Self-consistent modelling of electrochemical strain microscopy in mixed ionic-electronic conductors: Nonlinear and dynamic regimes

Varenyk, Oleksandr V.; Silibin, Maxim V.; Киселев, Д. А.; Eliseev, Eugene A.; Kalinin, Sergei V.; Morozovska, Anna N.

doi:10.1063/1.4927815

Cited by 16 publications

(9 citation statements)

References 44 publications

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“…Although Vegard strain arising from ionic motion may also be linear to the applied voltage, recent theoretical analysis suggests that it plays a key role only at low voltage under 1 V, beyond which quadratic electrostriction dominates. 46,47 voltage is much smaller than the voltage we applied, and thus we can safely conclude that the piezoresponse in lung tissue is dominated by linear piezoelectricity, especially when no ionic species are expected to be present in the tissues. In addition, both first and second harmonic responses versus the driven frequency can be fitted nicely by the damped harmonic oscillator model, 48 allowing us to determine the quality factor and the intrinsic piezoresponse amplitude.…”

Section: Resultsmentioning

confidence: 69%

Electromechanical Coupling of Murine Lung Tissues Probed by Piezoresponse Force Microscopy

Jiang

Yan

Esfahani

et al. 2017

ACS Biomater. Sci. Eng.

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Elastin is a major constituent of lung that makes up approximately 30% of lung’s dry weight, and the piezoelectricity of elastin is expected to be exhibited in lung tissues. Because hundreds of millions of cycles of inhalation and exhalation occur in one’s lifetime, such piezoelectric effect leads to hundreds of millions of cycles of charge generations in lung tissues, suggesting possible physiological significance. Using piezoresponse force microscopy (PFM), we show that the murine lung tissues are indeed piezoelectric, exhibiting predominantly first harmonic piezoresponse in both vertical and lateral modes. The second harmonic response, which could arise from ionic motions, electrochemical dipoles, and electrostatic interactions, is found to be small. The mappings of amplitude, phase, resonance frequency, and quality factor of both vertical and lateral PFM are also obtained, showing small fluctuation in frequency, but larger variation in quality factor, and thus energy dissipation. The phase mapping is confined in a small range, indicating a polar distribution with preferred orientation. It is also found that the polarity of the electromechanical coupling in lung tissues can be switched by an external electric field, resulting in characteristic hysteresis and butterfly loops, with a presence of internal bias in the polar structure. It is hypothesized that the piezoelectric charge generation during inhalation and exhalation could play a role in binding of oxygen to hemoglobin, and the polarity switching can help damp out the possible sudden increase in air pressure. We hope such observation of piezoelectricity and its polarity switching in lung lay the foundation for the subsequent studies of its physiological significance.

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Section: Resultsmentioning

confidence: 69%

Electromechanical Coupling of Murine Lung Tissues Probed by Piezoresponse Force Microscopy

Jiang

Yan

Esfahani

et al. 2017

ACS Biomater. Sci. Eng.

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“…Further details can be found in the supplementary information and recent work published by Varenyk et al . 46 .…”

Section: Resultsmentioning

confidence: 99%

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

Seol

Park

Varenyk

et al. 2016

Sci Rep

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Hysteresis loop analysis via piezoresponse force microscopy (PFM) is typically performed to probe the existence of ferroelectricity at the nanoscale. However, such an approach is rather complex in accurately determining the pure contribution of ferroelectricity to the PFM. Here, we suggest a facile method to discriminate the ferroelectric effect from the electromechanical (EM) response through the use of frequency dependent ac amplitude sweep with combination of hysteresis loops in PFM. Our combined study through experimental and theoretical approaches verifies that this method can be used as a new tool to differentiate the ferroelectric effect from the other factors that contribute to the EM response.

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“…9,10 Consequently, to explore the properties of such materials, groups have used a wide range of scanning probe microscopy methods, 11-14 as well as measuring the behavior of a moving ion front via optical methods. 2,8,15 Electrochemical strain microscopy (ESM) in particular has been widely applied to image ion uptake dynamics 16,17 and Prefabricated glass slides coated with a layer of indium tin oxide are sonicated in solutions of acetone and isopropyl alcohol successively. After sonication, the slides are plasma-cleaned for a period of 10 minutes and then immediately transferred to a dry-nitrogen atmosphere glovebox.Within this glovebox, the slides are spin-coated with the pre-prepared solutions containing the requisite solid polymer electrolyte.…”

