Occurrence and transformation of phenoxy acids in aquatic environment and photochemical methods of their removal: a review

Muszyński, Paweł; Brodowska, Marzena S.; Paszko, Tadeusz

doi:10.1007/s11356-019-06510-2

Cited by 27 publications

(13 citation statements)

References 139 publications

(157 reference statements)

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“…Evidence of the possible occurrence of photonitration processes in the natural environment has been obtained in the case of natural surface waters, although biological nitration pathways cannot be ruled out. In particular, it appears that the environmental conditions of the Rhône delta lagoons (shallow and sunlit waters, elevated concentrations of nitrate and nitrite) are particularly favourable to the transformation of phenolic compounds, arising from the environmental dissipation of phenoxyacid herbicides, into the corresponding nitroderivatives [31,[65][66][67][68][69] It should be remarked that natural waters are indeed much more complex compared to simplified laboratory systems, thus interaction between different components is highly likely. For instance, nitrate and nitrite occur together in the Rhône-delta lagoon water, and the processes they may trigger differ from the mere sum of the separate photoreactions.…”

Section: Possible Occurrence Of Photonitration In Natural Watersmentioning

confidence: 99%

“…Molecules 2021,26, x FOR PEERREVIEW 13 tration pathways cannot be ruled out. In particular, it appears that the environme conditions of the Rhône delta lagoons (shallow and sunlit waters, elevated concentrat of nitrate and nitrite) are particularly favourable to the transformation of phenolic c pounds, arising from the environmental dissipation of phenoxyacid herbicides, into corresponding nitroderivatives[31,[65][66][67][68][69]:…”

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confidence: 99%

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Secondary Formation of Aromatic Nitroderivatives of Environmental Concern: Photonitration Processes Triggered by the Photolysis of Nitrate and Nitrite Ions in Aqueous Solution

Marussi

Vione

2021

Molecules

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Aromatic nitroderivatives are compounds of considerable environmental concern, because some of them are phytotoxic (especially the nitrophenols, and particularly 2,4-dinitrophenol), others are mutagenic and potentially carcinogenic (e.g., the nitroderivatives of polycyclic aromatic hydrocarbons, such as 1-nitropyrene), and all of them absorb sunlight as components of the brown carbon. The latter has the potential to affect the climatic feedback of atmospheric aerosols. Most nitroderivatives are secondarily formed in the environment and, among their possible formation processes, photonitration upon irradiation of nitrate or nitrite is an important pathway that has periodically gained considerable attention. However, photonitration triggered by nitrate and nitrite is a very complex process, because the two ionic species under irradiation produce a wide range of nitrating agents (such as •NO2, HNO2, HOONO, and H2OONO+), which are affected by pH and the presence of organic compounds and, in turn, deeply affect the nitration of aromatic precursors. Moreover, aromatic substrates can highly differ in their reactivity towards the various photogenerated species, thereby providing different behaviours towards photonitration. Despite the high complexity, it is possible to rationalise the different photonitration pathways in a coherent framework. In this context, this review paper has the goal of providing the reader with a guide on what to expect from the photonitration process under different conditions, how to study it, and how to determine which pathway(s) are prevailing in the formation of the observed nitroderivatives.

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Section: Possible Occurrence Of Photonitration In Natural Watersmentioning

confidence: 99%

mentioning

confidence: 99%

Secondary Formation of Aromatic Nitroderivatives of Environmental Concern: Photonitration Processes Triggered by the Photolysis of Nitrate and Nitrite Ions in Aqueous Solution

Marussi

Vione

2021

Molecules

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“…The exact mass of the component corresponding to the HPLC peak with RRT = 1.35 (t R = 6.80 min) is 244.01 (50.54%). Based on the negative ion mode mass spectrum ( Figure 14) and the previously published path of oxidation of phenoxyacetic acids with hydrogen peroxide [38] , the structure of the new compound can be considered to be 8 (C 11 H 10 O 2 Cl 2 ; [M 8 − H + ] − = 242.97) ( Figure 15). The other proposed structure corresponding to the HPLC peak with RRT = 0.46 (t R = 2.30 min) can be considered to the 9 epoxide ( Figure 15).…”

Section: Forced Degradation Studiesmentioning

confidence: 99%

Development and validation of a stability-indicating HPLC assay method for determination of ethacrynic acid in solution formulation. HPLC-MS identification of hydrolytic and oxidative degradation products

