Strong and Stretchable Polypyrrole Hydrogels with Biphase Microstructure as Electrodes for Substrate‐Free Stretchable Supercapacitors

Chen, Fang; Chen, Qing; Song, Qun; Han, Lu; Ma, Mingming

doi:10.1002/admi.201900133

Cited by 50 publications

(41 citation statements)

References 50 publications

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“…In an attempt to improve the stretchability, elastic polymer chains such as polyvinyl alcohol (PVA), [19][20][21] polyacrylamide (PAAm), 22,23 poly(ethylene glycol)diacrylate, 4 and chitosan 24 have been incorporated into rigid conducting polymers in past works. However, these strategies usually suffer from unfavorable electrical and mechanical properties.…”

Section: Progress and Potentialmentioning

confidence: 99%

Hierarchically Structured Stretchable Conductive Hydrogels for High-Performance Wearable Strain Sensors and Supercapacitors

Zhao

Zhang

Yao

et al. 2020

Matter

124

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A strategy of creating stretchable conducting hydrogels for emerging soft electronics is reported. With ice-templated low-temperature polymerization (ITLP), the conducting gel exhibited a hierarchical dendritic microstructure with mitigated nanoaggregation and significantly enhanced electrical conductivity and toughness. Using such gels, strain sensors presented a broad sensing range and high sensitivity for health monitoring. Stretchable solid-state supercapacitors demonstrated remarkable capacitance and flexibility as wearable energy-storage devices. Such a general ITLP method may create diverse soft-electronic materials for energy, healthcare, and robotic applications.

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Section: Progress and Potentialmentioning

confidence: 99%

Hierarchically Structured Stretchable Conductive Hydrogels for High-Performance Wearable Strain Sensors and Supercapacitors

Zhao

Zhang

Yao

et al. 2020

Matter

124

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“…The cyclic voltammetry (CV) curves of devices made from PPy/APA matrices with different pore sizes (APA‐ x PVA, x = 0, 0.5, 3 wt% PVA) and nonaligned, homogenous matrix (HomoPA), respectively, were measured at 10 mV s −1 . As shown in Figure b, all four CV curves demonstrated a nearly rectangular shape, indicating a fast and efficient ion transfer . The enclosed CV area for the APA devices increased with decreasing pore size, an indication of higher loading of electrode materials.…”

Section: Resultsmentioning

confidence: 82%

“…Based on the 2 mm APA/PPy electrode with 3 wt% PVA and 28% FeCl 3 /ethanol solution, the resultant areal capacitance was boosted to 1838 mF cm −2 at 6.2 mA cm −2 , shown in Figure S10 in the Supporting Information. To the best of our knowledge, this capacitance is among the highest of hydrogel‐based solid‐state supercapacitors . Therefore, this presents a promising strategy that the morphological designs of anisotropic matrices and electrode materials coating can possibly advance energy storage devices and technologies.…”

Section: Resultsmentioning

confidence: 98%

“…b) GCD curves at various current densities from 6.2 to 15.5 mA cm −2 . c) Ragone plots comparing this supercapacitor with other representative flexible all‐solid‐state supercapacitors, including PPy/PVA, sodium dodecyl sulfate‐modified PPy/PVA, all‐in‐one PANi/PVA, all‐in‐one PPy/PVA, PPy/GO (graphene oxide), graphite/PANi, carbon nanotube/GO/PPy, graphene/PANi, and PANi/stainless steel wire . d) Capacitance retention during 1000 charging–discharging cycles at current density of 6.2 mA cm −2 .…”

Section: Resultsmentioning

confidence: 99%

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Wood‐Inspired Morphologically Tunable Aligned Hydrogel for High‐Performance Flexible All‐Solid‐State Supercapacitors