mentioning

confidence: 99%

“…9,10 Consequently, to explore the properties of such materials, groups have used a wide range of scanning probe microscopy methods 11−14 as well as measuring the behavior of a moving ion front via optical methods. 2,8,15 Electrochemical strain microscopy (ESM) in particular has been widely applied to image ion uptake dynamics, 16,17 and our group reported the use of ESM to probe local swelling behavior upon ion uptake in polymer electrochemical transistors. 18,19 Nevertheless, methods like ESM were originally developed for high-modulus inorganic materials and can be challenging to apply on soft polymer and gel samples.…”

mentioning

confidence: 99%

“…Ion-transport processes in thin film materials affect the performance of a wide variety of technologies ranging from bioelectronics , and electrochemical energy storage to the stability of perovskite photovoltaics. , The ability to characterize ion-transport dynamics in solid-state systems at the nanoscale is important to understanding the processing-structure–function relationships of these materials and has therefore attracted considerable interest. − Many polymer-based systems are, either by design or by consequence of their solution-based deposition kinetics, inherently nanostructured. , Consequently, to explore the properties of such materials, groups have used a wide range of scanning probe microscopy methods − as well as measuring the behavior of a moving ion front via optical methods. ,, Electrochemical strain microscopy (ESM) in particular has been widely applied to image ion uptake dynamics, , and our group reported the use of ESM to probe local swelling behavior upon ion uptake in polymer electrochemical transistors. , …”

mentioning

confidence: 99%

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Noncontact Imaging of Ion Dynamics in Polymer Electrolytes with Time-Resolved Electrostatic Force Microscopy

et al. 2018

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Ionic transport processes govern performance in many classic and emerging devices, ranging from battery storage to modern mixed-conduction electrochemical transistors. Here, we study local ion transport dynamics in polymer films using time-resolved electrostatic force microscopy (trEFM). We establish a correspondence between local and macroscopic measurements using local trEFM and macroscopic electrical impedance spectroscopy (EIS). We use polymer films doped with lithium bis(trifluoromethane)sulfonimide (LiTFSI) as a model system where the polymer backbone has oxanorbornenedicarboximide repeat units with an oligomeric ethylene oxide side chain of length n. Our results show that the local polymer response measured in the time domain with trEFM follows stretched exponential relaxation kinetics, consistent with the Havriliak-Negami relaxation we measure in the frequency-domain EIS data for macroscopic samples of the same polymers. Furthermore, we show that the trEFM results capture the same trends as the EIS resultschanges in ion dynamics with increasing temperature, increasing salt concentration, and increasing volume fraction of ethylene oxide side chains in the polymer matrix evolve with the same trends in both measurement techniques. We conclude from this correlation that trEFM data reflect, at the nanoscale, the same ionic processes probed in conventional EIS at the device level. Finally, as an example application for emerging materials syntheses, we use trEFM and infrared photoinduced force microscopy (PiFM) to image a novel diblock copolymer electrolyte for next-generation solid-state energy storage applications.Ion transport processes in thin film materials affect the performance of a wide variety of technologies ranging from bioelectronics 1,2 and electrochemical energy storage 3 , to the stability of perovskite photovoltaics. 4,5 The ability to characterize ion transport dynamics in solid-state systems at the nanoscale is important to understanding the processing-structure-function relationships of these materials and has therefore attracted considerable interest. 6-8 Many polymer-based systems are, either by design or by consequence of their solution-based deposition kinetics, inherently nanostructured. 9,10 Consequently, to explore the properties of such materials, groups have used a wide range of scanning probe microscopy methods, 11-14 as well as measuring the behavior of a moving ion front via optical methods. 2,8,15 Electrochemical strain microscopy (ESM) in particular has been widely applied to image ion uptake dynamics 16,17 and Prefabricated glass slides coated with a layer of indium tin oxide are sonicated in solutions of acetone and isopropyl alcohol successively. After sonication, the slides are plasma-cleaned for a period of 10 minutes and then immediately transferred to a dry-nitrogen atmosphere glovebox.Within this glovebox, the slides are spin-coated with the pre-prepared solutions containing the requisite solid polymer electrolyte. This process generates films with an average thickness of...

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Self-consistent modelling of electrochemical strain microscopy in mixed ionic-electronic conductors: Nonlinear and dynamic regimes

Cited by 16 publications

References 44 publications

Electromechanical Coupling of Murine Lung Tissues Probed by Piezoresponse Force Microscopy

Electromechanical Coupling of Murine Lung Tissues Probed by Piezoresponse Force Microscopy

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

Noncontact Imaging of Ion Dynamics in Polymer Electrolytes with Time-Resolved Electrostatic Force Microscopy

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