Decomposition of linear dodecylbenzenesulfonate by simultaneous treatment with ozone and ultraviolet irradiation: rapid disappearance of formed mutagens.

The decomposition products and mutagenic activity in Salmonella typhimurium strains TA98, TA100 and TA104 in the presence and absence of S9 mix of linear dodecylbenzenesulfonate (DBS) in aqueous solution after ozone treatment alone or simultaneous treatment with ozone and ultraviolet (UV) irradiation (ozone/UV treatment) were investigated. The decomposed DBS solutions after these treatments for 4 h were mutagenic for strains TA98, TA100 and TA104 both with and without S9 mix, but this mutagenicity disappeared rapidly during further ozone/UV treatment. Mutagenicity of the decomposed solution of DBS, however, was not substantially decreased by treatment with ozone alone. Formaldehyde and glyoxal were identified as the decomposition products of DBS in water by high-performance liquid chromatography after treatment with 2,4-dinitrophenylhydrazine. Although these two compounds were mutagenic for strain TA104 both with and without S9 mix, they disappeared after further ozone/UV treatment but not after ozone treatment alone. These results indicate that ozone/UV treatment is an effective procedure for purifying drinking water.     

A chemiluminescence-based continuous flow aqueous ozone analyzer using photoactivated chromotropic acid

Ozone has become the oxidant of choice for water disinfection, especially in large water treatment facilities. This paper describes a fast and sensitive method for the determination of ozone content by reaction with photoactivated chromotropic acid (CA, 4,5-dihydroxynaphthalene-2,7-disulfonic acid), which results in intense chemiluminescence (CL). Freshly ozonated water from a recirculating ozonizer/reservoir is injected into a carrier stream of deionized water in the flow-injection mode. This flow mixes with a stream of photoactivated CA solution in a spiral cell placed directly on top of an inexpensive miniature (8 mm diameter active area) photomultiplier tube (PMT). Alkaline CA is photoactivated by passing it through a FEP-Teflon^® coil (residence time ∼ 50 s) wrapped around a 1 W UV lamp emitting at 254 nm; without photoactivation, the signal is ∼70-fold lower. The S/N = 3 limit of detection for aqueous ozone is 3 μg l⁻¹ and good response slope is obtained up to an ozone concentration of 1.4 mg l⁻¹, the highest that could be made in this study. The response obeyed a quadratic equation with r² = 0.9984. No interference from permanganate ion is observed. The proposed system was applied to the monitoring of ozonation status of a playa lake water that exhibited significant ozone demand.     

Formation of hydroxyl radicals by collapsing ozone microbubbles under strongly acidic conditions

Hydroxyl radicals are strong oxidants in aqueous solution, reacting rapidly with a wide range of dissolved compounds. In contrast, ozone is a highly selective oxidant. Understanding the process by which ozone is transformed into hydroxyl radicals is important in the treatment of wastewater and drinking water. We use electron spin-resonance spectroscopy to demonstrate that when microbubbles of ozone in strongly acidic aqueous solution collapse, the ozone progressively decomposes and large quantities of hydroxyl radicals are generated. Moreover, the degradation of polyvinyl alcohol, which is ozone resistant, was also observed during the collapse of the microbubbles. These findings indicate that ozone microbubbles are potentially useful in future water-treatment applications.     

Chemiluminescence in the ozonation of C60 aqueous dispersions

Two types of chemiluminescence (CL) arising upon ozonation of crystalline, amorphous, and molecular aqueous dispersions of C₆₀ prepared in different ways were discovered and studied. The weak long-wavelength CL-1 (λ_max > 650 nm) is due to thermocatalytic decomposition of ozone on the surface of fullerene micro- and nanoparticles. The bright short-wavelength CL-2 (λ_max = 570 nm) is caused by generation of electronically excited states of the products of C₆₀ oxidation with ozone. CL-1 appears upon ozonation of aqueous dispersions of C₆₀ consisting of surface-hydrated crystalline micro- and nanoparticles by low concentrations of ozone. CL-2 is exhibited upon ozonation of nano-sized C₆₀ aqueous dispersions and colloid solutions, which contain C₆₀ molecules surrounded by a strong aqueous shell and their associates, by higher concentrations of ozone. Owing to shielding by the hydration shell, C₆₀ fullerene in aqueous dispersions is much less reactive towards ozone and forms oxidation products of different composition as compared with C₆₀ in organic solvents.     

