电解质
材料科学
电化学
反离子
聚苯胺
导电聚合物
离子
兴奋剂
导电体
快离子导体
离子运输机
半导体
聚合物
无机化学
氧化还原
纳米技术
电导率
异质结
欧姆接触
载流子
热传导
光电子学
有机半导体
电化学电池
化学工程
电活性聚合物
导线
作者
Zhiwei Li,Yinghong Xu,Wanheng Lu,Xinglong Pan,Langyuan Wu,Wei Li Ong,Natanel Shpigel,Gang Chen,G. W. P. Ho
标识
DOI:10.1073/pnas.2532302123
摘要
Doping to control carrier (electron or hole) transport is foundational to modulate the properties of semiconductors, enabling the development of homojunctions and heterojunctions for integrated electronics. Unlike semiconductors with unipolar charge-carrier dominance, both cations and anions in electrolytes are mobile, which is undesirable for many applications. Here, we report a universal strategy to dope electrolytes such that the ion transport can be unipolar by incorporating electroactive polymers within hydrogels that interact discriminately with one type of ion via redox and binding mechanisms, leaving the counterions mobile. This transforms the system into an active, selective conductor that directs ion flow with high precision. We demonstrate the generality of this strategy using a wide range of electroactive polymers and ions. Particularly, we use emeraldine base and leucoemeraldine base, derived from polyaniline to create both n-type and p-type conductors with high ion selectivity. This electrolyte doping strategy has significant implications beyond the developed thermoelectrochemical devices with boosted performance, with potential applications in supercapacitors, batteries, and electrochemical sensors.
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