Abbas Abdul Kadhim Klaif Rikabi , Mohanad W. Mahdi Alzubadiy , Zena Hussein Ali , Hebatallah Mohammed Khudhair , Maryam Jawad Abdulhasan
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We then use response surface methodology (RSM) to optimize the synthesis process and evaluate the effectiveness of the prepared nanocomposite for tetracycline remediation. We took different simulated concentrations of the TC contaminant without relying on actual TC concentrations in grounwater, the best removal of the TC contaminant in batch study was investigated with relying on the initial concentrations of TC and other experimental factors such as pH, adsorbent nanomaterial concentration and time. A pilot plant was then constructed to eliminate the TC contaminant from groundwater in different concentrations, where the removal efficiency was found decreased with increasing in the concentration of the TC Many parameters affecting the removal mechanisms in statistical and continuous systems were examined to select the best results that accomplish the maximum elimination rate. With the improved operating conditions, (L-Fe/Ni concentration: 1500 mg/L; concentration of TC: 20 mg/L; pH: 7.2; contact time: 128 min), removal percent of TC was found 87 % based on RSM system. The L-Fe/Ni reactive medium of continuous column has a main role in slowing down the movement of the TC plume. This study showed that the ecofriendly nanocomposite could be an appropriate and novel method for remediation of antibiotics and other contaminants in groundwater.</p></div>","PeriodicalId":21926,"journal":{"name":"South African Journal of Chemical Engineering","volume":"50 ","pages":"Pages 89-99"},"PeriodicalIF":0.0000,"publicationDate":"2024-07-18","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.sciencedirect.com/science/article/pii/S1026918524000829/pdfft?md5=67ec0b60481e51936d04432b2ad554bb&pid=1-s2.0-S1026918524000829-main.pdf","citationCount":"0","resultStr":"{\"title\":\"Optimization of ecofriendly L-Fe/Ni nanoparticles prepared using extract of black tea leaves for removal of tetracycline antibiotics from groundwater by response surface methodology\",\"authors\":\"Abbas Abdul Kadhim Klaif Rikabi , Mohanad W. 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We took different simulated concentrations of the TC contaminant without relying on actual TC concentrations in grounwater, the best removal of the TC contaminant in batch study was investigated with relying on the initial concentrations of TC and other experimental factors such as pH, adsorbent nanomaterial concentration and time. A pilot plant was then constructed to eliminate the TC contaminant from groundwater in different concentrations, where the removal efficiency was found decreased with increasing in the concentration of the TC Many parameters affecting the removal mechanisms in statistical and continuous systems were examined to select the best results that accomplish the maximum elimination rate. With the improved operating conditions, (L-Fe/Ni concentration: 1500 mg/L; concentration of TC: 20 mg/L; pH: 7.2; contact time: 128 min), removal percent of TC was found 87 % based on RSM system. The L-Fe/Ni reactive medium of continuous column has a main role in slowing down the movement of the TC plume. 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引用次数: 0
摘要
本文重点探讨了利用绿色合成的双金属铁/镍在石灰石颗粒支撑下修复地下水中四环素类抗生素(TC)的纳米技术。利用红茶叶提取物原位绿色合成纳米颗粒,生成锂-铁-镍纳米复合材料。合成的纳米复合材料采用了多种技术进行表征,如 X 射线衍射 (XRD)、扫描电子显微镜 (SEM)、透射电子显微镜 (TEM)、能量色散 X 射线 (EDX)、傅立叶变换红外光谱 (FTIR) 和表面积。然后,我们利用响应面方法论(RSM)优化合成过程,并评估所制备的纳米复合材料对四环素的修复效果。我们在不依赖于格栅水中实际四环素浓度的情况下,模拟了不同浓度的四环素污染物,并根据四环素的初始浓度以及 pH 值、纳米吸附材料浓度和时间等其他实验因素,研究了批量研究中四环素污染物的最佳去除率。然后建造了一个中试工厂,以去除地下水中不同浓度的三氯乙酸污染物,结果发现随着三氯乙酸浓度的增加,去除效率降低。 在统计和连续系统中,对影响去除机制的许多参数进行了研究,以选择能达到最大去除率的最佳结果。随着操作条件的改善,(L-Fe/Ni 浓度:1500毫克/升;三氯甲烷浓度:20毫克/升;pH值:7.2;接触时间:128分钟),三氯甲烷的去除率在 RSM 系统中达到了 87%。连续柱中的 L-Fe/Ni 反应介质在减缓三氯乙酸羽流移动方面发挥了主要作用。这项研究表明,生态友好型纳米复合材料可以成为修复地下水中抗生素和其他污染物的一种适当而新颖的方法。
Optimization of ecofriendly L-Fe/Ni nanoparticles prepared using extract of black tea leaves for removal of tetracycline antibiotics from groundwater by response surface methodology
This article focuses on employment of nanotechnologies in remediation of tetracycline antibiotics (TC) from groundwater by green synthesized bimetallic Fe/Ni supported by limestone particles. An in-situ green synthesis nanoparticles was prepared using black tea leaves extract to generate a L-Fe/Ni nanocomposite. The synthesized nanocomposite was characterized using several techniques, such as, X-Ray Diffraction (XRD), Scanning Electron microscopy (SEM), transmission electron microscope (TEM), Energy dispersive X-ray (EDX), FTIR (Fourier Transform-Infra Red) spectroscopy and surface area. We then use response surface methodology (RSM) to optimize the synthesis process and evaluate the effectiveness of the prepared nanocomposite for tetracycline remediation. We took different simulated concentrations of the TC contaminant without relying on actual TC concentrations in grounwater, the best removal of the TC contaminant in batch study was investigated with relying on the initial concentrations of TC and other experimental factors such as pH, adsorbent nanomaterial concentration and time. A pilot plant was then constructed to eliminate the TC contaminant from groundwater in different concentrations, where the removal efficiency was found decreased with increasing in the concentration of the TC Many parameters affecting the removal mechanisms in statistical and continuous systems were examined to select the best results that accomplish the maximum elimination rate. With the improved operating conditions, (L-Fe/Ni concentration: 1500 mg/L; concentration of TC: 20 mg/L; pH: 7.2; contact time: 128 min), removal percent of TC was found 87 % based on RSM system. The L-Fe/Ni reactive medium of continuous column has a main role in slowing down the movement of the TC plume. This study showed that the ecofriendly nanocomposite could be an appropriate and novel method for remediation of antibiotics and other contaminants in groundwater.
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