In just over a decade, Francois Ozon has earned an international reputation as a successful and provocative filmmaker. A student of Eric Rohmer and Jean Douchet at the prestigious Femis, Ozon made a ...number of critically acclaimed shorts in the 1990s and released his first feature film Sitcom in 1998. Two additional shorts and eleven feature films have followed, including international successes 8 femmes and Swimming Pool and more recent releases such as Angel, Ricky, and Le refuge. Ozon's originality lies in his filmmaking style, which draws on familiar cinematic traditions (the crime thriller, the musical, the psychological drama, the comedy, the period piece) but simultaneously mixes these recognizable genres and renders them unfamiliar. Despite tremendous diversity in cinematic choices, Ozon's oeuvre is surprisingly consistent in its desire to blur the traditional frontiers between the masculine and the feminine, gay and straight, reality and fantasy, auteur and commercial cinema. _x000B__x000B_Thibaut Schilt provides an overview of Francois Ozon's career to date, highlighting the director's unrestrained, voracious cinephilia, his recurrent collaborations with women screenwriters and actresses, and the trademarks of his cinema including music, dance, and the clothes that accompany these now typically Ozonian episodes. Schilt contextualizes Ozon's filmmaking within the larger fields of French filmmaking and international queer cinema, and he discusses several major themes running through Ozon's work, including obsessions with inadequate fathers, various types of mourning, and a recurring taste for "the foreign." The volume also includes an insightful interview with the director.
Benefitting from the continuous innovations in semiconductor materials and device fabricating techniques, ultraviolet (UV) photodetectors have been successfully used in advanced communications, flame ...detection, air purification, ozone sensing and leak detection, among others, in the past few decades. Nowadays, nanoscience, nanofabrication technologies and versatile materials have sparked a new vision of UV photodetectors, which move toward higher precision, lower energy consumption and greater miniaturization. This paper is thus mainly focused on the perspective of molding devices through exploring new materials and novel architectures inspired by state-of-the-art UV photodetectors, predicting the direction of next-generation photodetectors. It is expected that new concept UV photodetectors with smart, intelligent and multifunctional design will benefit daily life and the well-being of society in the near future.
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•Hydroxyl and sulfate radical related AOPs at basic pH were reviewed.•Studies of model and real wastewater were discussed, with emphasis to real effluents.•The studies of degradation ...pathways and by-products were reviewed.•Economical evaluation of the processes was discussed.•Good practice for planning the research is described.
Advanced oxidation processes (AOPs) have been used as an alternative and effective option for treatment of industrial wastewater, especially in the case of the non-biodegradable compounds. Despite of several well developed AOPs, the majority of them are effective only at acidic or neutral pH, namely Fenton related processes, making the list of available effective advanced oxidation technologies strongly limited. In many cases, industrial effluents are formed at basic pH conditions. This paper reviews the state of the art of AOPs exclusively at alkaline pH, the type of compounds and effluents effectively degraded, the influence of pH on the efficiency of the processes, economic evaluation and degradation pathways. Spent caustic, polyester and acetate fiber dye effluents, phenol, acidic and sulfur based compounds, specific dyes and drugs were effectively degraded at basic pH. Factors like point of zero charge, pKa of the compounds, amount of radicals produced and activation of the oxidants are crucial factors that affect the treatment efficiency of AOPs at basic pH. H2O2 and O3 were the cheapest processes while peroxone was the most expensive. The treatment costs were in general too expensive and unrealistic using the methodology used in the literature. The alternative methodology proposed in this paper reduced the treatment costs by three orders of magnitude to values more realistic and economical feasible. Literature regarding treatment of real effluents using AOPs at basic pH is scarce and further research is needed to perform complete analysis. It is important to present some alternatives regarding the treatment of alkaline effluents without pH correction using such technologies.
Vehicle emissions contribute to fine particulate matter (PM2.5) and tropospheric ozone air pollution, affecting human health, crop yields and climate worldwide. On-road diesel vehicles produce ...approximately 20 per cent of global anthropogenic emissions of nitrogen oxides (NOx), which are key PM2.5 and ozone precursors. Regulated NOx emission limits in leading markets have been progressively tightened, but current diesel vehicles emit far more NOx under real-world operating conditions than during laboratory certification testing. Here we show that across 11 markets, representing approximately 80 per cent of global diesel vehicle sales, nearly one-third of on-road heavy-duty diesel vehicle emissions and over half of on-road light-duty diesel vehicle emissions are in excess of certification limits. These excess emissions (totalling 4.6 million tons) are associated with about 38,000 PM2.5- and ozone-related premature deaths globally in 2015, including about 10 per cent of all ozone-related premature deaths in the 28 European Union member states. Heavy-duty vehicles are the dominant contributor to excess diesel NOx emissions and associated health impacts in almost all regions. Adopting and enforcing next-generation standards (more stringent than Euro 6/VI) could nearly eliminate real-world diesel-related NOx emissions in these markets, avoiding approximately 174,000 global PM2.5- and ozone-related premature deaths in 2040. Most of these benefits can be achieved by implementing Euro VI standards where they have not yet been adopted for heavy-duty vehicles.
