Efficient removal of safranin from aqueous solution using a new type of metalated highly self-doped polyaniline nanocomposite

Hammed H. A. M. Hassan, Marwa Abdel Fattah
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Abstract

We report the chemical synthesis of poly(aniline-co-aniline-2,5-disulfonic acid)) and its composite containing L-hexuronic acid and metallic Ag/SiO2 nanoparticles as a new thermally stable anionic polyelectrolyte for removing safranin dye. The composite was characterized by IR, UV, cyclic voltammetry, SEM, TEM, TGA, DSC, EDXS and elemental analyses. Microscopic images exhibited intensified spherical particles dispersed over almost the entire surface. The XRD exhibited peaks of the partially crystalline material at many 2θ values, and their interatomic spacing and sizes were calculated. The cyclic voltammograms exhibited characteristic redox peaks relative to the quinoid ring transition states. The uptake rates up to 82.5% adsorption were completed within 75 min and the equilibrium time was 45 min. The isotherm of dye adsorption interprets the interaction with the adsorbent and explain the relationship between the dye removal capacity and the initial dye concentration. In the current, the Langmuir isotherm model was the optimum to interpret both the dye/copolymer and the dye/composite interactions. The uptake of safranin by copolymer/SiO2@Ag nanocomposite was well defined by pseudo second order model with rate constant K2 = 0.03 g− 1 mg− 1 min− 1 for 19 mg safranin. A comparison of safranin adsorption efficiency of the synthesized material with other reported material in the same domain suggested that the present composite has a higher adsorption rate and capacity. The ongoing research is devoted to improving the removal percentage of the dye by using 1,3,5-triazine based sulfonated polyaniline/Ag@ SiO2 nanocomposite.

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一种新型金属化高度自掺杂聚苯胺纳米复合材料对水溶液中红花苷的高效去除
本文报道了化学合成聚苯胺-共苯胺-2,5-二磺酸及其复合材料(含l -己醛酸和金属Ag/SiO2纳米颗粒)作为一种新型的热稳定阴离子聚电解质,用于去除红花色素。通过IR、UV、循环伏安、SEM、TEM、TGA、DSC、EDXS和元素分析对复合材料进行了表征。显微图像显示强化的球形颗粒分散在几乎整个表面。XRD在多个2θ值处显示出部分结晶材料的峰,并计算了它们的原子间距和尺寸。循环伏安图显示出与醌环过渡态相关的特征性氧化还原峰。吸附速率为82.5%,在75 min内完成,平衡时间为45 min。染料吸附等温线解释了与吸附剂的相互作用,并解释了染料去除能力与初始染料浓度之间的关系。目前,Langmuir等温线模型是解释染料/共聚物和染料/复合材料相互作用的最佳模型。共聚物/SiO2@Ag纳米复合材料对红花素的吸收采用伪二阶模型,速率常数K2 = 0.03 g−1 mg−1 min−1。将合成的材料与同领域其他已报道的材料对红花素的吸附效率进行了比较,表明该复合材料具有更高的吸附速率和吸附容量。目前正在进行的研究是利用1,3,5-三嗪基磺化聚苯胺/Ag@ SiO2纳米复合材料来提高染料的去除率。
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