Anodic Oxidation of the Insecticide Imidacloprid on Mixed Metal Oxide (RuO2-TiO2and IrO2-RuO2-TiO2) Anodes

Silva, Larissa M.; Santos, Ruilianne P. A. dos; Morais, Catarina M.; Vasconcelos, C.L. de; Martínez‐Huitle, Carlos A.; Castro, Sonia

doi:10.1149/2.1871713jes

Cited by 23 publications

(12 citation statements)

References 57 publications

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“…The primary oxidation mechanisms during EAOPs are direct electron transfer and reaction with OH • . Past research has shown that electrochemical oxidation could completely mineralize ATZ , and imidacloprid (a similar neonicotinoid insecticide to CDN). , However, these studies required extended reaction times and/or elevated temperatures (e.g., 60 °C) to achieve mineralization.…”

Section: Resultsmentioning

confidence: 99%

Electrochemical Oxidation of Atrazine and Clothianidin on Bi-doped SnO₂–Ti_nO_2n–1 Electrocatalytic Reactive Electrochemical Membranes

Gayen

Chen

Abiade

et al. 2018

Environ. Sci. Technol.

138

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This research focused on improving mineralization rates during the advanced electrochemical oxidation treatment of agricultural water contaminants. For the first time, bismuth-doped tin oxide (BDTO) catalysts were deposited on Magneĺi phase (Ti n O 2n−1 , n = 4−6) reactive electrochemical membranes (REMs). Terephthalic acid (TA) was used as a OH • probe, whereas atrazine (ATZ) and clothianidin (CDN) were chosen as model agricultural water contaminants. The BDTO-deposited REMs (REM/BDTO) showed higher compound removal than the REM, due to enhanced OH • production. At 3.5 V/SHE, complete mineralization of TA, ATZ, and CDN was achieved for the REM/BDTO upon a single pass in the reactor (residence time ∼3.6 s). Energy consumption for REM/BDTO was as much as 31-fold lower than the REM, with minimal values per log removal of <0.53 kWh m −3 for TA (3.5 V/SHE), <0.42 kWh m −3 for ATZ (3.0 V/SHE), and 0.83 kWh m −3 for CDN (3.0 V/ SHE). Density functional theory simulations provided potential dependent activation energy profiles for ATZ, CDN, and various oxidation products. Efficient mass transfer and a reaction mechanism involving direct electron transfer and reaction with OH • were responsible for the rapid and complete mineralization of ATZ and CDN at very short residence times.

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Section: Resultsmentioning

confidence: 99%

Electrochemical Oxidation of Atrazine and Clothianidin on Bi-doped SnO₂–Ti_nO_2n–1 Electrocatalytic Reactive Electrochemical Membranes

Gayen

Chen

Abiade

et al. 2018

Environ. Sci. Technol.

138

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“…Among these new treatment technologies, electrochemical processes have been widely studied, mainly due to their high efficiency in the degradation of recalcitrant compounds [3,[5][6][7]. Silva et al [8] achieved complete oxidation of the insecticide imidacloprid, at a concentration of approximately 25 mg L −1 , by applying an anodic oxidation (AO) process with mixed metal oxide anodes. Successful degradation of the herbicides monolinuron, paraquat, and clopyralid and of the pesticide profenofos, at concentrations ranging 10-100 mg L −1 , by electro-Fenton (EF), was also reported [2,[9][10][11].…”

Section: Introductionmentioning

confidence: 99%

Methiocarb Degradation by Electro-Fenton: Ecotoxicological Evaluation

et al. 2020

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This paper studies the degradation of methiocarb, a highly hazardous pesticide found in waters and wastewaters, through an electro-Fenton process, using a boron-doped diamond anode and a carbon felt cathode; and evaluates its potential to reduce toxicity towards the model organism Daphnia magna. The influence of applied current density and type and concentration of added iron source, Fe2(SO4)3·5H2O or FeCl3·6H2O, is assessed in the degradation experiments of methiocarb aqueous solutions. The experimental results show that electro-Fenton can be successfully used to degrade methiocarb and to reduce its high toxicity towards D. magna. Total methiocarb removal is achieved at the applied electric charge of 90 C, and a 450× reduction in the acute toxicity towards D. magna, on average, from approximately 900 toxic units to 2 toxic units, is observed at the end of the experiments. No significant differences are found between the two iron sources studied. At the lowest applied anodic current density, 12.5 A m−2, an increase in iron concentration led to lower methiocarb removal rates, but the opposite is found at the highest applied current densities. The highest organic carbon removal is obtained at the lowest applied current density and added iron concentration.

