Nickel sulfide film by potentiodynamic deposition as competent electrode for supercapacitor

IF 3.3 Q3 ENERGY & FUELS
Sajeeda Shaikh, M. Rabinal
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引用次数: 1

Abstract

Abstract Nanostructures of transition metal sulfides can be important electrodes to achieve high performance supercapacitors. Creation of binder-less electrodes of these materials is a challenge. The present potentiodynamic electrodeposition technique helps to achieve these objectives and the studied supercapacitors exhibit a good performance. The potentiodynamic method is used to efficiently install binder-free stable film of nickel sulfide (Ni_3S_2) on a copper electrode at ambient conditions in neutral pH to explore its symmetric supercapacitor capabilities. The method yields nano-sized particles tightly bonded into 3D-porous structures. This alleviates large internal surface areas, mechanical stability, short ion diffusion length, and better ion-conducting pathways, which are essential properties of electrodes for a better supercapacitor. The supercapacitor was constituted with 2 M KOH electrolyte which shows a high specific capacity of 168.4 Cg^−1 at 2.5 Ag^−1 (758 Fg^−1 at 2.5 Ag^−1) and good stability up to 3000 charge–discharge cycles, high rate capability, and high energy and power density. Therefore, these hybrid electrodes can be promising materials for electrochemical energy storage systems. Graphical abstract Discussion Development of supercapacitor with high energy content, low cost, and environmental friendly is a great challenge. Microscopic electrochemical understanding of electrode and electrolytic interaction and the possible mechanisms of charge storage are critically important parameters to develop robust energy storage systems.
动电位沉积硫化镍薄膜作为超级电容器的称职电极
摘要过渡金属硫化物的纳米结构可以成为实现高性能超级电容器的重要电极。制造这些材料的无粘合剂电极是一项挑战。目前的动电位电沉积技术有助于实现这些目标,并且所研究的超级电容器表现出良好的性能。采用动电位法在中性pH的环境条件下,在铜电极上有效地安装了无粘结剂的稳定硫化镍(Ni_3S_2)膜,以探索其对称超级电容器的性能。该方法产生紧密结合到三维多孔结构中的纳米尺寸颗粒。这减轻了大的内表面积、机械稳定性、短的离子扩散长度和更好的离子传导路径,这些都是更好的超级电容器的电极的基本特性。超级电容器由2 M KOH电解质组成,在2.5 Ag−1时表现出168.4 Cg^−1的高比容量(在2.5 Ag^−1时为758 Fg^−),在3000次充放电循环中表现出良好的稳定性、高倍率能力以及高能量和功率密度。因此,这些混合电极可以成为电化学储能系统的有前途的材料。图形摘要讨论开发高能量、低成本、环保的超级电容器是一个巨大的挑战。对电极和电解相互作用的微观电化学理解以及电荷存储的可能机制是开发稳健储能系统的关键参数。
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来源期刊
MRS Energy & Sustainability
MRS Energy & Sustainability ENERGY & FUELS-
CiteScore
6.40
自引率
2.30%
发文量
36
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