UV-Catalyzed Persulfate Oxidation of an Anthraquinone Based Dye

Krawczyk, Kamil; Kudlek, Edyta; Silvestri, Daniele; Kukulski, Tomasz; Grűbel, Klaudiusz; Černík, Miroslav

doi:10.3390/catal10040456

Cited by 20 publications

(13 citation statements)

References 73 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This utility allows the creation of theoretical UV-Vis / infrared (etc.) spectra, facilitating the determination of reaction products without more sophisticated instruments such as mass spectrometry [28]. For example, the theoretical spectra of AB129 (studied here) was determined to be 594 nm, which matches the experimentally-obtained value (595 nm) almost exactly [28].…”

Section: •-supporting

confidence: 75%

“…). Our group has already experimentally determined that this is precisely what happens, i.e., the sulphate radical reacts selectively with the -NH-group [28]. The reason why the AB129 -NH 2 group is not the most reactive with the radicals, as indicated by ALIE analysis, could be trivially explained by the protonation of this group, which is possible in acidic and neutral pH values [33].…”

Section: •-mentioning

confidence: 95%

“…An extended investigation of our previous work [28] on the Acid Blue 129 (AB129) compound was presented herein. In this specific case, the HOMO and HOMO-1 of AB129 seem to be largely delocalized, making it more challenging to determine the reactive site available for free radicals (Fig.…”

Section: Regioselectivity and Products' Formationmentioning

confidence: 99%

“…Although when based only on HOMO distributions it is difficult to determine the reactive sites, it can be assumed that an electrophilic attack will probably occur somewhere within the vertical axis (Fig. 3) of the AB129 [28].…”

Section: Regioselectivity and Products' Formationmentioning

confidence: 99%

See 3 more Smart Citations

Do We Still Need a Laboratory to Study Advanced Oxidation Processes? A Review of the Modelling of Radical Reactions used for Water Treatment

Wacławek

2021

Ecological Chemistry and Engineering S

Self Cite

View full text Add to dashboard Cite

Environmental pollution due to humankind’s often irresponsible actions has become a serious concern in the last few decades. Numerous contaminants are anthropogenically produced and are being transformed in ecological systems, which creates pollutants with unknown chemical properties and toxicity. Such chemical pathways are usually examined in the laboratory, where hours are often needed to perform proper kinetic experiments and analytical procedures. Due to increased computing power, it becomes easier to use quantum chemistry computation approaches (QCC) for predicting reaction pathways, kinetics, and regioselectivity. This review paper presents QCC for describing the oxidative degradation of contaminants by advanced oxidation processes (AOP, i.e., techniques utilizing •OH for degradation of pollutants). Regioselectivity was discussed based on the Acid Blue 129 compound. Moreover, the forecasting of the mechanism of hydroxyl radical reaction with organic pollutants and the techniques of prediction of degradation kinetics was discussed. The reactions of •OH in various aqueous systems (explicit and implicit solvation) with water matrix constituents were reviewed. For example, possible singlet oxygen formation routes in the AOP systems were proposed. Furthermore, quantum chemical computation was shown to be an excellent tool for solving the controversies present in the field of environmental chemistry, such as the Fenton reaction debate [main species were determined to be: •OH < pH = 2.2 < oxoiron(IV)]. An ongoing discussion on such processes concerning similar reactions, e.g., associated with sulphate radical-based advanced oxidation processes (SR-AOP), could, in the future, be enriched by similar means. It can be concluded that, with the rapid growth of computational power, QCC can replace most of the experimental investigations related to the pollutant’s remediation in the future; at the same time, experiments could be pushed aside for quality assessment only.

show abstract

Section: •-supporting

confidence: 75%

Section: •-mentioning

confidence: 95%

Section: Regioselectivity and Products' Formationmentioning

confidence: 99%

Section: Regioselectivity and Products' Formationmentioning

confidence: 99%

See 2 more Smart Citations

Do We Still Need a Laboratory to Study Advanced Oxidation Processes? A Review of the Modelling of Radical Reactions used for Water Treatment

