Synergistic effects and mechanisms of hydroxyl radical-mediated oxidative degradation of sulfamethoxazole by Fe(II)-EDTA catalyzed calcium peroxide: Implications for remediation of antibiotic-contaminated water

Amina, Amina; Si, Xiongyuan; Wu, Kang; Si, Youbin; Yousaf, Balal

doi:10.1016/j.cej.2018.07.078

Cited by 59 publications

(15 citation statements)

References 45 publications

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“…Though CHCs or surfactants would affect the BTEX oxidation efficiency because that the presence of CHCs or surfactants could compete for

HO \cdot

with BTEX, the degradation of BTEX could be improved by the following technical methods: (a) increasing the amounts of nCaO 2 and Fe(II) to make the system produce enough

HO \cdot

, (b) adding Fe(II) in two or three stages rather than one stage to ensure the activity of catalyst, (c) optimizing the catalyst availability by chelating reagents (e.g., Fe(II) was used with EDTA) (Amina, Wu, Si, & Yousaf, ; Bai et al, ; Wang, Peng, Xie, Deng, & Deng, ; Xue et al, ; Xue, Lu, et al, ; Xue, Sui, et al, ). Further improving the efficiency of nCaO 2 /Fe(II) system by the above‐mentioned methods will be investigated in our future work.…”

Section: Resultsmentioning

confidence: 99%

The performance of nCaO₂ for BTEX removal: Hydroxyl radical generation pattern and the influences of co‐existing environmental pollutants

Sun

Lyu

et al. 2019

Water Environment Research

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In this study, nano‐CaO2 (nCaO2) was successfully synthesized and constituted the nCaO2/Fe(II) system applying to remediate BTEX, which are typical mixed pollutants in contaminated groundwater. The particle size of the synthesized nCaO2 was 108.91 nm, and it displayed better BTEX remediation performance than that of commercial CaO2. The innovative generation pattern of hydroxyl radicals (HO·) in the nCaO2/Fe(II) system has been investigated using benzoic acid as the HO· probe, and the proper molar ratio of nCaO2/Fe(II) was optimized as 1/1. Over 90% of BTEX was removed in 180 min with the nCaO2/Fe(II)/BTEX molar ratio of 40/40/1. Further experiments evaluated the influence of co‐existence of mixed pollutants chlorinated hydrocarbon compounds (CHCs) or surfactant constituents on BTEX remediation performance. The experimental results suggested that CHCs have limited influence on BTEX removal rate and surfactants have negative effects on BTEX remediation performance in the experimental conditions. In conclusion, the findings in this study could give some inspirations to apply the nCaO2/Fe(II) process in remediating co‐existing pollutants in contaminated groundwater. Practitioner points nCaO2/Fe(II) system applied to remediate mixed contaminants. HO· generation pattern of the nCaO2/Fe(II) system has been investigated. The influence of chloride hydrocarbon compounds have been studied. The effects of surfactants were evaluated.

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“…Though CHCs or surfactants would affect the BTEX oxidation efficiency because that the presence of CHCs or surfactants could compete for

HO \cdot

with BTEX, the degradation of BTEX could be improved by the following technical methods: (a) increasing the amounts of nCaO 2 and Fe(II) to make the system produce enough

HO \cdot

Section: Resultsmentioning

confidence: 99%

The performance of nCaO₂ for BTEX removal: Hydroxyl radical generation pattern and the influences of co‐existing environmental pollutants

Sun

Lyu

et al. 2019

Water Environment Research

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“…FeSO 4 (NH 4 ) 2 SO 4 (1.0 mmol/L, 5 μl), phosphate-buffered saline (50 mmol/L, pH 7.4, 5 μl), DMPO (0.9 mol/L, 5 μl), and 5 μl sludge samples were mixed together, and then measured immediately. IPA and CF were used as scavenger for •OH and •O 2 − , respectively (Amina et al, 2018).…”

Section: Analysis Of Reactive Oxygen Speciesmentioning

confidence: 99%

“…oxidation-reduction reaction, radical chain reaction, and hydrogen atom transfer). Through these reaction ways, organic pollutants can be degraded or produce less toxic intermediates (Qian et al, 2015;Amina et al, 2018;Zhang et al, 2018). Furthermore, MW irradiation can facilitate CaO 2 to generate more •OH and •O 2 − radicals, so the oxidation capacity of CaO 2 is improved.…”

Section: Analysis Of Reactive Oxygen Speciesmentioning

confidence: 99%

“…However, the enhancement of sludge dewatering properties is limited with single CaO 2 treatment (Chen et al, 2016). Research has shown that both ferrous iron and montmorillonite can catalyze the formation of •OH from CaO 2 , thus exhibiting synergistic effects on enhancing sludge dewaterability (Amina et al, 2018;Wu et al, 2018). Chen et al (2016) opined that the combination of CaO 2 and chemical flocculation exhibits superior performance in sludge dewatering performance.…”

Section: Introductionmentioning

confidence: 99%

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Synergetic Effect of Combined CaO2 and Microwave Treatment on Waste Active Sludge Dewaterability and Organic Contaminants’ Removal

Wang

Shang

Liu

et al. 2021

Front. Environ. Sci.

