Mixed Ionic–Electronic Conduction in Binary Polymer Nanoparticle Assemblies

Renna, Lawrence A.; Lenef, Julia D.; Bag, Monojit; Venkataraman, D.

doi:10.1002/admi.201700397

Cited by 9 publications

(10 citation statements)

References 54 publications

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“…In the case that any of the electronic or ionic transport is mediated by the presence of a secondary pathway in a MIEC, generally associated to grain boundaries or depleted regions, as we discuss before, a second

(or

) parallel combination connected in series with R e (or R i ), respectively, could be useful to fit the total impedance response, with associated pathway represented by a zig-zag line in Figure 2B (Huggins, 2002 ). In the recent literature, both the inclusion and exclusion of this second

(or

) parallel combination in biphasic polymeric MIECs have been observed, depending mainly on the electronic- and ionic-conducting phase concentration or microstructural differences (Patel et al, 2012 ; Renna et al, 2017 ). In the particular case of hOI -MIECs, the second contribution (and probably a third contribution) to ionic or electronic transport could be present due to the mere existence of the organic–inorganic interphase, as shown in Figure 2C .…”

Section: Charge Carrier Conductionmentioning

confidence: 99%

Mini-Review: Mixed Ionic–Electronic Charge Carrier Localization and Transport in Hybrid Organic–Inorganic Nanomaterials

et al. 2020

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In this mini-review, a comprehensive discussion on the state of the art of hybrid organic-inorganic mixed ionic-electronic conductors (hOI-MIECs) is given, focusing on conducting polymer nanocomposites comprising inorganic nanoparticles ranging from ceramic-in-polymer to polymer-in-ceramic concentration regimes. First, a brief discussion on fundamental aspects of mixed ionic-electronic transport phenomena considering the charge carrier transport at bulk regions together with the effect of the organic-inorganic interphase of hybrid nanocomposites is presented. We also make a recount of updated instrumentation techniques to characterize structure, microstructure, chemical composition, and mixed ionic-electronic transport with special focus on those relevant for hOI-MIECs. Raman imaging and impedance spectroscopy instrumentation techniques are particularly discussed as relatively simple and versatile tools to study the charge carrier localization and transport at different regions of hOI-MIECs including both bulk and interphase regions to shed some light on the mixed ionic-electronic transport mechanism. In addition, we will also refer to different device assembly configurations and in situ/operando measurements experiments to analyze mixed ionic-electronic conduction phenomena for different specific applications. Finally, we will also review the broad range of promising applications of hOI-MIECs, mainly in the field of energy storage and conversion, but also in the emerging field of electronics and bioelectronics.

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Section: Charge Carrier Conductionmentioning

confidence: 99%

Mini-Review: Mixed Ionic–Electronic Charge Carrier Localization and Transport in Hybrid Organic–Inorganic Nanomaterials

et al. 2020

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“…Impedance spectroscopy was conducted to further study the electrical conductivity of the films with the aim to isolate ionic from electronic conductivity. The use of gold to make electrical contacts allowed the separation of ions from electrons with the change in applied frequency. , Figure a shows the Nyquist plot obtained for P(BzMA- stat - n BA)/GO/LS (5 wt %) (Nyquist plots for other films are presented in Figure S7, Supporting Information). The negative imaginary y -axis ( Z ″) observed at high frequencies in the Nyquist plot can be ascribed to the magnetization of wires inside the cables (connecting the films to the potentiostat).…”

Section: Resultsmentioning

confidence: 99%

“…These studies highlight the complexity of mixed ionic–electronic conductivity in composites and the importance of carefully considering the intrinsic properties of the components when designing a hybrid composite. It is to be noted that isolating ionic from electronic conductivity in hybrid composites is not trivial and requires the combination of complex electrochemical techniques, typically involving the use of blocking electrodes (stainless steel and gold as ion blockers and Nafion as an electron blocker) during impedance measurements. ,− …”

Section: Introductionmentioning

confidence: 99%

Ionic–Electronic Conductivity in Ternary Polymer/Reduced Graphene Oxide/Polyelectrolyte Nanocomposite Coatings for Potential Application in Energy Storage

Saborío

Maslekar

Yao

et al. 2023

ACS Appl. Nano Mater.

