热电效应
材料科学
复合数
自愈水凝胶
电解质
离子键合
水溶液
电压
化学工程
电极
聚合物
电化学
离子电导率
塞贝克系数
导电体
热电发电机
纳米技术
温度梯度
复合材料
光电子学
扩散
离子
导电聚合物
载流子
基质(化学分析)
热电冷却
离子强度
作者
Shoubo Li,Junhui Tang,Ya‐Hsin Pai,Fan Wu,Yu‐Mei Lin,Shengqiang Bai,Ziqi Liang
标识
DOI:10.1007/s42114-025-01495-8
摘要
Thermoelectric hydrogels have drawn increasing research interest owing to their high ionic thermopower (α) values and superior mechanical stretchability. However, they are critically constrained by rapid dehydration and the poor interactions between polymeric frameworks and electrolytes, which fail to differentiate the diffusion rates of cations and anions under a certain temperature gradient (ΔT). This study reports a dual-channel ionic/electronic composite hydrogel implemented by directional freezing a cross-linked network of PEDOT:PSS-coated poly(vinyl alcohol) (PVA) and then immersion into an ionic electrolyte of CuCl2. Introducing 5 vol% conductive polymer PEDOT:PSS aqueous solution into the PVA hydrogel strengthened chemical coordination between the polymer matrix and Cu2+ ions to facilitate mobile Cl‒ ions, resulting in an ultrahigh α of ‒22.8 mV K−1, further elevated to − 33.8 mV K–1 via freezing–thawing cycles. Driven by ΔT, holes accumulate at the cold end of the composite hydrogel, in part neutralizing Cl‒ migration and mitigating open-circuit voltages to an equilibrium value, whereas holes drifting toward electrodes allow charge extraction to the external circuit. Notably, the composite hydrogel2 retained 90% of the peak voltage in a steady state at an optimum 0.5 M CuCl2. Furthermore, introducing CuCl2 doubles the water retention capacity of the hydrogel and simultaneously endows it with excellent re-usability and long-term stability. A hybrid thermoelectric generator delivers a stable output of ‒4.0 mV K−1 with a 100 kΩ external load. Such a device permits generating electricity continuously under not only temperature fluctuations but also a stable ΔT.
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