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•Ozone is an efficient oxidant used for degrading organic pollutants.•Catalysts can improve O3 decomposition to form hydroxyl radicals.•Fe-based materials is emerging and promising ...catalysts for catalytic ozonation.•The preparation and characterization of Fe-based catalysts was summarized.•Their application for removing toxic organic pollutants was reviewed.
Catalytic ozonation utilizes catalysts to improve the decomposition of ozone and the formation of hydroxyl radicals, which can overcome some disadvantages of ozonation. Fe-based materials are widely used as catalysts for heterogeneous catalytic ozonation due to their easy preparation, excellent catalytic performance and the abundance of Fe in nature. In this paper, the performances of various Fe-based catalysts, including Fe0-derived, FeOOH-derived, Fe2O3-derived, Fe3O4-derived and iron oxides composite, their preparation and characterization methods were briefly introduced. The catalytic ozonation using Fe-based catalysts for the degradation of various emerging contaminants, such as pesticides and herbicides, pharmaceuticals, phthalic acid esters, dyes, nitrobenzenes, phenols, as well as for the treatment of actual wastewater was summarized. The main influencing factors on catalytic ozonation of toxic organic pollutants were discussed, and their potential applications and perspectives were proposed.
Ethylenediurea (EDU) has been widely studied for its effectiveness to protect plants against injuries caused by surface ozone (O3), however its mode of action remains unclear. So far, there is not a ...unified methodological approach and thus the methodology is quite arbitrary, thereby making it more difficult to generalize findings and understand the EDU mode of action. This review examines the question of whether potential N addition to plants by EDU is a fundamental underlying mechanism in protecting against O3 phytotoxicity. Yet, this review proposes an evidence-based hypothesis that EDU may protect plants against O3 deleterious effects upon generation of EDU-induced hormesis, i.e. by activating plant defense at low doses. This hypothesis challenges the future research directions. Revealing a hormesis-based EDU mode of action in protecting plants against O3 toxicity would have further implications to ecotoxicology and environmental safety. Furthermore, this review discusses the need for further studies on plant metabolism under EDU treatment through relevant experimental approach, and attempts to set the bases for approaching a unified methodology that will contribute in revealing the EDU mode of action. In this framework, focus is given to the main EDU application methods.
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•Ethylenediurea (EDU) is a chemical compound that protects plants against O3 injury.•EDU mode of action in plants has not been revealed yet.•This article proposes a potential hormesis-based EDU mode of action.•Such a potential mode of action would have implications to environmental safety.
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•Visible active Biochar@Bi2O2CO3/g-C3N4/CoFe2O4 assembly.•Intimate charge transfer at the interface.•Degradation of herbicide paraquat under visible and solar light.•Higher conversion ...of 4-nitrophenol into 4-aminophenol.•Superior reduction of CO2 into CH4, CO & O2.
The development of novel visible powered nano-heterojunctions with multi-pronged capabilities for environmental and catalytic applications has been gaining importance for persistent pollutant degradation & clean energy production. A magnetically recoverable biochar supported ternary g-C3N4/Bi2O2CO3/CoFe2O4 heterojunction (BCBF) was fabricated which shows a high visible photoactivity. The heterojunction was used for degradation of pesticide paraquat under visible radiation (Xe lamp), natural sunlight, photo-ozonation, peroxymonosulphate, and coupled conditions. A high degradation of 99.3% was achieved under visible radiation in 90 min and 92.1% under solar light in 120 min. Biochar supported ternary junction performs manifold faster than Bi2O2CO3/CoFe2O4, g-C3N4/CoFe2O4, g-C3N4/CoFe2O4, Bi2O2CO3 (BOC), CoFe2O4 (CF) and g-C3N4 (CN). The effect of operational parameters as effect of pH, H2O2, anions, ozone and peroxymonosulphate (PMS) was also studied. In BCBF + PMS + O3 + Vis protocol a spectacular complete degradation was observed in less than 30 min. Ternary band structure efficiently reduces the charge recombination rate and promotes spectral activity which was confirmed by photoluminescence, photocurrent response and EIS analysis. By LC-MS, scavenging experiments and ESR studies a possible mechanism was also proposed. Cyto-toxicity studies of degraded products on human peripheral blood cells revealed almost 99% cell viability affirming the complete mineralization. The junction was also used for reduction of 4-nitrophenol into 4-aminophenol with complete conversion in less than 5 min with rate constant 13.05 × 10−3 s−1. In addition the ternary junction shows a high visible powered conversion of CO2 producing CH4 (∼119 µmol g−1), CO (∼131 µmol g−1) and O2 (∼242 µmol g−1) with a high rate constant of 13.05 × 10−3 s−1.
