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W4306739308 endingPage "101656" @default.
W4306739308 startingPage "101656" @default.
W4306739308 abstract "• Among stimuli–responsive polymer gel materials, electrosensitive ones have recently attracted increasing research interest. • Volumetric phase transition phenomena of polymer gels controlled by an applied potential holds great promise for future utility. • Electrosensor gels show great promise in construction of electrochemical actuators, micropumps, microvalves, artificial muscles, soft robots, and advanced drug delivery systems. Among stimuli–responsive polymer gel materials, those that are electrosensitive have recently attracted burgeoning research interest. In particular, electrosensitive hydrogels characterized by rapid and reversible volume and/or shape transition resulting from redox state changes are in increasing demand. This feature makes hydrogel materials much more attractive and has opened up new possibilities for their applications, e.g. in the construction of electrochemical actuators, micropumps, microvalves, artificial muscles, soft robots, and advanced drug delivery systems. In this review paper, we focus on one group of electroresponsive gels – those that undergo a volume phase transition or shape change in response to a change in oxidation state of the gel component. The number of articles on such materials is rather small, and in our view the field remains largely underexplored. Herein we review the mechanisms that have been shown to underlie this kind of electrosensitivity and present particular examples of macrogels, microgels, and thin gel layers anchored to conducting surfaces. Smart electroactive polymer gels that change volume and/or shape in response to a change in their oxidation state." @default.
W4306739308 created "2022-10-19" @default.
W4306739308 creator A5001282220 @default.
W4306739308 creator A5029210940 @default.
W4306739308 creator A5075471392 @default.
W4306739308 date "2022-12-01" @default.
W4306739308 modified "2023-10-17" @default.
W4306739308 title "Electrosensitive polymer gels: Controlling size and shape by means of red–ox processes – outlook and prospects" @default.
W4306739308 cites W1019363471 @default.
W4306739308 cites W1808512592 @default.
W4306739308 cites W1965701005 @default.
W4306739308 cites W1966847510 @default.
W4306739308 cites W1970217459 @default.
W4306739308 cites W1975014311 @default.
W4306739308 cites W1977350191 @default.
W4306739308 cites W1979058654 @default.
W4306739308 cites W1993632469 @default.
W4306739308 cites W1996688535 @default.
W4306739308 cites W1999105357 @default.
W4306739308 cites W2002734621 @default.
W4306739308 cites W2003034707 @default.
W4306739308 cites W2010772477 @default.
W4306739308 cites W2016085760 @default.
W4306739308 cites W2024306244 @default.
W4306739308 cites W2039754105 @default.
W4306739308 cites W2040694465 @default.
W4306739308 cites W2044512869 @default.
W4306739308 cites W2046888854 @default.
W4306739308 cites W2057082593 @default.
W4306739308 cites W2059710034 @default.
W4306739308 cites W2060239018 @default.
W4306739308 cites W2061038677 @default.
W4306739308 cites W2066492569 @default.
W4306739308 cites W2067488799 @default.
W4306739308 cites W2083051655 @default.
W4306739308 cites W2086186760 @default.
W4306739308 cites W2087343925 @default.
W4306739308 cites W2095765074 @default.
W4306739308 cites W2105581475 @default.
W4306739308 cites W2118945332 @default.
W4306739308 cites W2127955898 @default.
W4306739308 cites W2147988143 @default.
W4306739308 cites W2152247793 @default.
W4306739308 cites W2158006396 @default.
W4306739308 cites W2272006673 @default.
W4306739308 cites W2292750388 @default.
W4306739308 cites W2319021889 @default.
W4306739308 cites W2346828498 @default.
W4306739308 cites W2410933689 @default.
W4306739308 cites W2419201800 @default.
W4306739308 cites W2464852436 @default.
W4306739308 cites W2516369543 @default.
W4306739308 cites W2524016649 @default.
W4306739308 cites W2586082943 @default.
W4306739308 cites W2606251873 @default.
W4306739308 cites W2610568238 @default.
W4306739308 cites W2610715043 @default.
W4306739308 cites W2729247004 @default.
W4306739308 cites W2738623976 @default.
W4306739308 cites W2766307563 @default.
W4306739308 cites W2766885272 @default.
W4306739308 cites W2779184860 @default.
W4306739308 cites W2790354575 @default.
W4306739308 cites W2792187054 @default.
W4306739308 cites W2792966670 @default.
W4306739308 cites W2801042303 @default.
W4306739308 cites W2805176360 @default.
W4306739308 cites W2809550922 @default.
W4306739308 cites W2890915572 @default.
W4306739308 cites W2891692871 @default.
W4306739308 cites W2893869294 @default.
W4306739308 cites W2900565410 @default.
W4306739308 cites W2905321357 @default.
W4306739308 cites W2910965320 @default.
W4306739308 cites W2913594143 @default.
W4306739308 cites W2919188205 @default.
W4306739308 cites W2923335535 @default.
W4306739308 cites W2940549514 @default.
W4306739308 cites W2942438142 @default.
W4306739308 cites W2954107212 @default.
W4306739308 cites W2970928518 @default.
W4306739308 cites W2980768807 @default.
W4306739308 cites W2980826317 @default.
W4306739308 cites W2993673397 @default.
W4306739308 cites W2999261029 @default.
W4306739308 cites W3127923289 @default.
W4306739308 cites W3134873623 @default.
W4306739308 cites W3160218027 @default.
W4306739308 cites W3170319353 @default.
W4306739308 cites W3175098295 @default.
W4306739308 cites W3177146872 @default.
W4306739308 cites W3196062165 @default.
W4306739308 cites W3196480462 @default.
W4306739308 cites W4234274627 @default.
W4306739308 cites W2160950893 @default.
W4306739308 doi "https://doi.org/10.1016/j.apmt.2022.101656" @default.
W4306739308 hasPublicationYear "2022" @default.
W4306739308 type Work @default.