Recovery of Metals from Acid Mine Drainage by Bioelectrochemical System Inoculated with a Novel Exoelectrogen, Pseudomonas sp. E8

Ai, Chenbing; Hou, Shanshan; Zhang, Yan; Zheng, Xiaoya; Amanze, Charles; Chai, Liyuan; Qiu, Guanzhou; Zeng, Weimin

doi:10.3390/microorganisms8010041

Cited by 29 publications

(6 citation statements)

References 40 publications

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“…Understanding this behavior will be important for enabling accurate predictions of the geochemical reactivity underlying various geological and environmental technologies. For example, the inhibition of calcite dissolution by dissolved metal cations would negatively impact the efficiency of passive remediation of mine tailings and acid mine drainages where limestone (up to 95% calcite) is used to buffer acidic waters typically characterized by elevated levels of dissolved metals. − Specifically, the inhibited dissolution of calcite could lead to a higher-than-expected mobility of contaminants under conditions where acid mine waters pass through limestone beds. A robust understanding of these metal–carbonate interactions would help in the development of more efficient remediation strategies for metal contaminants associated with mining activities.…”

Section: Environmental Implicationsmentioning

confidence: 99%

Dynamic Inhibition of Calcite Dissolution in Flowing Acidic Pb²⁺ Solutions

Abdilla,

Lee,

Fenter

et al. 2024

Environ. Sci. Technol.

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Reactions of mineral surfaces with dissolved metal ions at far-from-equilibrium conditions can deviate significantly from those in near-equilibrium systems due to steep concentration gradients, ion−surface interactions, and reactant transport effects that can lead to emergent behavior. We explored the effect of dissolved Pb 2+ on the dissolution rate and topographic evolution of calcite ( 104) surfaces under far-from-equilibrium acidic conditions (pH 3.7) in a confined single-pass laminar-flow geometry. Operando measurements by digital holographic microscopy were conducted over a range of Pb 2+ concentrations ([Pb 2+ ] = 0 to 5 × 10 −2 M) and flow velocities (v = 1.67−53.3 mm s −1 ). Calcite (104) surface dissolution rates decreased with increasing [Pb 2+ ]. The inhibition of dissolution and the emergence of unique topographic features, including micropyramids, variable etch pit shapes, and larger scale topographic patterns, became increasingly apparent at [Pb 2+ ] ≥ 5 × 10 −3 M. A better understanding of such dynamic reactivity could be crucial for constructing accurate models of geochemical transport in aqueous carbonate systems.

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Section: Environmental Implicationsmentioning

confidence: 99%

Dynamic Inhibition of Calcite Dissolution in Flowing Acidic Pb²⁺ Solutions

Abdilla,

Lee,

Fenter

et al. 2024

Environ. Sci. Technol.

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“…Cr(VI) To date, many reports have shown that the metal ion removal efficiency and electricity production performance in MFCs are mainly affected by the metal ion type and concentration, electrode materials, anode substrates, and microbe community [19,20]. It is very meaningful to better understand these factors and their effects on the system in order to develop efficient and applicable technologies for metal-polluted wastewater treatment.…”

Section: Typical Ions Reactions Stanmentioning

confidence: 99%

Metal Recovery and Electricity Generation from Wastewater Treatment: The State of the Art

Chen

Zhu

et al. 2022

Processes

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The recovery of metal resources from wastewater is very important for both resource recovery and wastewater treatment. Compared with traditional metal-polluted wastewater treatment technologies, advanced wastewater treatment technologies with the functions of both recovering metals and generating electricity have been developed rapidly in recent years. These advanced technologies include microbial fuel cells, photo fuel cells, coupled redox fuel cells, etc. In this paper, these advanced technologies are elaborated from their principles to their applications in wastewater treatment for metals recovery and electricity generation. The recent progress of these technologies was also reviewed. The effects of different metal ions, cell configurations, and various operating parameters on their performance were also discussed. Although these technologies are promising, the challenges and the efforts needed to overcome them are also highlighted.