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This study investigated the synergetic effect of the combined calcium peroxide (CaO2) and microwave (MW) treatment on waste active sludge dewatering properties and organic contaminants’ removal. The optimal sludge dewaterability was obtained at CaO2 (20 mg/gVSS)/MW (70°C), and the capillary suction time decreased by 52% compared with raw sludge. Further investigation indicated that total extracellular polymeric substances (EPS), tightly bound EPS, total protein, and protein present in tightly bound EPS were closely correlated with sludge dewaterability. Tryptophan, aromatic protein–like substances and humic acid–like substances were the key compounds that affect sludge dewaterability. The charge neutralization and bridge effect of cation ions were strengthened when combined with MW irradiation. In addition, it was revealed that MW facilitated CaO2 to produce more hydroxyl and superoxide anion radicals. This study confirmed CaO2/MW to be an effective way to improve sludge dewatering and remove organic pollutants from sludge.

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“…amount of 0.47 g H 2 O 2 /g of CaO 2 ) can participate in the Fenton reaction and generate HO• which are the dominant radicals for the pollutant degradation under aqueous conditions (Xue et al 2018a(Xue et al , 2018bAmina et al 2019;Sun et al 2019;Tang et al 2020). At the same time, hydroperoxyl radical (HO 2 •), superoxide radical (O 2 À •), singlet oxygen ( 1 O 2 ) and hydroperoxide anions (HO 2 À ) can be generated as well in CaO 2 -based Fenton system (Ma et al 2007;Zhang et al 2015aZhang et al , 2015bPan et al 2018;Zheng et al 2019).…”

mentioning

confidence: 99%

Degradation of BTEX in groundwater by nano-CaO2 particles activated with L-cysteine chelated Fe(III): enhancing or inhibiting hydroxyl radical generation

et al. 2021

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The simultaneous oxidation performance of benzene, toluene, ethylbenzene, and xylene (BTEX) by nanoscale calcium peroxide particles (nCaO2) activated with ferric ions (Fe(III)) and the mechanism of the enhancement of BTEX degradation by L-cysteine (L-cys) were investigated. The batch experimental results showed that the nCaO2/Fe(III)/L-cys process was effective in the destruction of BTEX in both ultrapure water and actual groundwater. A proper amount of L-cys could enhance BTEX degradation due to the promotion of Fe(II)/Fe(III) redox cycles by the participation of L-cys, but excessive presence of L-cys would cause inhibition. Adding 1.0 mM L-cys to the nCaO2/Fe(III) system, the concentration of Fe(II) increased to 1.15 mM instantly. Simultaneously, the yield of HO• produced by 1.0 mM L-cys-containing system was 0.066 mM at 180 min reaction, higher than that without L-cys (0.049 mM). When excess L-cys (5.0 mM) was added to the system, the amount of Fe(II) increased to 3.73 mM because excessive L-cys caused a large number of Fe(III) in the system to be reduced. However, the yield of HO• decreased to 0.043 mM since excessive Fe(II) could conversely scavenge HO• to produce Fe(III) again. EPR tests and quenching results indicated that HO• was the dominant reactive species in the nCaO2/Fe(III)/L-cys system. For the removal of BTEX, the optimal molar ratio of nCaO2/Fe(III)/L-cys was 10.5/20/1 based on the calculation by RSM. Finally, the BTEX destruction pathway was proposed according to the detected intermediates by LC-MS.

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Synergistic effects and mechanisms of hydroxyl radical-mediated oxidative degradation of sulfamethoxazole by Fe(II)-EDTA catalyzed calcium peroxide: Implications for remediation of antibiotic-contaminated water

Cited by 59 publications

References 45 publications

The performance of nCaO₂ for BTEX removal: Hydroxyl radical generation pattern and the influences of co‐existing environmental pollutants

The performance of nCaO₂ for BTEX removal: Hydroxyl radical generation pattern and the influences of co‐existing environmental pollutants

Synergetic Effect of Combined CaO2 and Microwave Treatment on Waste Active Sludge Dewaterability and Organic Contaminants’ Removal

Degradation of BTEX in groundwater by nano-CaO2 particles activated with L-cysteine chelated Fe(III): enhancing or inhibiting hydroxyl radical generation

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Synergistic effects and mechanisms of hydroxyl radical-mediated oxidative degradation of sulfamethoxazole by Fe(II)-EDTA catalyzed calcium peroxide: Implications for remediation of antibiotic-contaminated water

Cited by 59 publications

References 45 publications

The performance of nCaO2 for BTEX removal: Hydroxyl radical generation pattern and the influences of co‐existing environmental pollutants

The performance of nCaO2 for BTEX removal: Hydroxyl radical generation pattern and the influences of co‐existing environmental pollutants

Synergetic Effect of Combined CaO2 and Microwave Treatment on Waste Active Sludge Dewaterability and Organic Contaminants’ Removal

Degradation of BTEX in groundwater by nano-CaO2 particles activated with L-cysteine chelated Fe(III): enhancing or inhibiting hydroxyl radical generation

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Product

Resources

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The performance of nCaO₂ for BTEX removal: Hydroxyl radical generation pattern and the influences of co‐existing environmental pollutants

The performance of nCaO₂ for BTEX removal: Hydroxyl radical generation pattern and the influences of co‐existing environmental pollutants