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Polymeric mixed ionic–electronic conductors are desired for a range of applications. The growing interest in the shift from liquid to solid polymer electrolytes further fueled research interest in this domain. However, the predominant research in the field has been limited to binary systems where components are selected for their electronic and ionic conduction. Here, in a systematic study, we have developed ternary nanocomposites comprising an insulating polymer poly(benzyl methacrylate-stat-n-butyl acrylate) used as a binder, reduced graphene oxide as an electronic conductor nanofiller, and different concentrations of polyelectrolytes lignosulfonate (LS) and polystyrene sulfonate as ionic conductors. The developed ternary nanocomposite can be simply coated to obtain a uniform film at ambient temperature, exhibiting mixed ionic–electronic conduction. Scanning electron microscopy–energy-dispersive spectroscopy mapping revealed the distribution of polyelectrolytes throughout the film surface. The nanocomposite coatings exhibited the highest ionic conductivity of ∼54 S m–1 (30 wt % LS relative to monomer) and electronic conductivity of ∼40 S m–1 (7 wt % LS relative to monomer). The obtained ionic–electronic conductivity values were some of the highest reported in the literature (compared against binary systems), despite comprising an insulating binder as a majority component. The present work provides the important fundamental understanding behind the design and fabrication of ternary polymeric mixed ionic–electronic conductive coatings and paves the way for further research in the field. The developed nanocomposite coatings are anticipated to find application in a range of fields including energy storage, biomedical engineering, and sensors.

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“…More recently, the field of organic electronics which utilizes π-conjugated small molecules and polymers as electronic conductors has experienced tremendous growth. Compared to traditional silicon-based electronics, organic electronics offer advantages of low cost processability, mechanical flexibility, biocompatibility, and nearly limitless capacity to tailor the physical properties via facile chemical design. − Together with the expansion of the organic electronics field, there have been growing interests in developing organic materials such as polymeric − or liquid crystal (LC) systems , with mixed electronic/ionic conducting properties that couple the electronic conduction of the π-conjugated moieties with other ionic conduction moieties.…”

mentioning

confidence: 99%

“…Given their enormous potential, understanding the structure–processing–transport relationships in organic mixed conductors are of keen scientific and technological interests. Until now, only a few structure–mixed conduction studies have been performed on organic mixed conductors, and most of them only focus on polymeric systems. − Understanding fundamental mixed conduction in conjugated polymers, however, is not straightforward due to the complex semicrystalline structures that make both structure characterization and simulation challenging . Compared to polymeric systems, LCs hold advantages of simple assembly and structural reorganization because of their intrinsic fluidity.…”

mentioning

confidence: 99%

Structure Control of a π-Conjugated Oligothiophene-Based Liquid Crystal for Enhanced Mixed Ion/Electron Transport Characteristics

et al. 2019

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Developing soft materials with both ion and electron transport functionalities is of broad interest for energy-storage and bioelectronics applications. Rational design of these materials requires a fundamental understanding of interactions between ion and electron conducting blocks along with the correlation between the microstructure and the conduction characteristics. Here, we investigate the structure and mixed ionic/electronic conduction in thin films of a liquid crystal (LC) 4T/PEO4, which consists of an electronically conducting quarterthiophene (4T) block terminated at both ends by ionically conducting oligoethylenoxide (PEO4) blocks. Using a combined experimental and simulation approach, 4T/PEO4 is shown to self-assemble into smectic, ordered, or disordered phases upon blending the materials with the ionic dopant bis(trifluoromethane)sulfonimide lithium (LiTFSI) under different LiTFSI concentrations. Interestingly, at intermediate LiTFSI concentration, ordered 4T/PEO4 exhibits an electronic conductivity as high as 3.1 × 10–3 S/cm upon being infiltrated with vapor of the 2,3,5,6-tetrafluoro-7,7,8,8-tetracyanoquinodimethane (F4TCNQ) molecular dopant while still maintaining its ionic conducting functionality. This electronic conductivity is superior by an order of magnitude to the previously reported electronic conductivity of vapor co-deposited 4T/F4TCNQ blends. Our findings demonstrate that structure and electronic transport in mixed conduction materials could be modulated by the presence of the ion transporting component and will have important implications for other more complex mixed ionic/electronic conductors.

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Mixed Ionic–Electronic Conduction in Binary Polymer Nanoparticle Assemblies

Cited by 9 publications

References 54 publications

Mini-Review: Mixed Ionic–Electronic Charge Carrier Localization and Transport in Hybrid Organic–Inorganic Nanomaterials

Mini-Review: Mixed Ionic–Electronic Charge Carrier Localization and Transport in Hybrid Organic–Inorganic Nanomaterials

Ionic–Electronic Conductivity in Ternary Polymer/Reduced Graphene Oxide/Polyelectrolyte Nanocomposite Coatings for Potential Application in Energy Storage

Structure Control of a π-Conjugated Oligothiophene-Based Liquid Crystal for Enhanced Mixed Ion/Electron Transport Characteristics

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