Kumar Ravindra, Keshari Ashish Kumar, Sinha Roy Susanta, Patel Geetika, Maity Gurupada
Department of Applied Physics, Gautam Buddha University, Greater Noida 210312, India.
Department of Physics, Shiv Nadar University, Greater Noida 201314, India.
ACS Omega. 2024 Jul 17;9(30):32828-32836. doi: 10.1021/acsomega.4c03452. eCollection 2024 Jul 30.
Two-dimensional transition-metal dichalcogenides (TMDs) have emerged as promising capacitive materials for supercapacitors owing to their layered structure, high specific capacity, and large surface area. Herein, Ni-doped SnS microflowers were successfully synthesized via a facile one-step solvothermal approach. The obtained Ni-doped SnS microflowers exhibited a high specific capacitances of 459.5 and 77.22 F g at current densities of 2 and 10 A g, respectively, in NaClO electrolyte, which was found to be higher than that of SnS-based electrodes in various electrolytes such as KOH, KCl, NaSO, NaOH, and NaNO. Additionally, these microflowers demonstrate a good specific energy density of up to 51.69 Wh kg, at a power density of 3204 Wkg. Moreover, Ni-doped SnS microflowers exhibit a capacity retention of 78.4% even after 5000 cycles. Better electrochemical performance of the prepared electrode may be attributed to some important factors, including the utilization of a highly ionic conductive and less viscous NaClO electrolyte, incorporation of Ni as a dopant, and the marigold flower-like morphology of the Ni-doped SnS. Thus, Ni-doped SnS is a promising electrode material in unconventional high-energy storage technologies.
二维过渡金属二硫属化物(TMDs)因其层状结构、高比容量和大表面积,已成为超级电容器中很有前景的电容材料。在此,通过简便的一步溶剂热法成功合成了镍掺杂的硫化锡微花。在NaClO电解液中,所制备的镍掺杂硫化锡微花在电流密度分别为2和10 A g时,比电容分别高达459.5和77.22 F g,这一数值高于在KOH、KCl、NaSO、NaOH和NaNO等各种电解液中的基于硫化锡的电极。此外,这些微花在功率密度为3204 Wkg时,展现出高达51.69 Wh kg的良好比能量密度。而且,镍掺杂硫化锡微花即使在5000次循环后仍保持78.4%的容量保持率。所制备电极更好的电化学性能可能归因于一些重要因素,包括使用高离子导电性且低粘度的NaClO电解液、掺入镍作为掺杂剂以及镍掺杂硫化锡的金盏花状形态。因此,镍掺杂硫化锡在非常规高能量存储技术中是一种很有前景的电极材料。
