Synergistic Design of Flexible Nanopapers for High-Performance Proton Pseudocapacitors
Jiayue Dong, Zhaoqing Lu, Li Hua, Zizhan Guo, Xiaoxu Xu, Jinlong Wu, Fengfeng Jia, Yuanming Wang

TL;DR
Researchers designed flexible nanopapers using graphene and MXene to create high-performance proton pseudocapacitors with excellent energy and power densities.
Contribution
A synergistic design of modified MXene and graphene with gas-induced expansion and precise surface chemical regulation is introduced for proton pseudocapacitors.
Findings
Modified graphene with a –COOH:–OH ratio of 1:1 achieved a pseudocapacitance of 430.5 F g−1.
Hydrazine-assisted MXene modification increased capacitance to 500.5 F g−1 under high mass loading.
The assembled proton pseudocapacitor delivered energy and power densities of 58.9 Wh kg−1 and 3802 W kg−1.
Abstract
By utilizing water vaporization to increase the surface area of graphene and precisely controlling the ratio of oxygen-containing functional groups, the optimal –COOH:–OH ratio of 1:1 was successfully achieved, resulting in a maximum pseudocapacitance of 430.5 F g−1.Through hydrazine-assisted hydrothermal reaction, –F groups on the MXene surface were substituted with –NH2, while gas generation facilitated the creation of a porous structure, boosting the capacitance to 500.5 F g−1 under high mass loading conditions. By utilizing water vaporization to increase the surface area of graphene and precisely controlling the ratio of oxygen-containing functional groups, the optimal –COOH:–OH ratio of 1:1 was successfully achieved, resulting in a maximum pseudocapacitance of 430.5 F g−1. Through hydrazine-assisted hydrothermal reaction, –F groups on the MXene surface were substituted with –NH2,…
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Taxonomy
TopicsSupercapacitor Materials and Fabrication · MXene and MAX Phase Materials · Advanced battery technologies research
