Mechanically stiff and high-areal-performance integrated all-in-wood supercapacitors with electroactive biomass-based hydrogel

超级电容器 材料科学 复合材料 聚吡咯 多孔性 分层(地质) 电容 抗压强度 电化学 电极 聚合 聚合物 化学 生物 物理化学 古生物学 构造学 俯冲
作者
Zhicheng Zhang,Chuying Yu,Zhiyuan Peng,Wenbin Zhong
出处
期刊:Cellulose [Springer Science+Business Media]
卷期号:28 (1): 389-404 被引量:32
标识
DOI:10.1007/s10570-020-03509-8
摘要

The integrated supercapacitors can remarkably reduce the interface contact resistance and avoid the delamination of multi-layer structure, while the mechanically stiff supercapacitors show a wide application prospect in the energy devices. Wood has unique hierarchical porous structure and high mechanical strength with the advantages of abundance and renewability. Here, a novel integrated and mechanically stiff all-in-wood supercapacitor is constructed with lignosulfonate/polypyrrole (Lig/PPy) hydrogel embedded in wood by in-situ polymerization of pyrrole in both sides of wood piece in the Lig/Py solution. Benefiting from strong interaction between Lig and wood, and high pseudo-capacitance of Lig, as well as the hierarchical porous structure of wood with vertical channels, as-prepared integrated Lig/PPy-Wood based supercapacitor (LPWS74−4h) displays a high areal capacitance of 1062 mF cm−2, high energy density of 47.2 µWh cm−2 and favorable cyclic performance. Meanwhile, the LPWS74−4h also shows impressive mechanical stiffness with a maximum compressive strength of 71 MPa. Particularly, LPWS74−4h can maintain good electrochemical performance even if it is crushed into cake shape under high pressure (over 71 MPa). It is expected that such integrated and mechanically stiff all-in-wood supercapacitors with superior electrochemical performance to be a promising candidate for the next generation green and structural energy devices. The integrated all-in-wood supercapacitors perfectly combine the conductive porous structure of Lig/PPy hydrogel with superior electrochemical performance and the unique hierarchical porous structure of wood with vertical channels. Impressive mechanical stiffness and superior electrochemical performance have been achieved.
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