Kuźma

Murányi

Mayer

et al. 2020

J Pharm Biopharm Res

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An isocratic stability-indicating HPLC assay method was developed to quantitate ethacrynic acid in solution formulations. Utilizing the method, the main thermal, hydrolytic, and one of the oxidative degradation products could be separated. The structure of the separated degradation products was confirmed by negative ion-mode HPLC-MS. The hydrolytic results confirmed the previously reported sequence of the formation of the dimeric Michael adduct. At the lower temperature, hydrogen peroxide can react with ethacrynic acid to form the epoxide derivative (7). At the higher temperature, several other oxidation products were also formed. The validated analytical method can be used to quantitate ethacrynic acid in a solution formulation in the 0.5-500 µg/mL concentration range.

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“…Among the many sources of water pollution, wastewater from the printing and dyeing industry is a major concern. The decolorization and degradation of most chromophores in dyes are difficult because of their stable aromatic structures, leading to prolonged toxic effects and environmental hazards [ 4 , 5 , 6 ]. Furthermore, dyes can absorb sunlight and reduce water clarity, preventing photosynthesis in aquatic plants, decreasing dissolved oxygen in water, affecting microbial diversity, and disrupting the self-purification capacity of water [ 7 ].…”

Section: Introductionmentioning

confidence: 99%

Microwave-Assisted Synthesis of Chalcopyrite/Silver Phosphate Composites with Enhanced Degradation of Rhodamine B under Photo-Fenton Process

Chang

Wen

et al. 2020

Nanomaterials

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A new composite by coupling chalcopyrite (CuFeS2) with silver phosphate (Ag3PO4) (CuFeS2/Ag3PO4) was proposed by using a cyclic microwave heating method. The prepared composites were characterized by scanning and transmission electron microscopy and X-ray diffraction, Fourier-transform infrared, UV–Vis diffuse reflectance spectroscopy, and X-ray photoelectron spectroscopy. Under optimum conditions and 2.5 W irradiation (wavelength length > 420 nm, power density = 0.38 Wcm−2), 96% of rhodamine B (RhB) was degraded by CuFeS2/Ag3PO4 within a 1 min photo-Fenton reaction, better than the performance of Ag3PO4 (25% degradation within 10 min), CuFeS2 (87.7% degradation within 1 min), and mechanically mixed CuFeS2/Ag3PO4 catalyst. RhB degradation mainly depended on the amount of hydroxyl radicals generated from the Fenton reaction. The degradation mechanism of CuFeS2/Ag3PO4 from the photo-Fenton reaction was deduced using a free radical trapping experiment, the chemical reaction of coumarin, and photocurrent and luminescence response. The incorporation of CuFeS2 in Ag3PO4 enhanced the charge separation of Ag3PO4 and reduced Ag3PO4 photocorrosion as the photogenerated electrons on Ag3PO4 were transferred to regenerate Cu2+/Fe3+ ions produced from the Fenton reaction to Cu+/Fe2+ ions, thus simultaneously maintaining the CuFeS2 intact. This demonstrates the synergistic effect on material stability. However, hydroxyl radicals were produced by both the photogenerated holes of Ag3PO4 and the Fenton reaction of CuFeS2 as another synergistic effect in catalysis. Notably, the degradation performance and the reusability of CuFeS2/Ag3PO4 were promoted. The practical applications of this new material were demonstrated from the effective performance of CuFeS2/Ag3PO4 composites in degrading various dyestuffs (90–98.9% degradation within 10 min) and dyes in environmental water samples (tap water, river water, pond water, seawater, treated wastewater) through enhanced the Fenton reaction under sunlight irradiation.

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Occurrence and transformation of phenoxy acids in aquatic environment and photochemical methods of their removal: a review

Cited by 27 publications

References 139 publications

Secondary Formation of Aromatic Nitroderivatives of Environmental Concern: Photonitration Processes Triggered by the Photolysis of Nitrate and Nitrite Ions in Aqueous Solution

Secondary Formation of Aromatic Nitroderivatives of Environmental Concern: Photonitration Processes Triggered by the Photolysis of Nitrate and Nitrite Ions in Aqueous Solution

Development and validation of a stability-indicating HPLC assay method for determination of ethacrynic acid in solution formulation. HPLC-MS identification of hydrolytic and oxidative degradation products

Microwave-Assisted Synthesis of Chalcopyrite/Silver Phosphate Composites with Enhanced Degradation of Rhodamine B under Photo-Fenton Process

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