用于超级电容器的高多孔 CeO2 掺杂 Zr 纳米粒子的增强电化学性能。

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2024-11-07 DOI:10.1002/jemt.24728
M V Arularasu, T V Rajendran, Bassim Arkook, Moussab Harb, K Kaviyarasu
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引用次数: 0

摘要

这项工作旨在开发一种超声波辅助合成方法,用于制造掺杂 CeO2 的 Zr 纳米粒子,从而提高超级电容器电极的性能。这种方法无需高温煅烧,只需通过 1 小时(CeO2-Zr-1)和 2 小时(CeO2-Zr-2)的超声波辐照,将 CeO2 嵌入 Zr 纳米粒子中,从而形成纳米结构,显著改善其电化学性质。通过理化分析,我们观察到掺杂了 CeO2 的 Zr 纳米粒子,尤其是经过 2 小时处理的粒子(CeO2-Zr-2),表现出卓越的晶相纯度、最佳的化学表面成分、最小的团聚(粒径低于 50 纳米)以及令人印象深刻的 178 m2/g 平均表面积。与 1 小时辐照样品(CeO2-Zr-1)和未掺杂 CeO2 纳米粒子相比,(CeO2-Zr-2)电极在电流密度为 1 A/g 时显示出 198 Fg-1 的显著电容,同时在 3750 次循环后保持了约 94.9% 的容量。这表明电极不仅具有良好的可逆性,还具有超强的稳定性。在(CeO2-Zr-2)样品中,通过超声波合成获得的纳米球状结构是电容行为和稳定性增强的原因,而掺杂 Zr 则产生了协同效应,在很大程度上提高了 CeO2 纳米粒子的导电性。由于这两种材料的结合,电极的表面积更大,这也是其性能优越的原因之一。
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Enhanced Electrochemical Performance of Highly Porous CeO2-Doped Zr Nanoparticles for Supercapacitor Applications.

The aim of this work was to develop an ultrasonic-assisted synthesis method for the fabrication of CeO2-doped Zr nanoparticles that would improve the performance of supercapacitor electrodes. This method, which eliminates the need for high-temperature calcination, involves embedding CeO2 into Zr nanoparticles through 1 hr (CeO2-Zr-1) and 2 hrs (CeO2-Zr-2) of ultrasonic irradiation, resulting in the formation of nanostructures with significant improvements in their electrochemical properties. Through physicochemical analysis, we observed that the CeO2-doped Zr nanoparticles, particularly those treated for 2 hrs (CeO2-Zr-2), exhibit superior crystalline phase purity, optimal chemical surface composition, minimal agglomeration with particle sizes below 50 nm, and an impressive average surface area of 178 m2/g. Compared to the 1 hr irradiation samples (CeO2-Zr-1) and undoped CeO2 nanoparticles, the (CeO2-Zr-2) electrodes demonstrated a remarkable capacitance of 198 Fg-1 at a current density of 1 A/g while maintaining ~94.9% of their capacity after 3750 cycles. This indicates not only good reversibility but also exceptional stability. In (CeO2-Zr-2) samples, the nanospherical structure achieved through ultrasonic synthesis is responsible for the enhanced capacitive behavior and stability, along with the synergistic effects caused by Zr doping, which improves the CeO2 nanoparticle conductivity to a significant extent. Surface areas of the electrodes are larger due to the combination of these two materials, which contribute to their superior performance.

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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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