EPR and kinetic investigation of free cyanide oxidation by photocatalysis and ozonation

Oxidation of free cyanide in aqueous suspensions of three commercial TiO₂ specimens, with different anatase crystal size, has been carried out in a batch photoreactor by simultaneously applying ozonation and photocatalysis. Dissolved ozone participates both in homogeneous and catalytic reactions with cyanide; the extents of these two processes are comparable to that of the photodegradation with oxygen. The reactivity results are well described by the Langmuir-Hinshelwood kinetic model, providing the values of the kinetic and equilibrium adsorption constants for the catalytic and photocatalytic reactions contributing to cyanide oxidation. The cyanide concentration decreases faster with time for catalysts with increasing anatase crystal size, being more marked under UV irradiation. EPR studies on gaseous ozone adsorption on the three samples in the dark have shown stronger ozone interactions with Ti⁴⁺ and O^2? ions of the samples with largest anatase crystal size, leading to the formation of significant signals of Ti³⁺ and _s O^??O₂ radicals than with the anatase with the lowest crystal size, where ozone was mainly adsorbed on water molecular arrangements covering its surface. The hampering of the ozone and/or cyanide adsorption by the water molecular arrangements covering the surface of the catalyst with the lowest crystal size would justify the low cyanide degradation rate observed for this sample.     

Detection and Inhibition of an Organic Interference in the Indigo Method for Ozone

Abstract

Aqueous samples of organic solutes often exhibit a delayed reaction in the indigo test for dissolved ozone which is similar to the reaction of ozone itself. This phenomenon has made timing critical in aqueous ozone measurements and has been observed in both laboratory situations with high organic carbon:ozone ratios and in a potable water treatment plant with low organic carbon:ozone ratios. Organic hydroperoxides, singlet oxygen, and Fenton's reagent but not triplet oxygen, hydrogen peroxide, nor p-benzoquinone were found to interfere. Addition of phenolic antioxidants was found to inhibit the interference. These results extend the utility of the indigo method to solutions of high organic carbon concentration.     

Reagentless - Continuous Determination of Aqueous Ozone with Glass Tube Separator - Thin Film Semiconductor

Abstract

A method without any reagent for the determination of ultra-trace aqueous ozone utilizing a glass tube-separation process and a thin film semiconductor is proposed. The glass tube was used as the separator to transfer ozone from water into a gas phase. Ozone was transfered into clean air flowing in the tube and then was continuously monitored at the thin film semiconductor. Signals were proportional to concentration of aqueous ozone more than 5 ppb. Detection limit (S/N=3) was 0.02 ppt for aqueous ozone. The relative standard deviation (n=7) was 3.8 % at 7.6 ppb. The interference from hydrogen peroxide. monochloramine. and dichloramine were completely eliminated. The sensitivity of aqueous ozone was 45 times greater than that of hypochlorite.     

Kinetics of Ozone-Olefin Reactions in Aqueous Solutions

The kinetics of the reactions of ozone with 12 substituted olefins in aqueous solutions at 293 K are studied by the stopped-flow method. Second-order rate constants are determined for these reactions. The dependence of the reactivity of olefins in H₂O on their structure can be described by the Taft equation.     