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“…Ai et al . ( 2020 ) achieved the selective recovery of Cu, Cd and Fe by working under MFC or MEC mode, and Leon‐Fernandez et al . ( 2021 ) the sequential recovery of Cu (in MFC mode) and Sn, Ni and Fe (in MEC mode), also from simulated acid mine drainages (Ai et al ., 2020 ; Leon‐Fernandez et al ., 2021 ).…”

Section: Generation Iii: Electrified Biological Treatmentmentioning

confidence: 99%

“…( 2020 ) achieved the selective recovery of Cu, Cd and Fe by working under MFC or MEC mode, and Leon‐Fernandez et al . ( 2021 ) the sequential recovery of Cu (in MFC mode) and Sn, Ni and Fe (in MEC mode), also from simulated acid mine drainages (Ai et al ., 2020 ; Leon‐Fernandez et al ., 2021 ). Finally, other studies have reported the coupling of bioanodes with the cathodic metal removal by precipitation as metal hydroxides or carbonates (Lefebvre et al ., 2012 ; Colantonio and Kim, 2016 ).…”

Section: Generation Iii: Electrified Biological Treatmentmentioning

confidence: 99%

Electrified bioreactors: the next power‐up for biometallurgical wastewater treatment

Ostermeyer

Bonin

León-Fernandez

et al. 2021

Microbial Biotechnology

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Summary Over the past decades, biological treatment of metallurgical wastewaters has become commonplace. Passive systems require intensive land use due to their slow treatment rates, do not recover embedded resources and are poorly controllable. Active systems however require the addition of chemicals, increasing operational costs and possibly negatively affecting safety and the environment. Electrification of biological systems can reduce the use of chemicals, operational costs, surface footprint and environmental impact when compared to passive and active technologies whilst increasing the recovery of resources and the extraction of products. Electrification of low rate applications has resulted in the development of bioelectrochemical systems (BES), but electrification of high rate systems has been lagging behind due to the limited mass transfer, electron transfer and biomass density in BES. We postulate that for high rate applications, the electrification of bioreactors, for example, through the use of electrolyzers, may herald a new generation of electrified biological systems (EBS). In this review, we evaluate the latest trends in the field of biometallurgical and microbial‐electrochemical wastewater treatment and discuss the advantages and challenges of these existing treatment technologies. We advocate for future research to focus on the development of electrified bioreactors, exploring the boundaries and limitations of these systems, and their validity upon treating industrial wastewaters.

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Recovery of Metals from Acid Mine Drainage by Bioelectrochemical System Inoculated with a Novel Exoelectrogen, Pseudomonas sp. E8

Cited by 29 publications

References 40 publications

Dynamic Inhibition of Calcite Dissolution in Flowing Acidic Pb²⁺ Solutions

Dynamic Inhibition of Calcite Dissolution in Flowing Acidic Pb²⁺ Solutions

Metal Recovery and Electricity Generation from Wastewater Treatment: The State of the Art

Electrified bioreactors: the next power‐up for biometallurgical wastewater treatment

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Recovery of Metals from Acid Mine Drainage by Bioelectrochemical System Inoculated with a Novel Exoelectrogen, Pseudomonas sp. E8

Cited by 29 publications

References 40 publications

Dynamic Inhibition of Calcite Dissolution in Flowing Acidic Pb2+ Solutions

Dynamic Inhibition of Calcite Dissolution in Flowing Acidic Pb2+ Solutions

Metal Recovery and Electricity Generation from Wastewater Treatment: The State of the Art

Electrified bioreactors: the next power‐up for biometallurgical wastewater treatment

Contact Info

Product

Resources

About

Dynamic Inhibition of Calcite Dissolution in Flowing Acidic Pb²⁺ Solutions

Dynamic Inhibition of Calcite Dissolution in Flowing Acidic Pb²⁺ Solutions