Removal of toxic heavy metal ion from tannery effluent by using Fusarium subglutinans and Hylocereus undatus

被引:3
作者
Latha, A. [1 ]
Ganesan, R. [2 ]
Venkatesan, G. [3 ]
Baraneedharan, P. [4 ]
机构
[1] Panimalar Engn Coll, Dept Civil Engn, Chennai, Tamil Nadu, India
[2] Saveetha Inst Med & Tech Sci SIMATS, Saveetha Sch Engn, Dept Civil Engn, Chennai, Tamil Nadu, India
[3] Saveetha Engn Coll, Dept Civil Engn, Chennai, India
[4] Saveetha Engn Coll, Dept Elect & Commun Engn, Chennai 602105, Tamil Nadu, India
来源
DESALINATION AND WATER TREATMENT | 2023年 / 312卷
关键词
Heavy metal; Dragon fruit peel; Adsorbent dosage; Biosorbent; Kinetic analysis; GREEN SYNTHESIS; AMOXICILLIN; CARBON; NANOPARTICLES; ADSORPTION; TETRACYCLINE; ZEOLITE; BATCH; WATER; DYE;
D O I
10.5004/dwt.2023.29952
中图分类号
TQ [化学工业];
学科分类号
0817 ;
摘要
The major sources of aquatic pollution are tannery effluent from tannery industries. One of method for removing harmful metals from natural water and commercial refuse sources is biosorption of heavy metals. The chrome tannery wastewater sample was procured from State Industries Promotion Corporation of Tamil Nadu Ltd (SIPCOT). To isolate the metal-tolerant fungus with the ability to absorb heavier metal chromium, the gathered specimens were serially reduced. It offers a possible substitute for the traditional method of eliminating metals. The filtered fungal biomass Fusarium subglutinans and agrowaste biosorbent Hylocereus undatus are used to remove the Cr6+ which is present in tannery effluent. The atomic absorption spectrophotometer was used to ascertain the remaining Cr level in solution. The highest % elimination of Cr6+ for the mixed biosorbent was determined to be 98.67% at 50 mg/L starting Cr6+ content, 5 g biosorbent dose, pH 2.0, and 150 rpm agitation speed at room temperature. The optimal period for Cr6+ biosorption on the biosorbent was 60 min. Finding the biosorption process efficiency requires determining its balance. The equilibrium parameters were examined. The association coefficient (R-2) for mixed biosorbent was discovered to be in the following order: Redlich-Peterson (0.9877) > Langmuir (0.8319) > Sips (0.7913) > Freundlich (0.5769). The findings indicated that mixed biosorbent had the capability to remove Cr6+, and the amount of Cr6+ removed from chrome tannery wastewater was determined to be 99.87%. The elimination of Cr6+ from chrome tannery wastewater is a practical, affordable, and environmentally beneficial procedure, according to the analysis of the processed effluent.
引用
收藏
页码:70 / 78
页数:9
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