Copper-PANI-graphite HB2 composite for eco-friendly efficient degradation of textile dyes: Advancements in wastewater treatment enhanced by solar radiation.

Chemosphere Pub Date : 2024-10-01 Epub Date: 2024-10-14 DOI:10.1016/j.chemosphere.2024.143537

Martin O A Pacheco-Álvarez, Rosa M Sevillano-Arredondo, Oracio Serrano, Juan Manuel Peralta-Hernández

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Abstract

This research aimed to assess the potential of Cu₅₀PANI@UG composite for sunlight drive photocatalytic dye degradation, targeting specifically Thymol Blue (TB) and Black NT (BNT) dyes and their mixture (DM). The Cu₅₀PANI@UG composite was successfully synthesized via electropolymerization in acetonitrile/sulfuric acid mixture under atmospheric conditions. Photocatalytic experiments were conducted by exposing aqueous dye solutions to sunlight. N,N-dimethyl-p-nitrosoaniline (RNO) served as a molecular probe for detecting hydroxyl radicals (^•OH). Additionally, experiments capturing free radicals were performed to identify active components, with a concomitant proposal of plausible degradation reaction mechanism for the Photo-Fenton-Like degradation into the Cu₅₀PANI@UG composite + H₂O₂ + hv reaction system. Various operating parameters affecting dye degradation were evaluated, including catalyst dosage (from 0.27 to 0.67 g L^-1), H₂O₂ concentration (from 16 to 64 mM), pH (from 3.0 to 9.0), and dye concentration (from 25 to 100 mg L^-1). Optimization of key parameters such as pH, catalyst dosage, and H₂O₂ concentration was conducted. The highest degradation efficiency, ca. 100% of DM dye, was achieved within 35 min under optimized conditions, using Cu₅₀PANI@UG composite as a catalytic precursor. These conditions were determined as follows: Catalyst dosage = 0.67 g L^-1, pH = 3.0-6.0, H₂O₂ = 32-64 mM, and irradiation time of 35 min. The degradation percentage under the Response Surface Methodology (RSM) was utilized as a statistical tool to correlate influential parameters. Four consecutive reusability trials were performed to assess catalyst stability.

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铜-PANI-石墨 HB2 复合材料用于高效降解纺织染料的生态友好型技术：利用太阳辐射强化废水处理的进展。

本研究旨在评估 Cu50PANI@UG 复合材料在阳光驱动下光催化降解染料的潜力，特别是针对百里酚蓝（TB）和黑色 NT（BNT）染料及其混合物（DM）。在大气条件下，通过在乙腈/硫酸混合物中进行电聚合，成功合成了 Cu50PANI@UG 复合材料。将染料水溶液置于阳光下进行了光催化实验。N,N-二甲基-p-亚硝基苯胺（RNO）是检测羟基自由基（-OH）的分子探针。此外，还进行了捕获自由基的实验，以确定活性成分，并同时提出了 Cu50PANI@UG 复合材料 + H2O2 + hv 反应体系中类似光-芬顿降解的合理降解反应机制。评估了影响染料降解的各种操作参数，包括催化剂用量（从 0.27 到 0.67 g L-1）、H2O2 浓度（从 16 到 64 mM）、pH 值（从 3.0 到 9.0）和染料浓度（从 25 到 100 mg L-1）。对 pH 值、催化剂用量和 H2O2 浓度等关键参数进行了优化。在优化条件下，以 Cu50PANI@UG 复合材料为催化前驱体，在 35 分钟内实现了最高降解效率，DM 染料的降解率约为 100%。这些条件确定如下催化剂用量 = 0.67 g L-1，pH = 3.0-6.0，H2O2 = 32-64 mM，辐照时间 35 分钟。利用响应面方法（RSM）下的降解百分比作为统计工具，对影响参数进行相关分析。连续进行了四次可重复使用性试验，以评估催化剂的稳定性。

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Chemosphere

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