First Direct and Unequivocal Electron Spin Resonance Spin-Trapping Evidence for pH-Dependent Production of Hydroxyl Radicals from Sulfate Radicals

Gao, Huiying; Huang, Chunhua; Mao, Li; Shao, Bo; Shao, Jie; Yan, Zhu-Ying; Tang, Miao; Zhu, Ben-Zhan

doi:10.1021/acs.est.0c04410

Cited by 163 publications

(58 citation statements)

References 80 publications

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“…Periodate (PI, IO 4 – )-based advanced oxidation processes (AOPs) have recently received increasing attention for the abatement of aqueous contaminants. − Compared with liquid-form oxidants (e.g., hydrogen peroxide (H 2 O 2 ), hypochlorous acid (HClO), and peracetic acid (PAA)) as the precursor of reactive species, solid-form oxidants (e.g., persulfate (PS) and PI) are relatively stable and impose much less safety risks during the transportation and storage process, which were even more preferred under certain circumstances. , For PI-based AOPs, despite the conclusive approach for the detection of iodate radical ( · IO 3 ) is still unavailable, · IO 3 and reactive oxygen species (e.g., hydroxyl radical ( · OH), atomic oxygen radical anion ( · O – ), superoxide radical ( · O 2 – ), and singlet oxygen ( 1 O 2 )) were generally recognized as the dominant active intermediates generated via the inter- and/or intramolecular electron transfer mechanism (eqs –). ,,− …”

Section: Introductionmentioning

confidence: 99%

Enhanced Oxidation of Organic Contaminants by Iron(II)-Activated Periodate: The Significance of High-Valent Iron–Oxo Species

Zong

Shao

Zeng

et al. 2021

Environ. Sci. Technol.

302

144

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Potassium periodate (PI, KIO 4 ) was readily activated by Fe(II) under acidic conditions, resulting in the enhanced abatement of organic contaminants in 2 min, with the decay ratios of the selected pollutants even outnumbered those in the Fe(II)/ peroxymonosulfate and Fe(II)/peroxydisulfate processes under identical conditions. Both 18 O isotope labeling techniques using methyl phenyl sulfoxide (PMSO) as the substrate and Xray absorption near-edge structure spectroscopy provided conclusive evidences for the generation of high-valent iron−oxo species (Fe(IV)) in the Fe(II)/PI process. Density functional theory calculations determined that the reaction of Fe(II) with PI followed the formation of a hydrogen bonding complex between Fe(H 2 O) 62+ and IO 4 (H 2 O) − , ligand exchange, and oxygen atom transfer, consequently generating Fe(IV) species. More interestingly, the unexpected detection of 18 O-labeled hydroxylated PMSO not only favored the simultaneous generation of • OH but also demonstrated that • OH was indirectly produced through the self-decay of Fe(IV) to form H 2 O 2 and the subsequent Fenton reaction. In addition, IO 4− was not transformed into the undesired iodine species (i.e., HOI, I 2 , and I 3 − ) but was converted to nontoxic iodate (IO 3 − ). This study proposed an efficient and environmental friendly process for the rapid removal of emerging contaminants and enriched the understandings on the evolution mechanism of • OH in Fe(IV)-mediated processes.

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Section: Introductionmentioning

confidence: 99%

Enhanced Oxidation of Organic Contaminants by Iron(II)-Activated Periodate: The Significance of High-Valent Iron–Oxo Species

Zong

Shao

Zeng

et al. 2021

Environ. Sci. Technol.

302

144

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“…6 a), however, the peak ( m / z 209) was clearly detected but the peak ( m / z 130) was hardly detected, suggesting that the main free radicals of O SC were SO 4 • − . Actually, because of the Scheme 3 [35] , the difficulty of free radical identification was increased [43] . However, by PN-HRMS with ROC detecting, the detection (consumption) was along with the reaction (from “without US originally” to “after introducing US”) to gain the variations of peaks at m / z 130 and 209 in real time, illustrating that i) •OH mainly originated from reaction of US-O SC , not Scheme 3 ; ii) after introducing US, the type of dominant free radicals tended to be •OH in the system and the transformation may be mainly initiated from SO 4 • − (being consistent with Section 3.5.1 -iiii); and iii) the PN-HRMS with ROC detecting (comparing with traditional detecting means, liquid chromatograph/mass spectrometer (LC/MS) or EPR with intermittent sample testing one by one) at a certain degree could avoid the potential misjudgement due to Scheme 3 .…”

Section: Resultsmentioning

confidence: 99%

Ultrasonic role to activate persulfate/chlorite with foamed zero-valent-iron: Sonochemical applications and induced mechanisms

Zhang

Leng

et al. 2021

Ultrasonics Sonochemistry

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Highlights The novel foamed-ZVI activating persulfate/chlorite by ultrasonic was applied. The real-time and online continuous detections tracked radicals transformation. The EPR spectra with different systems in different mixtures were detected. The free or non-free radicals processes induced by US were explored. The dynamics on cavitation and the US-field simulation were presented.

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“…It is commonly believed that SO 4 ˙could be easily converted to ˙OH under alkaline conditions (Equation 4), and the produced ˙OH possesses a shorter life and lower oxidation capacity than SO 4 ˙-. 33 In addition, the leaching of Fe and Co became more serious in acidic solution (Figure S5A), but the leached amount was still very low even after experiencing five cycles at initial pH of 3.6…”

Section: Effect Of Phmentioning

confidence: 99%

Filter‐membrane treatment of continuous‐flow tetracycline through photocatalysis‐assisted peroxydisulfate oxidation

Zhu

Tang

et al. 2022

AIChE Journal

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Herein, we craft a high‐performance advanced oxidation process (AOP) of photocatalysis‐coupled peroxydisulfate (PDS) system toward practical applications in organic wastewater treatment. CoFe2O4 nanoparticles well grow onto TiO2 nanotube arrays (TNAs) mesh (CoFe2O4/TNAs). The artful CoFe2O4/TNAs composite plays a bifunctional role in the proposed AOP. On one hand, CoFe2O4/TNAs itself is a visible‐light‐response photocatalyst. On the other hand, the Co(II) or Fe(II) in CoFe2O4 can heterogeneously activate PDS to generate energetic active species (•OH, SO4˙–, O2˙–, and 1O2). Meanwhile, the photo‐induced electrons can be also captured by electron traps Co(III) (or Fe(III)) which are further reduced to Co(II) (or Fe(II)) for continuous activation of PDS. As a result, the robust AOP of photocatalysis‐coupled PDS can almost completely degrade 10 mg/L refractory tetracycline within 40 min. Moreover, the proposed process shows a stable continuous‐flow treatment performance. This work provides basic understanding and support for continuous‐flow treatment of organic wastewater by photocatalysis‐coupled PDS system.

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First Direct and Unequivocal Electron Spin Resonance Spin-Trapping Evidence for pH-Dependent Production of Hydroxyl Radicals from Sulfate Radicals

Cited by 163 publications

References 80 publications

Enhanced Oxidation of Organic Contaminants by Iron(II)-Activated Periodate: The Significance of High-Valent Iron–Oxo Species

Enhanced Oxidation of Organic Contaminants by Iron(II)-Activated Periodate: The Significance of High-Valent Iron–Oxo Species

Ultrasonic role to activate persulfate/chlorite with foamed zero-valent-iron: Sonochemical applications and induced mechanisms

Filter‐membrane treatment of continuous‐flow tetracycline through photocatalysis‐assisted peroxydisulfate oxidation

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