以陈皮精油脱羟基为原料,绿色化学法合成二氧化锰超级电容器电极材料

D. Izzah, F. Fajaroh, A. Aliyatulmuna, S. Sumari, Sitti Marfu'ah
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引用次数: 0

摘要

在这个时代,大多数技术都需要电子设备。电子设备的性能可能会受到超级电容器等储能元件的影响,因此需要采用绿色化学方法开发超级电容器电极材料。具有良好比电容的材料是MnO2。大多数MnO2的合成方法都不是基于绿色化学,因此有一种替代方法。其中之一是利用陈皮的废料。本研究旨在通过陈皮精油的脱羟基反应合成MnO2。本研究的步骤包括陈皮精油的分离、陈皮精油组成成分的分析、通过陈皮精油脱羟基合成MnO2以及MnO2的表征。XRD结果表明,在pH为11时合成的MnO2具有最高的α-MnO2百分比(97%)。根据ICSD20227,α-MnO2衍射图的存在证明了这一点。SEM结果表明,MnO2具有球形形态,粒径为39.51nm。与β-MnO2和γ-MnO2相比,α-MnO2具有更大的隧道结构,使充放电过程更容易,从而使α-Mn02具有作为超级电容器电极材料的潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Synthesis of MnO2 as Supercapacitor Electrodes Material by Green Chemistry Method Through Dehydroxylation of Tangerine Peel (Citrus reticulata) Essential Oil
In this era, most technology requires electronic equipment. The performance of electronic equipment may be affected by energy storage components like a supercapacitor, so the development of supercapacitor electrode materials using green chemical methods needs to be pursued. Material with a good specific capacitance is MnO2. Most of the MnO2 synthesis methods are not based on green chemistry, so there is an alternative method. One of them is by utilizing the waste from tangerine peels. This study aimed to synthesize MnO2 through dehydroxylation of tangerine peel essential oil. The steps for conducting this research consisted of isolation of tangerine peel essential oil, analysis of the constituent components of tangerine peel essential oil, synthesis of MnO2 through dehydroxylation of essential oils tangerine peel, and MnO2 characterization. XRD results showed that MnO2 synthesized at pH 11 had the highest percentage of α-MnO2 (97%). This is evidenced by the presence of α-MnO2 diffractogram according to the ICSD No.20227. The SEM results showed that MnO2 had a spherical morphology with a particle diameter of 39.51 nm. α-MnO2 has a larger tunnel structure compared to β- and γ-MnO2, making the charge-discharge process easier so that α-MnO2 has the potential as a supercapacitor electrode material.
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