Zhao

Alsaid

Yao

et al. 2020

Adv Funct Materials

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Oriented microstructures are widely found in various biological systems for multiple functions. Such anisotropic structures provide low tortuosity and sufficient surface area, desirable for the design of high‐performance energy storage devices. Despite significant efforts to develop supercapacitors with aligned morphology, challenges remain due to the predefined pore sizes, limited mechanical flexibility, and low mass loading. Herein, a wood‐inspired flexible all‐solid‐state hydrogel supercapacitor is demonstrated by morphologically tuning the aligned hydrogel matrix toward high electrode‐materials loading and high areal capacitance. The highly aligned matrix exhibits broad morphological tunability (47–12 µm), mechanical flexibility (0°–180° bending), and uniform polypyrrole loading up to 7 mm thick matrix. After being assembled into a solid‐state supercapacitor, the areal capacitance reaches 831 mF cm−2 for the 12 µm matrix, which is 259% times of the 47 µm matrix and 403% times of nonaligned matrix. The supercapacitor also exhibits a high energy density of 73.8 µWh cm−2, power density of 4960 µW cm−2, capacitance retention of 86.5% after 1000 cycles, and bending stability of 95% after 5000 cycles. The principle to structurally design the oriented matrices for high electrode material loading opens up the possibility for advanced energy storage applications.

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“…Electroconductive hydrogels (EHs) obtained by introducing conductive components into conventional hydrogels have been widely reported and studied since they were firstly reported in 1994 (Gilmore, Hodgson, Luan, Small, & Wallace, ). Conductive polymers such as polypyrrole (F. Chen, Chen, Song, Lu, & Ma, ; Hur et al, ; L. Li et al, ), polyaniline (W. Li, Gao, Wang, Zhang, & Ma, ; Pan et al, ), polythiophene and derivatives (Q. Chen et al, ; Q. Chen, Wang, Chen, Zhang, & Ma, ; Ghosh, Rasmusson, & Inganäs, ; Yao et al, ) and conductive carbon materials such as carbon nanotubes (CNTs; Z. Chen et al, ), graphene (Xu, Sheng, Li, & Shi, ) are commonly used for synthesizing EHs (F. Zhao, Bae, Zhou, Guo, & Yu, ; F. Zhao, Shi, Pan, & Yu, ). The π–π‐conjugated structure of conductive components provide the hydrogels with good electrical conductivity (Zhang et al, ).…”

Section: Introductionmentioning

confidence: 99%

Electroconductive hydrogels for biomedical applications

Han

Zhang

2019

WIREs Nanomed Nanobiotechnol

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Electroconductive hydrogels (EHs), combining both the biomimetic features of hydrogels and the electrochemical properties of conductive polymers and carbon‐based materials, have received immense considerations over the past decade. The three‐dimensional porous structure, hydrophilic properties, and regulatable chemical and physical properties of EH resemble the extracellular matrix in tissues, enable EHs a good matrix for cell growth, proliferation, and migration. Different from nonconductive hydrogels, EHs possess high electrical conductivity and electrochemical redox properties, which can be utilized to detect electric signals generated in biological systems, and also to supply electrical stimulation to regulate the activity and function of cells and tissues. Hence, this article provides a summary of the new development of EH for biomedical applications in the decade. We give a brief introduction of the design and synthesis of EHs, as well as current applications of EHs in biomedical fields, including cell culture, tissue engineering, drug delivery and controlled release, biosensors, and implantable bioelectronics. The development trends and challenges of EHs for biomedical applications are also discussed. This article is categorized under: Implantable Materials and Surgical Technologies > Nanomaterials and Implants Diagnostic Tools > Biosensing Therapeutic Approaches and Drug Discovery > Emerging Technologies

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Strong and Stretchable Polypyrrole Hydrogels with Biphase Microstructure as Electrodes for Substrate‐Free Stretchable Supercapacitors

Cited by 50 publications

References 50 publications

Hierarchically Structured Stretchable Conductive Hydrogels for High-Performance Wearable Strain Sensors and Supercapacitors

Hierarchically Structured Stretchable Conductive Hydrogels for High-Performance Wearable Strain Sensors and Supercapacitors

Wood‐Inspired Morphologically Tunable Aligned Hydrogel for High‐Performance Flexible All‐Solid‐State Supercapacitors

Electroconductive hydrogels for biomedical applications

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