, which often lead to a misinterpretation of the measured PFM response. This review aims to summarize the non-piezoelectric origins of the EM response that impair the interpretation of PFM measurements. We primarily discuss two major non-piezoelectric origins, namely, the electrostatic effect and electrochemical strain. Several approaches for differentiating the ferroelectric contribution from the EM response are also discussed. The review suggests a fundamental guideline for the proper utilization of the PFM technique, as well as for achieving a reasonable interpretation of observed PFM responses.

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Origin of Hysteresis in CH₃NH₃PbI₃ Perovskite Thin Films

Seol

Jeong

Han

et al. 2017

Adv Funct Materials

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Organic-inorganic hybrid perovskite solar cells are attracting the attention of researchers owing to the high level of performance they exhibit in photo voltaic device applications. However, the attainment of an even higher level of performance is hindered by their anomalous current-voltage (I-V) hysteresis behavior. Even though experimental and theoretical studies have suggested that the perovskite materials may have a ferroelectric nature, it is still far from being fully understood. In this study, the origin of the hysteresis behavior in CH 3 NH 3 PbI 3 perovskite thin films is investigated. The behavior of ferro electricity using piezoresponse force microscopy is first examined. Then, by comparing the scanratedependent nano/macroscopic I-V curves, it is found that ion migration assisted by the grain boundaries is a dominant origin of I-V hysteresis from a macroscopic viewpoint. Consequently, the observa tions suggest that, even though ferroelectricity exists in the CH 3 NH 3 PbI 3 perovskite materials, ion migration primarily contributes to the macroscopic I-V hysteresis. The presented results can provide fundamental guidelines to the resolution of hysteresis issues in organic-inorganic hybrid perovskite materials.

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Determination of ferroelectric contributions to electromechanical response by frequency dependent piezoresponse force microscopy

Cited by 40 publications

References 49 publications

Ferroelectric or non-ferroelectric: Why so many materials exhibit “ferroelectricity” on the nanoscale

Ferroelectric or non-ferroelectric: Why so many materials exhibit “ferroelectricity” on the nanoscale

Non-piezoelectric effects in piezoresponse force microscopy

Origin of Hysteresis in CH₃NH₃PbI₃ Perovskite Thin Films

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Determination of ferroelectric contributions to electromechanical response by frequency dependent piezoresponse force microscopy

Cited by 40 publications

References 49 publications

Ferroelectric or non-ferroelectric: Why so many materials exhibit “ferroelectricity” on the nanoscale

Ferroelectric or non-ferroelectric: Why so many materials exhibit “ferroelectricity” on the nanoscale

Non-piezoelectric effects in piezoresponse force microscopy

Origin of Hysteresis in CH3NH3PbI3 Perovskite Thin Films

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Product

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Origin of Hysteresis in CH₃NH₃PbI₃ Perovskite Thin Films