Removal of Divalent Copper Ions from Aqueous Solution using Sorghum bicolor L. Stem Waste as an Effective Adsorbent

IF 1.3 Q4 ENGINEERING, ENVIRONMENTAL
Rika Wahyuni Rusti Annisa, F. Fahruddin, Paulina Taba
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Abstract

Sorghum stem ( Sorghum bicolor L . ) is a plant that has not been maximally utilized. But sorghum stems contain high cellulose. The hydroxyl (OH-) and carboxyl (-COOH) groups on cellulose can bind heavy metals; therefore, sorghum stems have the opportunity to be used as an adsorbent to absorb heavy metals, especially Cu(II) metal, which can pollute the environment. Therefore, this research was conducted to determine the optimum pH, contact time, and the adsorption capacity of Cu(II) using HNO 3 modified sorghum stem adsorbent. The stages of the re - search included the preparation of sorghum stem adsorbent, modification of adsorbent with HNO 3 , determination of optimum pH, optimum contact time and adsorption capacity of Cu(II) metal. Furthermore, the functional groups of the adsorbent before and after modification were determined by FTIR. SEM-EDS to assess the morphological structure and chemical components contained in the adsorbent. After the research, the optimum pH of Cu(II) metal adsorption was pH 6, and the adsorption power was 99.88%. The optimum contact time is 10 minutes. The percent removal of Cu(II) metal with concentrations of 10, 30, 50, and 100 ppm were 79.96; 79.90; 56.40 and 54.04%, respectively. Adsorption of Cu(II) metal using HNO 3 modified sorghum stem adsorbent followed the Freundlich isotherm pattern compared to Langmuir with R 2 = 0.9039. It is concluded that activated sorghum stem can be used as Cu(II) metal adsorbent.
利用高粱双色茎废料作为有效吸附剂去除水溶液中的二价铜离子
高粱茎(Sorghum bicolor L .但高粱茎中含有大量纤维素。纤维素上的羟基(OH-)和羧基(-COOH)可以吸附重金属,因此,高粱茎有机会用作吸附剂来吸收重金属,尤其是会污染环境的金属铜(II)。因此,本研究采用 HNO 3 改性高粱茎吸附剂来确定最佳 pH 值、接触时间和对 Cu(II)的吸附能力。研究的各个阶段包括制备高粱茎吸附剂、用 HNO 3 对吸附剂进行改性、确定最佳 pH 值、最佳接触时间和对金属铜(II)的吸附量。此外,还通过傅立叶变换红外光谱测定了吸附剂改性前后的官能团。通过 SEM-EDS 评估吸附剂的形态结构和所含化学成分。经研究,吸附 Cu(II) 金属的最佳 pH 值为 pH 6,吸附力为 99.88%。最佳接触时间为 10 分钟。对浓度为 10、30、50 和 100 ppm 的金属铜(II)的去除率分别为 79.96%、79.90%、56.40% 和 54.04%。使用 HNO 3 改性高粱茎吸附剂对金属铜(II)的吸附遵循 Freundlich 等温线模式,与 Langmuir 相比,R 2 = 0.9039。结论是活性高粱茎可用作 Cu(II) 金属吸附剂。
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来源期刊
Journal of Ecological Engineering
Journal of Ecological Engineering ENGINEERING, ENVIRONMENTAL-
CiteScore
2.60
自引率
15.40%
发文量
379
审稿时长
8 weeks
期刊介绍: - Industrial and municipal waste management - Pro-ecological technologies and products - Energy-saving technologies - Environmental landscaping - Environmental monitoring - Climate change in the environment - Sustainable development - Processing and usage of mineral resources - Recovery of valuable materials and fuels - Surface water and groundwater management - Water and wastewater treatment - Smog and air pollution prevention - Protection and reclamation of soils - Reclamation and revitalization of degraded areas - Heavy metals in the environment - Renewable energy technologies - Environmental protection of rural areas - Restoration and protection of urban environment - Prevention of noise in the environment - Environmental life-cycle assessment (LCA) - Simulations and computer modeling for the environment
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