Degradation of 4-Chlorophenol by High-Voltage Pulse Corona Discharges Combined with Ozone

Degradation of aqueous 250 mg/L 4-chlorophenol (4-CP) by high-voltage pulse corona discharges combined with ozone was investigated to gain insight into factors affecting enhancement of the combined system. High-voltage pulse corona discharges, ozonation, and a combination of the two were used to facilitate the degradation of aqueous 4-CP. Experimental results indicate that the treatment of 4-CP using a combination of high-voltage pulse corona discharges and ozonation within 30 min resulted in the almost degradation (96%) and a 51% reduction of the chemical oxygen demand (COD). This apparent synergistic effect may be attributed to the enhancement of ozone decomposition. The degradation of aqueous 4-CP by high-voltage pulse corona discharges combined with ozone was found to be affected by ozone concentration, substrate concentration, and interelectrode separations. The increase of ozone concentration leads to an increase of 4-CP conversion and COD removal. The conversion of 4-CP decreased with increase in 4-CP concentration and interelectrode separations.     

Model compound studies on the cleavage of glycosidic bonds by ozone in aqueous solution

Kinetic expressions have been developed for the initial phase of the reactions between ozone and methyl-β-D-glucopyranoside, a model compound for cellulose, in aqueous solutions at moderately low pH (pH 3) and ambient temperature. Ozone is reasonably stable under these conditions. The reaction is first order in the glucoside and ozone, second order overall. Kinetic and analytical data suggest that the glucoside is directly attacked by ozone to form polyoxide intermediates. The α-glucoside was more stable and was attacked by ozone exclusively at the acetal oxygen in the initial phase of the reaction. In contrast, the β-anomer was ozonized nearly twice as fast, and was attacked by ozone mainly at the C-H bond of the anomeric carbon. The latter reaction resulted in the formation of δ-gluconolactone, probably by way of a hydrotrioxide intermediate. The fragmentation of the intermediate could be assisted by properly oriented non-bonding orbitals of the two acetal oxygens. These stereoelectronic rules were previously proposed by Deslongchamp and coworkers on the ozonolysis of acetals in non-aqueous media. The activation energy for the reaction was 69.5 kJ/mole in both acetic and sulfuric acid solutions at pH 3. The presence of transition metal-ion, in particular Co(II) and Fe(II) ions, resulted in enhancement of both ozone decomposition and degradation of the glycoside, apparently caused by free radical reactions. In some cases, addition of acetic acid led to substantial suppression of the degradation of the glucoside.     

Oxidation of oleic acid and oleic acid/sodium chloride(aq) mixture droplets with ozone: changes of hygroscopicity and role of secondary reactions

The heterogeneous reactions of oleic acid (OL) and oleic-acid/sodium-chloride(aq) (OL/NaCl(aq)) mixture droplets with ozone are studied at two relative humidities (RH). The reactions were monitored concomitantly using attenuated total reflectance Fourier transform infrared spectroscopy (ATR-FT-IR) for the organic species and UV-vis spectrometry for the ozone concentration in order to investigate reaction rate discrepancies reported in literature as well as the oxidation mechanism. The less volatile products were identified and resolved by a Fourier transform ion cyclotron resonance mass spectrometer (FT-ICR-MS). This led to identification of 13 organic molecules (up to 45 carbons). Identified products were predominantly composed by nananoic acid and azelaic acid. Our results suggest that the propagation reaction is possibly initiated by a secondary reaction such as the stabilized Criegee intermediates reacting with oleic acid. For hygroscopic properties, the ATR-IR spectra at high RH (87 +/- 5%) showed that the hydrophobic oleic acid droplets can take up water slightly when exposed to ozone. For internally mixed OL/NaCl(aq) droplets, the hygroscopic properties of the droplets upon ozone exposure were found to be complex; hygroscopic properties or the growth factors of the droplets are altered as the oxidation products of oleic acid exist concurrently with NaCl(aq). Furthermore, the concentration of ozone was monitored to examine the kinetics of the oxidation reaction. The integrated ozone profile recorded by UV-vis spectrometry showed the consumed ozone represents only 30 +/- 2% of total oleic acid and hence confirmed the existence of secondary reactions. A kinetic model was used to simulate an ozone temporal profile that could only be described if the secondary reactions were included. The discrepancy of ozone uptake coefficients according to the OL and ozone measurements as well as their atmospheric implications are herein discussed.     

