ZnO/nZVI nanoparticle-enhanced double-slope U-shaped solar distillation: A thermodynamic investigation of cephalexin adsorption

IF 7.1 3区 材料科学 Q1 GREEN & SUSTAINABLE SCIENCE & TECHNOLOGY
A. Sangeetha , S. Shanmugan , Abdulaziz Alasiri
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引用次数: 0

Abstract

The increasing need for sustainable methods to remove pharmaceutical contaminants like cephalexin and improve water desalination is critical. This study explores ZnO/nZVI nanoparticles synthesized with Jackfruit peel extracts as eco-friendly, cost-effective adsorbents, enhancing water purification in solar desalination systems. This work used a matte black paint coating within a double slope U-shaped solar distiller (DSUD) in a discontinuous experimental setting to examine potential improvements in solar distillation performance. Activated carbon (AC) and bioactive powdered nanoparticles of ZnO/nZVI (nano zerovalent iron), produced from jackfruit peel extracts (JP) were combined in a synergistic way. The effectiveness of cephalexin removal was assessed taking into account the JPAC solution parameters, reaction duration, ZnO/nZVI concentrations in the nanocomposite dosage, and initial nanocomposite concentration. The best conditions for cephalexin adsorption were found to be pH 5 and reaction time of 50 min, which resulted in high absorption efficiencies of 94.74% (nZVI) and 97.53% (ZnO) at room temperature with a JPAC dose of 2.50 g L⁻1. The efficiency of the eco-friendly adsorbent in getting rid of cephalexin was calculated using “pseudo-second-order kinetics” for nanocomposites, which is consistent with the “Langmuir” isothermal absorption process. The nanocomposites as absorbent materials in solar thermal desalination processes, efficient heat transmission and energy storage have been established. JPAC and the addition of steel balls (S) with a silver hue to the DSUD improved the internal heat transfer mechanisms. Thermodynamic of Gibbs free energy and the Laplacian method (TGL), two thermodynamic concepts, were used to extensively study the temperature dynamics of the DSUD with SJPAC components. For ZnO/JPAC, an exceptional distillate production rate was noted from 8:00 to 18:00, with a noteworthy 4.932 L/m2 output in winter and 5.833 L/m2 per day in summer. Using silver balls, ZnO/JPAC generated significant yields over a 24-h period: 8.957 L/m2 in summer and 7.253 L/m2 in winter, with an ideal energy efficiency of 51.05%. The unique advancements in TGL procedures and their environmental consequences are presented in this paper. The field of thermal energy transduction will advance if silver balls are used in DSUD for the synthesis of JPAC, ZnO/JPAC, and nZVI/JPAC, as supported by the theoretical insights presented here.

Abstract Image

ZnO/nZVI 纳米粒子增强型双斜 U 型太阳能蒸馏:头孢氨苄吸附的热力学研究
去除头孢氨苄等药物污染物和改善海水淡化对可持续方法的需求与日俱增。本研究探讨了用柚子皮提取物合成的 ZnO/nZVI 纳米粒子,将其作为生态友好、经济高效的吸附剂,提高太阳能海水淡化系统的水净化效果。这项研究在不连续的实验环境中,在双斜坡 U 型太阳能蒸馏器(DSUD)内使用了哑光黑色涂料涂层,以检验太阳能蒸馏性能的潜在改进。活性炭(AC)和从柚子皮提取物(JP)中提取的具有生物活性的粉末状纳米 ZnO/nZVI(纳米零价铁)以协同增效的方式结合在一起。考虑到 JPAC 溶液参数、反应持续时间、纳米复合材料用量中 ZnO/nZVI 的浓度以及纳米复合材料的初始浓度,对头孢氨苄的去除效果进行了评估。结果发现,pH 值为 5、反应时间为 50 分钟是头孢氨苄的最佳吸附条件,在室温下,当 JPAC 剂量为 2.50 g L-1 时,吸收效率高达 94.74%(nZVI)和 97.53%(ZnO)。利用纳米复合材料的 "伪二阶动力学 "计算了环保吸附剂去除头孢氨苄的效率,这与 "朗缪尔 "等温吸收过程一致。纳米复合材料作为吸收材料在太阳能热脱盐过程中的高效传热和储能作用已经确立。JPAC 和在 DSUD 中添加银色钢球 (S) 改善了内部传热机制。吉布斯自由能热力学和拉普拉斯法(TGL)这两个热力学概念被用来广泛研究含有 SJPAC 成分的 DSUD 的温度动态。就 ZnO/JPAC 而言,从 8:00 到 18:00,蒸馏物的生产率非常高,值得注意的是,冬季每天的产量为 4.932 升/平方米,夏季为 5.833 升/平方米。通过使用银球,ZnO/JPAC 在 24 小时内产生了可观的产量:夏季为 8.957 升/平方米,冬季为 7.253 升/平方米,理想能效为 51.05%。本文介绍了 TGL 程序的独特进步及其对环境的影响。如果在 DSUD 中使用银球合成 JPAC、ZnO/JPAC 和 nZVI/JPAC,热能传导领域将得到进一步发展,本文提出的理论见解也为这一点提供了支持。
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
CiteScore
5.80
自引率
6.40%
发文量
174
审稿时长
32 days
期刊介绍: Materials Today Sustainability is a multi-disciplinary journal covering all aspects of sustainability through materials science. With a rapidly increasing population with growing demands, materials science has emerged as a critical discipline toward protecting of the environment and ensuring the long term survival of future generations.
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