E. Papadaki, Theodoros G. Chatzimitakos, V. Athanasiadis, Dimitris Kalompatsios, Eleni Bozinou, P. Mitlianga, S. Lalas
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The results showed that FAs were able to sorb most of the examined metals compared to HAs. Several metals such as Ba (34.22–37.77%), Ca (99.12–99.58%), and Sr (97.89–98.12%) were efficiently sorbed when 900 ppm of FAs from both sources were used but were not sorbed by HAs from any source (≤0.1%). Due to the functional groups on the surface of FA, it is plausible to conclude that it can remove more metals than HA. Meanwhile, lignite from the South Field mine was found to be more efficient for the sorption efficiency in lower concentrations (300–600 ppm), whereas lignite from the Mavropigi mine was more effective in higher concentrations (900 ppm). For instance, higher removal rates were observed in Mo (62.84%), Pb (56.81%), and U (49.22%) when 300 ppm of HAs of South Field mine were used, whilst the employment of 900 ppm of HAs from Mavropigi mine led to high removal rates of As (49.90%), Se (64.47%), and Tl (85.96%). The above results were also reflected in a principal component analysis, which showed the dispersion of the metal parameters near to or far from the HA and FA parameters depending on their sorption capacity. Overall, both HA and FA could be effectively utilized as sorbent materials for metal removal from water samples. The results of the research indicate a potential application to the remediation of water from metals under dynamic conditions in order to protect public health.","PeriodicalId":81291,"journal":{"name":"Foundations","volume":"103 8","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2023-12-07","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Assessment of Humic and Fulvic Acid Sorbing Potential for Heavy Metals in Water\",\"authors\":\"E. Papadaki, Theodoros G. Chatzimitakos, V. Athanasiadis, Dimitris Kalompatsios, Eleni Bozinou, P. Mitlianga, S. 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引用次数: 0
摘要
水源重金属污染是一个紧迫的环境问题。为此目的,正在使用各种程序来修复水,包括吸附。本研究的目的是探讨腐植酸(HAs)和黄腐酸(FAs)对水中金属的去除效果。具体来说,研究了HA和FA作为26种重金属、碱金属和碱土金属的吸附材料的潜力。HA和FA分别从希腊西马其顿Kozani的Mavropigi矿和South Field矿的褐煤样品中分离得到。实验采用未经pH调节的天然矿泉水进行,以便更好地了解实际样品的吸附效率。结果表明,与HAs相比,FAs能够吸收大部分被检测的金属。当两种来源的FAs均为900 ppm时,Ba(34.22-37.77%)、Ca(99.12-99.58%)和Sr(97.89-98.12%)等金属均被有效吸附,而任何来源的HAs均未被吸附(≤0.1%)。由于FA表面的官能团,它可以比HA去除更多的金属。同时,南田矿褐煤在较低浓度(300-600 ppm)下的吸附效率更高,而Mavropigi矿褐煤在较高浓度(900 ppm)下的吸附效率更高。例如,当使用300 ppm South Field矿的HAs时,Mo(62.84%)、Pb(56.81%)和U(49.22%)的去除率较高,而使用900 ppm Mavropigi矿的HAs时,As(49.90%)、Se(64.47%)和Tl(85.96%)的去除率较高。上述结果也反映在主成分分析中,表明金属参数在HA和FA参数附近或远处的分散取决于它们的吸附量。综上所述,HA和FA都可以有效地作为吸附材料去除水样中的金属。研究结果表明,为保护公众健康,在动态条件下对水中的金属进行修复具有潜在的应用前景。
Assessment of Humic and Fulvic Acid Sorbing Potential for Heavy Metals in Water
Pollution of water sources with heavy metals is a pressing environmental issue. To this end, various procedures are being used to remediate water, including sorption. The aim of this study was to investigate the effectiveness of humic acids (HAs) and fulvic acids (FAs) for the removal of metals from water. Specifically, HA and FA were examined for their potential to be used as sorbent materials for 26 heavy metals, alkali metals, and alkaline earth metals. HA and FA were isolated from lignite samples from two mines (Mavropigi mine and South Field mine, Kozani, West Macedonia, Greece). Experiments were carried out using natural mineral water without pH adjustment, so as to gain a better overview of the sorption efficiency in real-life samples. The results showed that FAs were able to sorb most of the examined metals compared to HAs. Several metals such as Ba (34.22–37.77%), Ca (99.12–99.58%), and Sr (97.89–98.12%) were efficiently sorbed when 900 ppm of FAs from both sources were used but were not sorbed by HAs from any source (≤0.1%). Due to the functional groups on the surface of FA, it is plausible to conclude that it can remove more metals than HA. Meanwhile, lignite from the South Field mine was found to be more efficient for the sorption efficiency in lower concentrations (300–600 ppm), whereas lignite from the Mavropigi mine was more effective in higher concentrations (900 ppm). For instance, higher removal rates were observed in Mo (62.84%), Pb (56.81%), and U (49.22%) when 300 ppm of HAs of South Field mine were used, whilst the employment of 900 ppm of HAs from Mavropigi mine led to high removal rates of As (49.90%), Se (64.47%), and Tl (85.96%). The above results were also reflected in a principal component analysis, which showed the dispersion of the metal parameters near to or far from the HA and FA parameters depending on their sorption capacity. Overall, both HA and FA could be effectively utilized as sorbent materials for metal removal from water samples. The results of the research indicate a potential application to the remediation of water from metals under dynamic conditions in order to protect public health.
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