Theoretical analysis of physicochemical processes occurring during water treatment by ozone and ultraviolet radiation

The paper presents a kinetic model developed for ozone dissolution in water and taking into account convective and diffusion processes occurring in the vicinity of floating bubbles that contain an ozone-air mixture. It was shown that the gradient of ozone concentration in a convective-diffusion layer and consequently the rate of ozone transfer from bubbles to the solution depended on the rate of ozone decomposition both in its reaction with organic admixtures and in the conditions of exposure to ultraviolet radiation. The obtained kinetic curves of destruction of organic compounds and changes of ozone concentration in water and ozone-air mixture are compared with experimental data for humic acids. The paper also analyzes additional factors affecting the kinetics of ozone dissolution and the rate of resultant reactions.     

MnO2纳米溶胶-甲醛化学发光体系及其分析应用研究

Na2S2O3在中性水溶液中还原KMnO4可制备得到暗棕色的可溶性MnO2溶胶.所制备的MnO2溶胶透明、稳定,最大吸收波长位于357 nm处,平均粒径约40 nm.研究发现,所制备的MnO2纳米溶胶在酸性介质中与甲醛反应可产生弱的化学发光.考察了近30种药物分子在MnO2纳米溶胶-甲醛体系中的化学发光行为.结果表明,吩噻嗪类药物、氨基硫醇类药物等对该体系的化学发光信号具有显著的增强作用.据此,建立了利用这一化学发光体系测定五种吩噻嗪类药物和四种氨基硫醇类药物新的流动注射化学发光分析方法.所建立的方法被成功地用于片剂中奋乃静含量和猪饲料中盐酸氯丙嗪含量的测定.通过对化学发光光谱、荧光光谱、紫外可见吸收光谱等实验的研究,提出了可能的化学发光反应机理.所有反应的化学发光光谱的最大发射波长均位于630～640 nm间,与分析物的种类无关.当向反应体系中加入单线态氧清除剂叠氮化钠和三亚乙基二胺时,反应的化学发光强度被不同程度的抑制,这表明单线态氧可能是该化学发光反应的发光体.     

The structures of ozone and HOx radicals in aqueous solution from combined quantum/classical molecular dynamics simulations

Ozone in aqueous solution decomposes through a complex mechanism that involves initial reaction with a hydroxide ion followed by formation of a variety of oxidizing species such as HO, HO(2), and HO(3) radicals. Though a number of hydrogen-bonded complexes have been described in the gas phase, both theoretically and experimentally, the structures of ozone and HO(x) in liquid water remain uncertain. In this work, combined quantum/classical computer simulations of aqueous solutions of these species have been reported. The results show that ozone undergoes noticeable electron polarization but it does not participate in hydrogen bonds with liquid water. The main contribution of the solvation energy comes from dispersion forces. In contrast, HO(x) radicals form strong hydrogen bonds. They are better proton donors but weaker proton acceptors than water. Their electronic and geometrical structures are significantly modified by the solvent, especially in the case of HO(3). In all cases, fluctuations in amplitudes of electronic properties are considerable, suggesting that solvent effects might play a crucial role on oxidation mechanisms initiated by ozone in liquid water. These mechanisms are important in a broad range of domains, such as atmospheric processes, plant response to ambient ozone, and medical and industrial applications.     

