利用乙二醇合成聚合物防晒光催化剂 ZnO2、CuO2、PbO2 和 CdO2,用于去除纺织废水中的活性蓝染料

IF 2.1 4区 化学 Q3 CHEMISTRY, PHYSICAL
Rida Zulfiqar, Ruba Munir, Muhammad Zeeshan Bashir, Gadah Albasher, Tayyaba Samreen, Iram Hafiz, Mian Anjum Murtaza, Saima Noreen
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引用次数: 0

摘要

工业染料是造成环境污染的主要原因。本研究采用光催化剂吸附技术,通过批量研究去除合成阴离子染料。吸附剂采用化学合成法制备。在 pH 值为 5 时,ZnO2 对活性蓝染料的去除率最高。在 pH 值为 2、4 和 5 时,四种纳米粒子(ZnO2、CuO2、PbO2 和 CdO2)消除阴离子染料的最佳剂量均为 0.5 克/50 毫升。对于 ZnO2、CuO2、PbO2 和 CdO2 纳米光催化剂,在催化剂用量为 0.05 时,染料去除率最高。不同种类的吸附剂对阴离子染料去除率最高的起始浓度为 25-200 mg/L。在染料浓度为 100、150 和 75 mg/L 时,ZnO2(85.69 mg/L)、CuO2(79.04 mg/L)、PbO2(64.12 mg/L)和 CdO2(51.58 mg/L)的吸附容量最大。阴离子染料去除率最高的最佳温度为 37 °C,随着温度的降低,整个化合物的吸附能力下降。这表明在排除某些阴离子染料时,所有吸附过程都会产生放热现象。朗缪尔生物吸附等温线对平衡生物吸附数据的适应性最好,而假二阶对吸附动力学数据的适应性最好。此外,数据显示,ZnO2、CuO2、PbO2 和 CdO2 纳米粒子吸附消除活性蓝染料的过程遵循二阶动力学(R2 = 0.9855)和 Langmuir 模型(0.9997)。0.5 N 氢氧化钠可实现最大程度的解吸。傅立叶变换红外(FTIR)被用来表征纳米颗粒,它提供了染料上官能团的信息。因此,通过使用吸附技术,可以观察到废水中染料的最大去除率,ZnO2 对阴离子染料的去除率最高。在紫外线(UV)辐射下,ZnO2 在光催化作用的辅助下可有效降解水溶液中的活性蓝。
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 Polymeric Sunscreen Photocatalyst ZnO2, CuO2, PbO2, and CdO2 Using Ethylene Glycol for Reactive Blue Dye Removal from Textile Waste Water

Synthesis of Polymeric Sunscreen Photocatalyst ZnO2, CuO2, PbO2, and CdO2 Using Ethylene Glycol for Reactive Blue Dye Removal from Textile Waste Water

Industrial dyes are the main cause of environmental pollution. The present study consists of the removal of synthetic anionic dye using batch study with photocatalyst using adsorption technology. The adsorbents were prepared using the chemical synthesis method. At pH 5, ZnO2 shows maximum results in the Reactive Blue dye. At the same time, CuO2 shows maximum results at pH 2. In contrast, the CdO2 and PbO2 nanoparticles presented maximum results at pH 4. The optimum dose for all four kinds of nanoparticles, ZnO2, CuO2, PbO2, and CdO2, was found to be 0.5 g/50 mL for the elimination of anionic dye at pH 2, 4, and 5. For ZnO2, CuO2, PbO2, and CdO2 nano photocatalyst, the maximum percentage of dye removal was recorded at 0.05 catalyst dosage. The starting concentration of dye in the series of 25–200 mg/L was measured as optimum for the highest deletion of anionic stain by dissimilar kinds of chosen adsorbents. The maximum adsorption capacity of ZnO2 (85.69 mg/L), CuO2 (79.04 mg/L), PbO2 (64.12 mg/L), and CdO2 (51.58 mg/L) was obtained at 100, 150 and 75 mg/L dye concentration. The optimum temperature for the highest removal of anionic dyes was detected at 37 °C, and the reduction examined a decline in the adsorption capacity of whole compounds as temperature decreases. It represented the exothermic behavior of all sorption processes intricate in the exclusion of certain anionic dyes. Langmuir biosorption isotherms were given the best fitness on equilibrium biosorption data, whereas the pseudo 2nd order displayed the fitness on adsorption kinetic data. Additionally, data show that the elimination of Reactive Blue dye by adsorption with ZnO2, CuO2, PbO2, and CdO2 nanoparticles follows second-order kinetics (R2 = 0.9855) and Langmuir model (0.9997). Utmost desorption was attained by 0.5 N sodium hydroxide. Fourier Transform Infrared (FTIR) was used to characterize the nanoparticles, which gave information about the functional groups on dyes. So, by using the adsorption technology, maximum dye removal from wastewater was observed, and ZnO2 showed maximum percentage removal of anionic dye. Reactive Blue is effectively degraded in aqueous solution by photocatalysis with ZnO2 assistance while being exposed to ultraviolet (UV) radiation.

Graphical Abstract

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来源期刊
Catalysis Surveys from Asia
Catalysis Surveys from Asia 化学-物理化学
CiteScore
4.80
自引率
0.00%
发文量
29
审稿时长
>12 weeks
期刊介绍: Early dissemination of important findings from Asia which may lead to new concepts in catalyst design is the main aim of this journal. Rapid, invited, short reviews and perspectives from academia and industry will constitute the major part of Catalysis Surveys from Asia . Surveys of recent progress and activities in catalytic science and technology and related areas in Asia will be covered regularly as well. We would appreciate critical comments from colleagues throughout the world about articles in Catalysis Surveys from Asia . If requested and thought appropriate, the comments will be included in the journal. We will be very happy if this journal stimulates global communication between scientists and engineers in the world of catalysis.
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