Review on discharge Plasma for water treatment: mechanism, reactor geometries, active species and combined processes

Zeghioud, Hichem; Nguyen-Tri, Phuong; Khezami, Lotfi; Amrane, Abdeltif; Assadi, Aymen Amine

doi:10.1016/j.jwpe.2020.101664

Cited by 162 publications

(73 citation statements)

References 142 publications

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“…e decrease in the removal efficiency with the increase in the electrode distances can be explained as follows: with the increase in the interelectrode distance, the possibility of electrical discharge is reduced, leading to the decrease in the electric-field energy generated to create the plasma and subsequently low production of oxidants during the plasma process. ese results are consistent with those reported in some previous studies [17,38,39]; these studies indicated that a suitable two-electrode spacing from 8 to 20 mm not only improves the formation of oxidants but also accelerates the temperature during the plasma process, leading to the mitigation of a high concentration of pollutants. In the case of COD and ammonia, with the increase in the interelectrode distance, even the removal efficiency decreased, albeit with an insignificant decrease.…”

Section: Effect Of the Initial Phsupporting

confidence: 92%

“…Recently, the application of cold plasma-one of the AOPs-has attracted considerable attention for wastewater treatment due to its efficiency, less chemical requirements, and low sludge production [17]. Cold plasma has been employed for the degradation of recalcitrant pollutants in the wastewater generated from pesticide production [18], a slaughterhouse [19], textiles [20], and pharmaceuticals [21][22][23][24].…”

Section: Introductionmentioning

confidence: 99%

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Removal of Antibiotics from Real Hospital Wastewater by Cold Plasma Technique

Nguyen

Tran

et al. 2021

Journal of Chemistry

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Hospital wastewater contains a complex mixture of bioactive substances and microorganisms that are deleterious to humans and aquatic animals. In this study, four antibiotics, namely, ofloxacin, ciprofloxacin, cefuroxime, and amoxicillin, respectively, from the wastewater of seven hospitals in Ho Chi Minh City, Vietnam, were monitored. The results revealed that the wastewater from these hospitals is contaminated with at least one of the antibiotics. In addition, the degradation capacity of the antibiotics by the wastewater treatment plant at one of the hospitals by the cold plasma technique was investigated. Furthermore, effects of the variation in pH, interelectrode distance, applied voltage, and reaction time on the removal efficiency were investigated in terms of the reduction in antibiotics concentration, COD, and ammonia. Ciprofloxacin, cefuroxime, COD, and ammonia were almost eliminated, while ofloxacin and amoxicillin were reduced by more than 72% under optimum conditions (initial pH of 10, reaction time of 15 min, applied voltage of 30 kV, and interelectrode distance of 10 mm). All of these factors affected the removal efficiency. The removal efficiency was most robust in the first 5 min, and it increased with the increase in the reaction time. However, the removal efficiency tended to saturate over time, while it decreased with the increase in the reaction time. With an applied voltage of 30 kV onwards, the removal efficiency was not significantly different. Most of the pollutants were predominately eliminated under slightly alkaline conditions (pH of ∼10). In addition, primary oxidants in the aqueous phase, such as O3, H2O2, and ⋅OH, were generated. Besides, the obtained results also revealed that the decomposition of ciprofloxacin and cefuroxime follows the first-order reaction kinetics; meanwhile, the third-order reaction kinetics was most likely for the decomposition of ofloxacin and amoxicillin.

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Section: Effect Of the Initial Phsupporting

confidence: 92%

Section: Introductionmentioning

confidence: 99%

Removal of Antibiotics from Real Hospital Wastewater by Cold Plasma Technique

Nguyen

Tran

et al. 2021

Journal of Chemistry

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“…[2] One process that has been extensively investigated since then is the oxidation of organic compounds by nonthermal plasma in air or in oxygen-containing gases, with fundamental research in this area being motivated by the interest in developing novel advanced oxidation processes (AOPs) to treat polluted air [3] and water. [4] These studies have provided a deep insight into the discharge-generated reactive species (electrons, molecular excited states, atoms, radicals, ions [5,6] ), which are responsible for the initial attack on the organic pollutants, and into the resulting degradation intermediates and final products. As the aim of such treatments is the complete mineralization of all organic carbon into CO 2 , [7] it is not surprising that discharges and conditions are optimized, so as to achieve as harsh an environment as possible in terms of type and concentration of strong oxidizing reactive species.…”

mentioning

confidence: 99%

Nitrogen‐containing organic products from the treatment of liquid toluene with plasma‐activated N₂ gas