Surface study of sintered alumina substrates using solution‐processed ZnO nanorods as a microscopic wettability indicator

Wettability and its distribution are crucial factors that indicate the surface conditions of substrates. We report a surface study of sintered alumina substrates using solution‐processed ZnO nanorods as a microscopic wettability indicator. The alumina substrates comprising of micrometer‐sized sintered grains were treated separately with ultraviolet/ozone (dry process) or ozone water (wet process), and their surface conditions were characterized by conventional surface analysis methods, such as water contact angle, X‐ray photoelectron spectroscopy and grazing angle attenuated total reflection Fourier transform infrared spectroscopy. The results showed that the alumina substrates treated with ultraviolet/ozone and ozone water had distinct clean surfaces compared to those without treatments, but no significant differences were noted between these two ozone‐based treatments. Then, as a wettability‐sensitive deposition technique, Pd‐catalyzed chemical deposition of ZnO nanorods was performed on the alumina substrates, which involved dip coating of Pd nanoparticles on the substrates in aqueous solutions, followed by the chemical solution growth of ZnO. Vertically aligned ZnO nanorods of ~85 nm in diameter were densely formed along a rough surface of the substrates. Morphological uniformity of the nanorods varied depending on the treatment condition; local surfaces with sufficient wettability provided uniform nanorods but those with insufficient wettability gave irregular nanorods, making the visualization of the microscopic surface wettability possible. Copyright © 2016 John Wiley & Sons, Ltd.     

Thermal-Plasma Jet Oxidation of Phenol in Aqueous Solutions

Chemical transformations occurring in distilled water and aqueous phenol solutions during treatment with an oxygen plasma jet were experimentally studied. The phenol conversion by plasma treatment of its aqueous solutions was found to be mainly due to reactions involving free radicals.     

Chemiluminescence in the interaction of organoboron peroxides with water

Chemiluminescence (CL) was detected in the reactions of organoboron peroxides, intermediate products of the oxidation of 9-borabicyclo[3.3.1]nonane (1) by water. Triplet cyclooctanone emitting at λ=420±15 nm is the emitter of CL. A mechanism for the formation of the excited ketone was suggested. The interaction of water with other components of the reaction mixture (the initial boron hydride I, end products of its oxidation, and a number of intermediate radicals) are not accompanied by CL. Translated fromIzvestiya Akademii Nauk. Seriya Khimicheskaya, No. 9, pp. 1692–1695, September, 1997.     

The sol-gel route of TEOS ozonation

A new solvent-less sol-gel route for silica film elaboration is presented. TEOS polymerization is induced by ozone bubbling through the initial sol composed of TEOS and water with the molar ratio R = [H₂O]/[Si]. Replacing ozone by pure oxygen allows for demonstrating the specific effects of ozone. With ozone bubbling, a comparison of certain film properties is made between R = 0 and R = 5 with HCl aqueous solution (pH = 1.8). The opto-geometrical properties of the films are studied by spectroscopic ellipsometry, the surface topography by atomic force microscopy and the chemical content by infra-red spectroscopy. The huge influence of the R value on sol and film properties is shown.     

Predicting optimal doses of ozone in the process of disinfecting drinking water based on a mathematical model

Statistical methods of miltifactorial experiment design have been applied to studying the disinfection of drinking water with ozone. Based on the mathematical model obtained, the optimal doses of ozone that are necessary for the ozone treatment of water of a known qualitative composition can be determined, and the efficiency of a chosen mode of ozone treatment can be predicted. It is demonstrated with river craft that the model can be used in the practice of water supply.     

Ozonocatalytic decomposition of glyoxal and glyoxylic and formic acids in the presence of iron(III) ions

Rate constants of reactions of ozone with glyoxal, glyoxylic and formic acid in aqueous solutions at pH 1.5 were determined. It was shown that iron(III) in the form of ions accelerates oxidation of glyoxal and glyoxylic acid, but does not influence reaction between ozone and formic acid. It was established that the catalyst acts effectively if its concentration is comparable to the concentration of the oxidized substrate, the optimal stoichiometric ratio (Fe³⁺/substrate) being close to 1/3. The catalytic reaction mechanism was studied using a competitive chelate ligand, oxalic acid. We concluded that the catalytic activity of iron(III) in the investigated reaction was due to its ability to form chelate complexes in which the substrate was more easily oxidized by molecular ozone.