The Oxidation and Immobilization of As(III) by Colloidal Ferric Hydroxide in the Concomitant Pollution of Oxytetracycline

Tong, Yunping; Wang, Xiaolei; Wang, Xinghao; Sun, Zhaoyue; Fang, Guodong; Gao, Juan

doi:10.1021/acsestengg.2c00367

Cited by 7 publications

(2 citation statements)

References 76 publications

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“…Superoxide (O 2 •– ) is a ubiquitous reactive oxygen species in the environment, − playing a crucial role in various biochemical processes. It influences biological cell activity, facilitates metal recycling, and promotes pollutant reduction. ,, O 2 •– exhibits both oxidizing and reducing properties ( E 0 (O 2 •– /H 2 O 2 ) = +0.91 V) and reducing properties ( E 0 (O 2 /O 2 •– ) = −0.18 V), , allowing it to engage in single electron transfer, deprotonation, and nucleophilic substitution reactions with organic components. , O 2 •– is detected in different advanced oxidation processes, particularly in heterogeneous systems, and numerous studies have highlighted its significant contribution to pollutant degradation. − The contribution of O 2 •– is usually identified by the quenching method, − resulting from the apparent inhibition caused by the quenching of p -benzoquinone ( p -BQ) or superoxide dismutase (SOD). However, since O 2 •– is not highly reactive, quenching in complex systems is susceptible to interference from highly reactive species.…”

Section: Introductionmentioning

confidence: 99%

Identification of Superoxide Contribution through the Quenching Method and Model System

Cai,

Yao,

et al. 2024

ACS EST Eng.

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The quenching method is widely utilized to evaluate the contribution of reactive species; however, its validity has recently been questioned. The primary role of superoxide (O 2•− ) in pollutant degradation remains controversial due to its low reactivity. To ascertain the suitability of the quenching method and the degradation ability of O 2•− , a simple and efficient O 2generation system was built using p-benzoquinone (p-BQ) as the probe with disodium hydrogen phosphate−dimethyl sulfoxide (DHP−DMSO). The results demonstrated that O 2 •− is accountable for p-BQ transformation in DHP−DMSO, and can also be generated in various alkaline-organic solvent (methanol, ethanol, iso-propanol, tert-butanol, acetonitrile, acetone, chloroform, and tetrahydrofuran) systems, revealing that these reagents do not scavenge O 2•− . Superoxide dismutase has limited ability on O 2 •− quenching in the presence of hydroxyl radicals ( • OH). Some organic solvents can produce organic radicals when stimulated by • OH. This serves as a reminder to exercise caution when employing these quenchers. O 2•− exhibited insufficient degradation capability for the majority of the eight organic pollutants tested. The relevance of O 2•− in pollutant degradation can be quickly discerned by DHP−DMSO. This study holds significant importance in accurately evaluating the contribution of reactive species.

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Section: Introductionmentioning

confidence: 99%

Identification of Superoxide Contribution through the Quenching Method and Model System

Cai,

Yao,

et al. 2024

ACS EST Eng.

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“…The increasing toxicity and complexity due to the combined pollution of heavy metals and antibiotics in aqueous media, arising from worldwide urbanization and industrialization, is causing public concern over environmental issues. − As a result of natural and anthropogenic activities including waste discharge, rock weathering, and mining, high levels of arsenic (up to 1350 μg/L) have been frequently detected in groundwater in the northwest of China, for example, Inner Mongolia, Xinjiang Uighur, and Guizhou province, which markedly exceed the detection limit (10 μg/L) set by the World Health Organization (WHO) . Meanwhile, in the rural areas contaminated by arsenic, pharmaceutical antibiotics (e.g., tetracycline) used for animals and humans to treat infectious diseases are often directly released into domestic sewage, which will be reutilized for irrigation of farmland and inevitably lead to the antibiotic pollution of groundwater. , Excessive and long-term exposure to heavy metals and antibiotics can adversely affect the growth of animals and plants and even cause a series of health-related problems such as cancer, neurotoxicity, and chronic kidney disease through migration and the food chain. − Recent studies have demonstrated that the presence of tetracycline could reduce the immobility of arsenic in aqueous solutions, and meanwhile, the presence of high concentrations of arsenic also inhibited the removal of tetracycline. ,, Undoubtedly, their interactive behavior adversely affects the overall treatment efficiency.…”

Section: Introductionmentioning

confidence: 99%

Highly Dispersed Magnetite Nanoparticles on Biochar with Sulfonation Modification for Simultaneous Removal of Arsenite and Tetracycline from Aqueous Solutions: Performance and Mechanistic Insight

Zhao,

Zhu,

Zhou

et al. 2023

ACS EST Water

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The remediation of combined pollution of heavy metals and antibiotics in an aqueous environment remains challenging. Through magnetite (Fe3O4) dispersion followed by sulfonation modification, we report a novel bifunctional biochar-based composite (labeled Fe3O4@BC–SO3H) for simultaneous removal of arsenite (As(III)) and tetracycline (TC) in aqueous solutions. Batch experiments in single-solute systems show that Fe3O4@BC–SO3H exhibits faster kinetic and higher adsorption capacity than raw biochar, Fe3O4, and magnetite-dispersed biochar (Fe3O4@BC), thus leading to enhanced removal efficiency for either As(III) or TC. More notably, Fe3O4@BC–SO3H can simultaneously remove above 85% of As(III) and TC compared with less than 50% removal of As(III) and TC by biochar, Fe3O4, and Fe3O4@BC. Combining the spectroscopic analyses, the co-removal process of As(III) and TC indicates a unique mechanism with two-stage reactions, which involves As(III) redox transformation in the first stage and TC adsorption in the second stage. This study proposes a new strategy to design biochar-based composites for the decontamination of As(III) and TC. Overall, the excellent performance and stability of Fe3O4@BC–SO3H show its substantial potential as a low-cost, highly efficient, and eco-friendly material for the remediation of combined pollution in water.

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Antibiotics-heavy metals combined pollution in agricultural soils: Sources, fate, risks, and countermeasures

Shu,

Li,

Xie

et al. 2024

Green Energy & Environment

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The Oxidation and Immobilization of As(III) by Colloidal Ferric Hydroxide in the Concomitant Pollution of Oxytetracycline

Cited by 7 publications

References 76 publications

Identification of Superoxide Contribution through the Quenching Method and Model System

Identification of Superoxide Contribution through the Quenching Method and Model System

Highly Dispersed Magnetite Nanoparticles on Biochar with Sulfonation Modification for Simultaneous Removal of Arsenite and Tetracycline from Aqueous Solutions: Performance and Mechanistic Insight

Antibiotics-heavy metals combined pollution in agricultural soils: Sources, fate, risks, and countermeasures

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