Orange Dye Removal Efficiency by Few-layer Graphene: an Investigation by UV-Vis Spectroscopy

IF 0.8 4区物理与天体物理 Q4 OPTICS

Optics and Spectroscopy Pub Date : 2022-07-31 DOI:10.1134/S0030400X22030092

Hamid Motahari, Hoorieh Shaterian Mohammadi, Abbas Behjat

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Abstract

Nowadays, few-layer graphene (FLG) has been introduced as a new type of adsorbent. In this research, the orange dyes including, methyl orange (MO) as an industrial dye and the soft drink orange dye (orange Fanta soda) as a food dye, have been removed by FLG adsorbent. In all steps, UV-Vis spectroscopy as a valuable and fast method has been applied. The optical absorption coefficient has been decreased from 0.9 to less than 0.2 by FLG adsorbent for 50 ppm MO dye solution. Therefore, the MO solution with 50 ppm concentration converts to about 10 ppm output solution using 0.05 g of FLG adsorbent in a few minutes. It is about 80% adsorption dye removal efficiency. Also, MO dye removals have been performed in the range of 10 ppm to 500 ppm concentrations, but as the concentration of the solution increases, the dye adsorption ability of FLG decreases. The maximum efficient and optimum MO dye concentrations are about 100 ppm and 50 ppm, respectively, due to 0.05 g FLG adsorbent. It has been completely saturated at about 500 ppm concentration MO dye solution. Also, it has been observed that, for 50 ppm MO dye solution, increasing the amount of mass adsorbent from 0.05 to 0.25 g can cause the output MO concentration to decrease from 10 ppm to 3 ppm. It has been revealed that about 94% of MO dye can remove by 0.25 g FLG adsorbent. The contact time due to 94% MO removal process is less than 5 minutes. Therefore, only by 0.25 g of FLG adsorbent we can purify wastewater containing 50 ppm MO dye to less than 3 ppm dye concentration, at less than a few minutes. Finally, the FLG glass tube filter can remove more than 90% food orange dye in less than 90 s for 50 mL of soft drink solution. Therefore, the FLG tube filtration process is so fast, easy, and high efficient.

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紫外可见光谱法研究少层石墨烯对橙色染料的去除效果

近年来，少层石墨烯作为一种新型吸附剂被广泛应用。本研究采用FLG吸附剂对工业染料甲基橙(MO)和食用染料软饮料橙色染料(芬达橙色汽水)进行了脱除。在所有步骤中，紫外可见光谱作为一种有价值且快速的方法得到了应用。在50ppm MO染料溶液中，FLG吸附剂的光学吸收系数由0.9降至0.2以下。因此，使用0.05 g FLG吸附剂，50 ppm浓度的MO溶液在几分钟内转化为10 ppm左右的输出溶液。吸附脱色效率约为80%。此外，在10 ppm至500 ppm的浓度范围内进行了MO染料的去除，但随着溶液浓度的增加，FLG对染料的吸附能力下降。由于添加0.05 g FLG吸附剂，MO染料的最大有效浓度和最佳浓度分别约为100 ppm和50 ppm。它已在约500ppm浓度的MO染料溶液中完全饱和。此外，还观察到，对于50 ppm的MO染料溶液，将质量吸附剂的量从0.05 g增加到0.25 g，可以使输出的MO浓度从10 ppm降低到3 ppm。结果表明，0.25 g FLG吸附剂可去除约94%的MO染料。94% MO去除过程中接触时间小于5分钟。因此，只需0.25 g的FLG吸附剂，我们就可以在不到几分钟的时间内将含有50 ppm MO染料的废水净化到低于3 ppm的染料浓度。最后，FLG玻璃管过滤器可以在不到90秒的时间内对50ml的软饮料溶液去除90%以上的食品橙色染料。因此，FLG管过滤过程是如此快速，简单，高效。

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

Optics and Spectroscopy 物理-光谱学

CiteScore

1.60

自引率

0.00%

发文量

审稿时长

4.5 months

期刊介绍： Optics and Spectroscopy (Optika i spektroskopiya), founded in 1956, presents original and review papers in various fields of modern optics and spectroscopy in the entire wavelength range from radio waves to X-rays. Topics covered include problems of theoretical and experimental spectroscopy of atoms, molecules, and condensed state, lasers and the interaction of laser radiation with matter, physical and geometrical optics, holography, and physical principles of optical instrument making.