Novel bowl-like or capped carbon with a low carbon footprint as electrode material in EDLCs

IF 3.1 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY
Satvik Anshu , Rahul R , Surbhi Priya , Alok Kumar Srivastava , Amreesh Chandra
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Abstract

Large surface area, excellent electrical conductivity, homogeneous structure, and extended cycling stability are desirable characteristics for energy materials. Carbon-derived structures exhibit porous structure, work well in a wide potential window, and are highly conductive. Hence, they can show enhanced rate capability and cycle life. Despite ongoing efforts, the synthesis of carbons at lower temperatures remains a challenge. In comparison, the high-temperature synthesis protocols lead to a high CO2 footprint. Here, we report the synthesis of unique carbon morphologies, namely capped carbon nanostructures (CCS) and bowl-like carbon structures (BCS). Their performances are either comparable or higher than those conventionally used morphologies of carbon, such as nanospheres, microspheres, nanotubes, graphene oxide, and layered structures. The four-sided opening in BCS particles ensures higher adsorption of electrolyte ions, which is even higher than hierarchical or spherical structures. The cap formation on the CCS acts like an additional layer on top of the sphere. Further, the CCS is arranged in a sequential honeycomb array, which leads to the formation of definitive channels for electrolyte diffusion. The unique carbon morphologies showed nearly ∼ 40 % increment in the specific capacitance values compared to other commonly used carbon structures. The novel morphologies also have a much lower carbon footprint, as shown by the life cycle assessment (LCA) studies.

将低碳足迹的新型碗状或封盖碳作为 EDLC 的电极材料
大表面积、优异的导电性、均匀的结构和更长的循环稳定性是能源材料的理想特性。碳衍生结构呈现多孔结构,在宽电位窗口内工作良好,并具有高导电性。因此,它们可以提高速率能力和循环寿命。尽管一直在努力,但在较低温度下合成碳仍然是一项挑战。相比之下,高温合成方案会导致较高的二氧化碳足迹。在此,我们报告了独特碳形态的合成,即封盖碳纳米结构(CCS)和碗状碳结构(BCS)。它们的性能与传统的碳形态(如纳米球、微球、纳米管、氧化石墨烯和层状结构)相当或更高。BCS 颗粒的四面开口可确保更高的电解质离子吸附性,其吸附性甚至高于分层或球形结构。CCS 上形成的帽状结构就像球体顶部的附加层。此外,CCS 呈蜂窝状依次排列,从而形成了明确的电解质扩散通道。与其他常用的碳结构相比,这种独特的碳形态使比电容值提高了近 40%。生命周期评估(LCA)研究表明,这种新型形态的碳足迹也低得多。
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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来源期刊
Carbon Trends
Carbon Trends Materials Science-Materials Science (miscellaneous)
CiteScore
4.60
自引率
0.00%
发文量
88
审稿时长
77 days
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