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“…This is an important economical aspect given the cost of ruthenium-based compounds. Due to these salient features, the conducting RuO 2 -TiO 2 heterostructure is explored in the development of supercapacitors [23], electrode for chlorine electrogeneration [28] as well as pigments, fillers, electro-resistor films for electrodes, or dielectric device catalyst supports [29,30].…”

Section: Introductionmentioning

confidence: 99%

Polyaniline-Grafted RuO2-TiO2 Heterostructure for the Catalysed Degradation of Methyl Orange in Darkness

et al. 2019

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Massive industrial and agricultural developments have led to adverse effects of environmental pollution resisting conventional treatment processes. The issue can be addressed via heterogeneous photocatalysis as witnessed recently. Herein, we have developed novel metal/semi-conductor/polymer nanocomposite for the catalyzed degradation and mineralization of model organic dye pollutants in darkness. RuO2-TiO2 mixed oxide nanoparticles (NPs) were modified with diphenyl amino (DPA) groups from the 4-diphenylamine diazonium salt precursor. The latter was reduced with ascorbic acid to provide radicals that modified the NPs and further served for in situ synthesis of polyaniline (PANI) that resulted in RuO2/TiO2-DPA-PANI nanocomposite catalyst. Excellent adhesion of PANI to RuO2/TiO2-DPA was noted but not in the case of the bare mixed oxide. This stresses the central role of diazonium compounds to tether PANI to the underlying mixed oxide. RuO2-TiO2/DPA/PANI nanocomposite revealed superior catalytic properties in the degradation of Methyl Orange (MO) compared to RuO2-TiO2/PANI and RuO2-TiO2. Interestingly, it is active even in the darkness due to high PANI mass loading. In addition, PANI constitutes a protective layer of RuO2-TiO2 NPs that permitted us to reuse the RuO2-TiO2/DPA/PANI nanocomposite nine times, whereas RuO2-TiO2/PANI and RuO2-TiO2 were reused seven and five times only, respectively. The electronic displacements at the interface of the heterojunction metal/semi-conductor under visible light and the synergistic effects between PANI and RuO2 result in the separation of electron-hole pairs and a reduction of its recombination rate as well as a significant catalytic activity of RuO2-TiO2/DPA/PANI under simulated sunlight and in the dark, respectively.

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Anodic Oxidation of the Insecticide Imidacloprid on Mixed Metal Oxide (RuO₂-TiO₂and IrO₂-RuO₂-TiO₂) Anodes

Cited by 23 publications

References 57 publications

Electrochemical Oxidation of Atrazine and Clothianidin on Bi-doped SnO₂–Ti_nO_2n–1 Electrocatalytic Reactive Electrochemical Membranes

Electrochemical Oxidation of Atrazine and Clothianidin on Bi-doped SnO₂–Ti_nO_2n–1 Electrocatalytic Reactive Electrochemical Membranes

Methiocarb Degradation by Electro-Fenton: Ecotoxicological Evaluation

Polyaniline-Grafted RuO2-TiO2 Heterostructure for the Catalysed Degradation of Methyl Orange in Darkness

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Anodic Oxidation of the Insecticide Imidacloprid on Mixed Metal Oxide (RuO2-TiO2and IrO2-RuO2-TiO2) Anodes

Cited by 23 publications

References 57 publications

Electrochemical Oxidation of Atrazine and Clothianidin on Bi-doped SnO2–TinO2n–1 Electrocatalytic Reactive Electrochemical Membranes

Electrochemical Oxidation of Atrazine and Clothianidin on Bi-doped SnO2–TinO2n–1 Electrocatalytic Reactive Electrochemical Membranes

Methiocarb Degradation by Electro-Fenton: Ecotoxicological Evaluation

Polyaniline-Grafted RuO2-TiO2 Heterostructure for the Catalysed Degradation of Methyl Orange in Darkness

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Product

Resources

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Anodic Oxidation of the Insecticide Imidacloprid on Mixed Metal Oxide (RuO₂-TiO₂and IrO₂-RuO₂-TiO₂) Anodes

Electrochemical Oxidation of Atrazine and Clothianidin on Bi-doped SnO₂–Ti_nO_2n–1 Electrocatalytic Reactive Electrochemical Membranes

Electrochemical Oxidation of Atrazine and Clothianidin on Bi-doped SnO₂–Ti_nO_2n–1 Electrocatalytic Reactive Electrochemical Membranes