2017
DOI: 10.1002/adma.201702926
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3D Porous Hydrogel/Conducting Polymer Heterogeneous Membranes with Electro‐/pH‐Modulated Ionic Rectification

Abstract: Heterogeneous membranes composed of asymmetric structures or compositions have enormous potential in sensors, molecular sieves, and energy devices due to their unique ion transport properties such as ionic current rectification and ion selectivity. So far, heterogeneous membranes with 1D nanopores have been extensively studied. However, asymmetric structures with 3D micro-/nanoscale pore networks have never been investigated. Here, a simple and versatile approach to low-costly fabricate hydrogel/conducting pol… Show more

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Cited by 88 publications
(85 citation statements)
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“…When the applied electric field is reversed, it can lead to an accumulation of ions in the pores and results in higher ionic conductivity. This nonlinear ionic conductivity response eventually leads to the ionic rectification performance of ionic diodes (Figure c) …”
Section: Promote Energy Efficiency By Asymmetrymentioning
confidence: 99%
“…When the applied electric field is reversed, it can lead to an accumulation of ions in the pores and results in higher ionic conductivity. This nonlinear ionic conductivity response eventually leads to the ionic rectification performance of ionic diodes (Figure c) …”
Section: Promote Energy Efficiency By Asymmetrymentioning
confidence: 99%
“…Co‐loading of nanoparticles with molecules of different charge, VEGF (negative charge), and SDF‐1 (positive charge) can improve the controllable and selective release of the whole delivery system. The development of environmental‐responsive hydrogels with response to temperature, pH, enzymes, and so forth allows for better targeting of tissue engineering scaffolds (Bao et al, ; Tang et al, ; Zhong et al, ). In particular, injectable hydrogel scaffolds may avoid surgical trauma and infection as much as possible, to further reduce the risk of surgery, and simultaneously improve in situ the precision of the gel at the focus of the lesion (Rose & Laura, ).…”
Section: Introductionmentioning
confidence: 99%
“…This synthetic strategy of preparing mechanical strong conductive hydrogels would be a useful approach for other systems. Otherwise, electrochemical polymerization also can be used to grow conducting polymers in a prefabricated hydrogel …”
Section: Fabrication Of Conductive Hydrogelsmentioning
confidence: 99%
“…Until now,v arious strategies have been developed to fabricate conductive hydrogel for flexible electronic devices,i ncluding co-networks,b lends and self-assembly. [50][51][52][53][54][55][56][57][58] These strategies provide ab road perspective on designing and fabricating nanocomposite conductive hydrogels. We further divide theses trategies into several approaches:( i) electro or chemicalp olymerization of ac onducting monomer in ap refabricatedh ydrogel, (ii)mixing the conductive materials/monomers and hydrophilicp olymers/monomers followed by simultaneous or step-wise cross-linking to produce conductive hydrogels, and (iii)self-assembling the modified electrical conductive materials.…”
Section: Fabricationo Fc Onductive Hydrogelsmentioning
confidence: 99%
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