Natural Pyrite-assisted Mechanochemical Recovery of Insoluble Manganese from Electrolytic Manganese Residue: Kinetics and Mechanisms

Xiang, Hongrui; Yang, Zhihui; Liu, Size; Li, Xiaoqin; Yang, Chenyun; Ke, Yong; Liu, Xiaoyun; Zhao, Feiping; Shi, Meiqing; Lin, Zhang

doi:10.1021/acsestengg.3c00190

Cited by 9 publications

(3 citation statements)

References 60 publications

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“…A new characteristic peak was observed at 35.22°, which may be attributed to β-FeCr 2 O 4 . , These results indicated that Fe 3+ attaches to the surface and pore structure of biochar, providing more adsorption sites, which was beneficial for the adsorption of a large number of pollutants. Moreover, the results indicated that a series of chemical reactions may have occurred between Fe and Cr(VI) on Fe@MBC during the progress of the removal reaction. , …”

Section: Results and Discussionmentioning

confidence: 93%

Fabrication of Iron-Containing Biochar by One-Step Ball Milling for Cr(VI) and Tetracycline Removal from Wastewater

Jiang,

Wei,

et al. 2023

Langmuir

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Section: Results and Discussionmentioning

confidence: 93%

Fabrication of Iron-Containing Biochar by One-Step Ball Milling for Cr(VI) and Tetracycline Removal from Wastewater

Jiang,

Wei,

et al. 2023

Langmuir

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“…However, there is still ammonia nitrogen in the electrolyte that has not been removed, and so, it is necessary to further study how to treat it synchronously. In addition, the recovery of insoluble manganese from electrolytic manganese slag is also worth exploring [18], so as to realize harmless treatment and resource utilization in the real sense.…”

Section: Discussionmentioning

confidence: 99%

Recovery and Utilization of Lead in Lead–Containing Waste Residue from Electrolytic Manganese Production

Song,

Fan,

Zhou

2023

Metals

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As a metallurgical and chemical raw material, electrolytic manganese is an important strategic resource. However, with the rapid development of the electrolytic manganese industry, the correct disposal of anode slime has become a serious problem. The purpose of this experiment was to reduce the occupation of land resources by the lead–containing waste residue of electrolytic manganese, reduce the pollution caused by the lead–containing waste residue to the environment and provide a reference for the research on the treatment technology and resource utilization of lead–containing waste residue in China. In this experiment, a special process was studied for the composition characteristics of lead–containing waste residues produced by electrolytic manganese. The acid leaching–enrichment–membrane electrolysis process was used to recover the lead in the lead–containing waste residues of electrolytic manganese and to recover the acid, so as to maximize the utilization of resources. In this experiment, the pretreated lead–containing waste residue was leached, enriched and concentrated, and then the enriched Pb2+ solution was used as cathode solution and dilute nitric acid as anode solution to recover lead by membrane electrolysis. The membrane electrolysis experiment uses lead plate as cathode, selects the best anion exchange membrane and anodic electrolysis material, and then takes lead recovery, acid recovery, current efficiency, voltage and power consumption as investigation indexes to explore and analyze the influence of many factors such as Pb2+ concentration and current density on the experiment, so as to determine the best membrane electrolysis process parameters. The optimum process parameters of lead recovery by membrane electrolysis were determined as follows: Pb2+ concentration was 40 g/L, current density was 30 mA/cm2, reaction temperature was 60 °C, cathodic pH value was 4.0, anodic HNO3 concentration was 0.5 mol/L, and cathodic ammonium nitrate concentration was 50 g/L. Under the optimal conditions, the current efficiency was 85.6%, the acid recovery was 73.03%, the lead recovery was 99.2%, the voltage was 3.8 V, and the power consumption was 1148.4 kW·h·t−1. Through the three steps of acid leaching–enrichment–membrane electrolysis, 78.53% of the Pb2+ in the original lead–containing waste residue can be recovered in the form of metal lead element, and the HNO3 recovered in the anode chamber can also be used again in the acid leaching process, which can not only solve the problem of environmental pollution caused by lead–containing waste residue but also achieve the recovery and utilization of resources, with good social and economic benefits.

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“…In past decades, tremendous progress has been made to eliminate heavy metals from water. − Some low-cost advantage-oriented approaches (i.e., chemical precipitation, ion flotation, ion exchange, adsorption, and coagulation/flocculation) have been used to remove heavy metals from wastewater. − Among these approaches, adsorption is considered suitable for dealing with wastewater containing low concentrations of metal ions . Adsorbents such as activated carbon, mesoporous resins, and membranes have been reported for removal of heavy metals.…”

Section: Introductionmentioning

confidence: 99%

Aminopoly(carboxylic acid)-Functionalized PolyHIPE Beads toward Eliminating Trace Heavy Metal Ions from Water

Guo,

Wang,

You

et al. 2024

Langmuir

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Many advanced materials are designed for the removal of heavy metal ions from water. However, materials for eliminating trace heavy metal ions from wastewater to meet drinking water standards remain a major challenge. Herein, epoxy group-functionalized open-cellular beads are synthesized by UV polymerization of a water-in-oil-in-water system. The epoxy groups are further transformed into diethylenetriaminepentaacetic acid (DTPA) with hexamethylene diamine as a bridging agent. The resulting material (DTPA@polyHIPE beads) can eliminate trace Cu(II), Cr(III), Pb(II), Fe(III), or Cd(II) from water. When 0.15 g of DTPA@polyHIPE beads are used to adsorb metal ions of 20 mg in 100 mL of water, the residue concentrations of Cu(II), Cr(III), Pb(II), Fe(III), and Cd(II) are reduced to 0.08, 0.06, 0.02, 0.09, and 0.07 mg/L, respectively. The adsorption efficiencies of the beads for these ions are all higher than 99.55%. The adsorbent is durable and exhibits good recyclability by retaining an adsorption capacity of ≥91% after 5 cycles. The negative values of ΔG in the adsorption process indicate that the adsorption is feasible and spontaneous. The chemical adsorption follows the Freundlich adsorption model, indicating a multilayer heterogeneous adsorption. The DTPA@polyHIPE beads have a great potential application in dealing with trace heavy metal ion polluted water.

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Natural Pyrite-assisted Mechanochemical Recovery of Insoluble Manganese from Electrolytic Manganese Residue: Kinetics and Mechanisms

Cited by 9 publications

References 60 publications

Fabrication of Iron-Containing Biochar by One-Step Ball Milling for Cr(VI) and Tetracycline Removal from Wastewater

Fabrication of Iron-Containing Biochar by One-Step Ball Milling for Cr(VI) and Tetracycline Removal from Wastewater

Recovery and Utilization of Lead in Lead–Containing Waste Residue from Electrolytic Manganese Production

Aminopoly(carboxylic acid)-Functionalized PolyHIPE Beads toward Eliminating Trace Heavy Metal Ions from Water

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