Kinetic and Mechanistic Study of oxidative Degradation And Detoxification of Fast Yellow Azo Dye Using Surfactant Assisted Ir-Ni Bimetallic Nanocatalyst

IF 0.9 Q4 CHEMISTRY, PHYSICAL Current Organocatalysis Pub Date : 2022-04-07 DOI:10.2174/2213337209666220407113453

A. Goel, Shikha

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Abstract

Catalytic degradation of azo dye. Azo dyes are toxic agents and pollutants and the degradation of these dyes has an important application in the treatment of textile industry wastes. Catalytic decolorization of fast yellow dye by hexacyanoferrate (III), abbreviated as HCF(III) using polyvinylpyrrolidone abbreviated as PVP stabilized Ir-Ni bimetallic nanocrystals has been evaluated by kinetic spectrophotometric method at 440nm wavelength of the reaction mixture. The impact of various operational factors such as fast yellow dye abbreviated as [FY], oxidant [HCF(III)] ions, promoter iridium-nickel bimetallic nanoparticles abbreviated as [(Ir-Ni)] BMNPs, and solution pH on the rate of the reaction have been examined. The results represent that the reaction follows first -order kinetics model with respect to [oxidant] at optimum pH 8 and fix temperature 40±0.1◦C. Thermodynamic parameters such as activation energy (Ea), enthalpy (ΔH#), entropy (ΔS#), frequency factor (A), and free energy of activation (ΔF#) have been evaluated by examining the reaction rate at four temperatures i.e. 40⁰C, 45⁰C, 50⁰C, and 55⁰C. On the basis of experimental outcomes, an appropriate mechanism involving complex formation has been proposed. Analytical techniques such as UV-Vis spectroscopy, FTIR, and LCMS of degraded products represent the formation of easier and less harmful compounds.

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表面活性剂辅助Ir-Ni双金属纳米催化剂氧化降解脱毒快黄偶氮染料的动力学及机理研究

偶氮染料的催化降解。偶氮染料是一种有毒物质和污染物，对偶氮染料的降解在纺织工业废水处理中有着重要的应用。在反应混合物的440nm波长处，用动力学分光光度法考察了六氰铁酸盐(III)(简称HCF(III))与聚乙烯吡咯烷酮(简称PVP稳定Ir-Ni双金属纳米晶体)对坚黄染料的催化脱色效果。考察了各种操作因素如坚黄染料(简写为[FY])、氧化剂[HCF(III)]离子、促进剂铱-镍双金属纳米颗粒(简写为[(Ir-Ni)])和溶液pH对反应速率的影响。结果表明，在最佳pH值为8，固定温度为40±0.1◦C时，与[氧化剂]有关的反应符合一级动力学模型。热力学参数，如活化能(Ea)、焓(ΔH#)、熵(ΔS#)、频率因子(A)和自由活化能(ΔF#)已经通过检查四种温度下的反应速率进行了评估，即40⁰C、45⁰C、50⁰C和55⁰C。在实验结果的基础上，提出了一个涉及复杂形成的适当机制。分析技术，如紫外可见光谱，FTIR，和LCMS降解产物代表更容易和更少有害的化合物的形成。

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来源期刊

Current Organocatalysis CHEMISTRY, PHYSICAL-

CiteScore

2.00

自引率

0.00%

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期刊介绍： Current Organocatalysis is an international peer-reviewed journal that publishes significant research in all areas of organocatalysis. The journal covers organo homogeneous/heterogeneous catalysis, innovative mechanistic studies and kinetics of organocatalytic processes focusing on practical, theoretical and computational aspects. It also includes potential applications of organocatalysts in the fields of drug discovery, synthesis of novel molecules, synthetic method development, green chemistry and chemoenzymatic reactions. This journal also accepts papers on methods, reagents, and mechanism of a synthetic process and technology pertaining to chemistry. Moreover, this journal features full-length/mini review articles within organocatalysis and synthetic chemistry. It is the premier source of organocatalysis and synthetic methods related information for chemists, biologists and engineers pursuing research in industry and academia.