Hosseini

Saleem

Marotta

et al. 2021

Plasma Processes & Polymers

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This proof-of-principle study explored the possibility to form nitrogen-containing organic products via exposure of liquid toluene to a flow of molecular nitrogen, at room temperature and atmospheric pressure, activated by dielectric barrier discharges. N-containing organic compounds indeed formed under these conditions, including benzonitrile, a high-value chemical that is industrially synthesized from toluene under demanding conditions. Toluene-derived higher hydrocarbons, as well as oxygen-containing derivatives, were also detected, the latter due to efficient reactions of residual oxygen in the system. A mechanistic description of the observed chemistry is provided, together with guidelines for increasing the selectivity for C-N forming reactions and the development of this approach into a novel synthetic approach for high-value organic N-containing chemicals.

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“…The authors conveyed that the chemical cocktail consisting of UV radiation and diverse reactive species render non-thermal plasma an adequate treatment method that is economically feasible and has been applied in various areas of environmental remediation. NTP used in combination with adsorbents, catalysts, electrolysis, biodegradation, ultrasonication, ozonisation and ultrafiltration processes could be promising methods for the removal of persistent pollutants and microorganisms from polluted waters, and this was also endorsed by Zeghioud et al [ 134 ].…”

Section: Overview Of the Plasma Processmentioning

confidence: 99%

“…The TOC and COD removal efficiencies 43.0% and 73.7%, respectively demonstrated that the resultant degradation metabolites of OTC were less harmful, and the proposed elimination mechanism pathways demonstrated that OTC was degraded to H 2 O, CO 2, and simpler entities. Complementary investigations on the removal of pharmaceutical residues in water by DBD technologies have been reported [ 134 , 151 , 152 ].…”

Section: Overview Of the Plasma Processmentioning

confidence: 99%

Removal of Pharmaceutical Residues from Water and Wastewater Using Dielectric Barrier Discharge Methods—A Review

Mouele

Tijani

Badmus

et al. 2021

IJERPH

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Persistent pharmaceutical pollutants (PPPs) have been identified as potential endocrine disruptors that mimic growth hormones when consumed at nanogram per litre to microgram per litre concentrations. Their occurrence in potable water remains a great threat to human health. Different conventional technologies developed for their removal from wastewater have failed to achieve complete mineralisation. Advanced oxidation technologies such as dielectric barrier discharges (DBDs) based on free radical mechanisms have been identified to completely decompose PPPs. Due to the existence of pharmaceuticals as mixtures in wastewater and the recalcitrance of their degradation intermediate by-products, no single advanced oxidation technology has been able to eliminate pharmaceutical xenobiotics. This review paper provides an update on the sources, occurrence, and types of pharmaceuticals in wastewater by emphasising different DBD configurations previously and currently utilised for pharmaceuticals degradation under different experimental conditions. The performance of the DBD geometries was evaluated considering various factors including treatment time, initial concentration, half-life time, degradation efficiency and the energy yield (G50) required to degrade half of the pollutant concentration. The review showed that the efficacy of the DBD systems on the removal of pharmaceutical compounds depends not only on these parameters but also on the nature/type of the pollutant.

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Review on discharge Plasma for water treatment: mechanism, reactor geometries, active species and combined processes

Cited by 162 publications

References 142 publications

Removal of Antibiotics from Real Hospital Wastewater by Cold Plasma Technique

Removal of Antibiotics from Real Hospital Wastewater by Cold Plasma Technique

Nitrogen‐containing organic products from the treatment of liquid toluene with plasma‐activated N₂ gas

Removal of Pharmaceutical Residues from Water and Wastewater Using Dielectric Barrier Discharge Methods—A Review

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Review on discharge Plasma for water treatment: mechanism, reactor geometries, active species and combined processes

Cited by 162 publications

References 142 publications

Removal of Antibiotics from Real Hospital Wastewater by Cold Plasma Technique

Removal of Antibiotics from Real Hospital Wastewater by Cold Plasma Technique

Nitrogen‐containing organic products from the treatment of liquid toluene with plasma‐activated N2 gas

Removal of Pharmaceutical Residues from Water and Wastewater Using Dielectric Barrier Discharge Methods—A Review

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Nitrogen‐containing organic products from the treatment of liquid toluene with plasma‐activated N₂ gas