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•Ozone oxidation coupled with post-absorption is firstly reviewed for flue gas treatment.•Simultaneous removal of NOx, SO2, VOCs, and mercury can be achieved by this ...technology.•Solubility increase and bond breaking are basic principles for pollutants removal by ozone.•This technology is potential to attain ultra-low emission for industrial boiler and furnaces.
Traditional flue gas pollutants treatment technologies are installed with their individual function. Industries usually make simple combination and increase operation load of equipment to face with the increasing stringent environmental stress and emission standard. Especially, these technique routes are not available to industrial boilers and furnaces because of specific conditions, such as unsuitable temperature window, complicated components in flue gas, and flexible operation. Simultaneous removal of multi-pollutants within one or two devices is a prospective direction that can save space occupation and cost. Interestingly, the solubility of NOx and mercury increases with its valance state, and organic pollutants can be degraded into nontoxic small molecules by oxidation. Ozone is a strong gas phase oxidant that can achieve pre-oxidation at low temperature, following by post-absorption to completely remove oxidized products. This review focuses on research progress involved in homogeneous and heterogeneous catalytic oxidation of NOx, organic pollutants, and mercury by ozone, as well as NOx absorption regarding of its full path removal. The reaction mechanism, kinetics, operation parameters, conversion efficiency and ozone residual are all summarized in detail. This paper also systematically reviews various approaches in catalytic ozonation towards improving catalytic activity, selectivity, and stability, as well as lowering temperature, such as active metals, metal loading contents, supports, precursors, and other modification. Finally, the overall technique route of simultaneous removal of multi-pollutants by ozone is analyzed. In conclusion, the ozone oxidation technology is advantaged in flue gas pollutants treatment, including low temperature, no massive adjustment in operation and original devices, saving space, no secondary pollution, N/S sources recovery, and potential to ultra-low emission.
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•ARGs exponentially and linearly decreased with the increase of UV doses and chloride concentrations(p<0.05).•Sulfa ARGs could be removed effectively by chlorination disinfection.•SMX ...ARB has greater tolerance to disinfection than TC or non-ARB.•Ozone and UV release free ARGs to environment resulted from apoptosis.
Antibiotic resistance genes (ARGs) in environment have gradually engendered extensive concern recently due to the harm caused to environment and human beings. Wastewater treatment plants are considered as important nodes of ARGs controlling and it is of utmost importance to figure out effects and mechanisms of each process, especially disinfections. In this study, three disinfection processes (ultraviolet, chlorination, and ozone) were used to reduce levels of ARGs in secondary effluents from a municipal wastewater treatment plant. Results indicated that the abundance of ARGs decreased exponentially as the dosage increased during the ultraviolet disinfection treatment (R2=0.68–0.92). In the 0–5mg/L available chlorine concentrations, with a contact time of 30min, the abundance of ARGs decreased linearly as the chlorine concentrations increased (R2=0.77–0.99). In a 2mg/L concentration of ozone (O3), the abundance of ARGs had higher removal efficiency, but the removal efficiency was not significantly enhanced by increasing the concentration of ozone. However, an experiment using the DNase I treatment showed that UV and ozone disinfection resulted in apoptosis, and the bacterial DNA was released into the environment; ARGs were mostly found as free DNA in the treated wastewater. These results provide insights into behavior of ARGs during disinfection processes in wastewater treatment plants.
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•Industrial installations for eliminating dioxins from flue gas.•Mechanisms of catalytic oxidation of chloroaromatics.•Catalyst classification and adaptation.•Catalyst deactivation ...and possible regeneration.•Miscellaneous methods to improve the catalytic oxidation process.
Commercial catalysts for the catalytic oxidation of chloroaromatics are mainly based on either noble metals or transition metal oxides supported on a suitable carrier. This paper reviews studies relative to these two generic groups of catalysts and their performances for chloroaromatic decomposition, i.e. conversion efficiency, stability and selectivity towards harmless products (e.g., CO2), and in particular, avoiding the formation of polychlorinated by-products. The various approaches towards improved catalysts, including tuning the support, adding dopants or promoters, improving the preparation methods, or auxiliary means such as the introduction of ozone (O3) or hydrogen peroxide (H2O2) in the gas to be treated, and combination with non-thermal plasma treatment are systematically reviewed. This review also appraises various modes of deactivation (i.e., originating from fouling, coking, poisoning, sintering of the catalyst, and from volatilization of its active phases) as well as possible methods for regeneration.