FeS2 Nanoparticles in S-Doped Carbon: Ageing Effects on Performance as a Supercapacitor Electrode

C Pub Date : 2023-11-17 DOI:10.3390/c9040112

Sirine Zallouz, Bénédicte Réty, J. Le Meins, Mame Youssou Ndiaye, P. Fioux, Camélia Matei Ghimbeu

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Abstract

Although transition metal sulfides have prodigious potential for use as electrode materials because of their low electronegativities, their large volume changes inhibit broad application. Moreover, there is only limited knowledge of the ageing processes of these materials at the nanoscale. Herein, nano-C/FeS2 materials were prepared via one-pot syntheses from green biodegradable carbon precursors, followed by activation and sulfidation. The increased activation/sulfidation time led to an increase in the size of the nanoparticles (7 to 17 nm) and their aggregation, as well as in an increase in the specific surface area. The materials were then used as electrodes in 2-electrode symmetric supercapacitors with 2 M KOH. The activation process resulted in improved capacitance (60 F g−1 at 0.1 A g−1) and rate capability (36%) depending on the composite porosity, conductivity, and size of the FeS2 particles. The ageing of the FeS2 nanoparticles was investigated under air, and a progressive transformation of the nano-FeS2 into hydrated iron hydroxy sulfate with a significant morphological modification was observed, resulting in drastic decreases in the capacitance (70%) and retention. In contrast, the ageing of nano-FeS2 during cycling led to the formation of a supplementary iron oxyhydroxide phase, which contributed to the enhanced capacitance (57%) and long-term cycling (132% up to 10,000 cycles) of the device.

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S 掺杂碳中的 FeS2 纳米颗粒：老化对超级电容器电极性能的影响

尽管过渡金属硫化物因其电负性低而在用作电极材料方面具有巨大潜力，但其巨大的体积变化阻碍了其广泛应用。此外，人们对这些材料在纳米尺度上的老化过程了解有限。在本文中，纳米碳/FeS2 材料是通过绿色可生物降解碳前体的一锅合成法制备的，然后进行活化和硫化。活化/硫化时间的延长导致纳米颗粒的尺寸（7 至 17 纳米）增大、聚集以及比表面积的增加。这些材料随后被用作 2 M KOH 的双电极对称超级电容器的电极。活化过程提高了电容（0.1 A g-1 时为 60 F g-1）和速率能力（36%），这取决于复合孔隙率、电导率和 FeS2 颗粒的大小。在空气中对纳米 FeS2 颗粒的老化进行了研究，结果发现纳米 FeS2 逐渐转变为水合羟基硫酸铁，形态发生了显著变化，导致电容（70%）和保持率急剧下降。与此相反，在循环过程中，纳米铁二氧化物的老化导致形成了羟基氢氧化铁补充相，从而提高了器件的电容（57%）和长期循环能力（132%，高达 10,000 次循环）。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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