Wacławek

2021

Ecological Chemistry and Engineering S

Self Cite

View full text Add to dashboard Cite

show abstract

“…Advanced oxidation processes (AOPs) are considered as future alternative to traditional methods of removing organic pollutants: pharmaceutical active compounds [ 28 , 29 ], pesticides [ 30 , 31 ], dyes [ 32 , 33 ], volatile organic compounds [ 34 , 35 ], etc. The sustainability represents an important advantage of AOPs due to the use of light radiation as the main energy source to provide oxidative species responsible for pollutant mineralization [ 36 , 37 , 38 ].…”

Section: Introductionmentioning

confidence: 99%

Tandem Structures Semiconductors Based on TiO2_SnO2 and ZnO_SnO2 for Photocatalytic Organic Pollutant Removal

Eneşca

Isac

2021

Nanomaterials

View full text Add to dashboard Cite

The photocatalyst materials correlation with the radiation scenario and pollutant molecules can have a significant influence on the overall photocatalytic efficiency. This work aims to outline the significance of optimizing the components mass ratio into a tandem structure in order to increase the photocatalytic activity toward pollutant removal. ZnO_SnO2 and TiO2_SnO2 tandem structures were obtained by the doctor blade technique using different mass ratios between the components. The samples contain metal oxides with crystalline structures and the morphology is influenced by the main component. The photocatalytic activity was tested using three radiation scenarios (UV, UV-Vis, and Vis) and two pollutant molecules (tartrazine and acetamiprid). The results indicate that the photocatalytic activity of the tandem structures is influenced by the radiation wavelength and pollutant molecule. The TiO2_SnO2 exhibit 90% photocatalytic efficiency under UV radiation in the presence of tartrazine, while ZnO_SnO2 exhibit 73% photocatalytic efficiency in the same experimental conditions. The kinetic evaluation indicate that ZnO_SnO2 (2:1) have a higher reaction rate comparing with TiO2_SnO2 (1:2) under UV radiation in the presence of acetamiprid.

show abstract

UV‐C Activation of Peroxides for Bisphenol A Removal from a Real Water Sample

Öztürk

Ucun

Arslan-Alaton

2021

CLEAN Soil Air Water

View full text Add to dashboard Cite

The peroxides peracetic acid (PAA) and percarbonate (PC) are applied for UV‐C‐based advanced oxidation of the endocrine disrupting micropollutant bisphenol A (BPA; 2 mg L−1 = 8.76 µm) in pure and tap water. Their performance is compared with the more conventional hydrogen peroxide (HP)‐ and persulfate (PS)‐activated UV‐C treatments. Acidic and neutral pH values, 4 and 7, result in faster BPA removals with HP‐ and PS‐activated UV‐C treatments, respectively, whereas higher BPA removal rates are obtained at acidic and alkaline pH values, 4 and 10, with the PC/UV‐C and PAA/UV‐C treatments, respectively. Increasing the peroxide concentrations enhances BPA removals with the exception of PC/UV‐C treatment where an asymptotic removal rate is ultimately reached due to the inhibitory effect of increasing alkalinity. The order of total organic carbon (TOC) removal for the BPA‐spiked tap water (TW) (TOC ≈ 5 mg L−1 with added BPA) is TOCPAA/UV‐C (16%) < TOCPS/UV‐C (24%) < TOCHP/UV‐C (27%) < TOCPC/UV‐C (35%). BPA removal is most negatively affected for the HP/UV‐C processes, whereas the PC/UV‐C process outperformed the other peroxide/UV‐C treatments in terms of TOC removal due to the differences in the reactivity/selectivity of the in situ formed free radical types that may become important when working with real water. The originally low toxicity toward the marine photobacterium Vibrio fischeri and the freshwater crustacean Daphnia magna fluctuated during photochemical treatments.

show abstract

UV-Catalyzed Persulfate Oxidation of an Anthraquinone Based Dye

Cited by 20 publications

References 73 publications

Do We Still Need a Laboratory to Study Advanced Oxidation Processes? A Review of the Modelling of Radical Reactions used for Water Treatment

Do We Still Need a Laboratory to Study Advanced Oxidation Processes? A Review of the Modelling of Radical Reactions used for Water Treatment

Tandem Structures Semiconductors Based on TiO2_SnO2 and ZnO_SnO2 for Photocatalytic Organic Pollutant Removal

UV‐C Activation of Peroxides for Bisphenol A Removal from a Real Water Sample

Contact Info

Product

Resources

About