Chlorination Decoloration of Textile Wastewaters and Dyestuffs-A Kinetic Study

Kan, Chia-Hsin

17 July 2000

Almost all dyestuffs used for textile processing impose heavy colors on effluents such that they can¡¦t meet effluent regulations. Sodium hypochlorite (NaOCl) has long been used for effluent decoloration by most textile plants. However, despite by the operators¡¦ experience, there is still no scientific method for controlling the dosing rate of sodium hypochlorite. An insufficient dosage may result in an aesthetically and legally unacceptable effluent. Whereas an excessive one may lead to the formation of chlorine-containing organic compounds which are harmful to the aquatic life and may limit the water utilization. It is necessary to develop a control technique for chlorination decoloration of textile wastewaters. In this study, secondary effluent samples from a textile wastewater plant and synthetic wastewater samples prepared by two azo-type dyestuffs were used for chlorination decoloration tests in a batch reactor with a residual chlorine indicator. Experimental results indicate that the most economic and effective reaction conditions for decoloration of the test wastewaters were pH = 4 and residual chlorine = 14 mg/L. In the conditions, wastewaters with true color intensity = 1,200 ADMI could be reduced to values less than 400 ADMI within 60 min. Results also confirm that on-line monitoring of residual chlorine concentration in the reacting liquid can be used to achieve a better control of chlorine addition. Experimental data also indicate that the color removal rate (-dC/dt) was linearly proportional to the color intensity (C) and free hypochlorous acid (HOCl) concentration.

Kinetic Study

Sodium hypochlorite

decoloration

textile wastewater

Theoretical Kinetic Study of Gas Phase Oxidation of Nicotine by Hydroxyl Radical

Chavarrio Cañas, Javier Eduardo

11 1900

Cigarette smoke is suspected to cause diverse illnesses in smokers and people breathing second- and third-hand smoke. Although different studies have been done to elucidate the impact on health due to smoking, there is a lack of kinetic information regarding the degradation of nicotine under different environmental conditions. As a consequence, currently it is not possible to determine thoroughly the risk due to exposure to nicotine and the compounds derived from its decomposition. With the aim of contributing to clarify the different degradation paths followed by nicotine during and after the consumption of cigarettes, this work presents a theoretical study of the hydrogen atom abstraction reaction by hydroxyl radical at four sites in the nicotine molecule in a broad range of temperature, specifically be-tween 200-3000 K. The site-specific kinetic rate constants were computed by means of the multi-structural torsional variational transition state theory with small curvature tunneling contribution, performing ab initio calculations at the level M06-2X/aug-cc-pVQZ//M06-2X/cc-pVTZ. According to our computations, the dependence on temperature of the studied rate constants exhibited a non-Arrhenius fashion, with a minimum at 873 K. A negative temperature dependence was observed at temperatures lower than 873 K, indicating more prolonged exposure to nicotine in warmer environments. On the other hand, the opposite behavior was observed at higher temperatures; this non-Arrhenius be-havior results of interest in tobacco cigarette combustion, inducing different reaction mechanisms depending on the burning conditions of the different smoking devices. The results indicate that multi-structural and torsional anharmonicity is an im-portant factor in the computation of accurate rate constants, especially at high tem-peratures where the higher-energy conformers of the different species exert a larger influence. The anharmonicity factors suggest that disregarding the anharmonic de-viations leads to overestimation of the rate constant coefficients, by a factor between four and six. Our computed overall kinetic rate constant at 298 K exhibited very good agreement with the only experimental value meausred by Borduas et al. [1], af-fording certainty about our calculated site-specific rate constants, which are currently inaccessible to experiments. However, further experimental studies are necessary to validate our kinetic studies at other temperatures.

Nicotine degradation

Kinetic study

Atmospheric oxidation

A kinetic study of the growth of anchorage-dependent mouse L cells

Haldankar, Raj

January 1994

No description available.

Engineering, Chemical

Kinetic study

anchorage-dependent

mouse L cells

Cold Fiber Solid Phase Microextraction

Hosseinzadeh Haddadi, Shokouh

January 2008

A cold fiber solid phase microextraction device was designed and constructed based on the use of a thermoelectric cooler (TEC). A three-stage thermoelectric cooler was used for cooling a copper rod coated with a polydimethylsiloxane (PDMS) hollow fiber, which served as the SPME fiber. The copper rod was mounted on a commercial SPME plunger and exposed to the cold surface of the TEC, which was enclosed in a small aluminum box. A heat sink and a fan dissipated the generated heat at the hot side of the TEC. By applying an appropriate DC voltage to the TEC, the upper part of the copper rod, which was in contact to the cold side of the TEC, was cooled and the hollow fiber reached a lower temperature through heat transfer. A thermocouple was embedded in the cold side of the TEC for indirect measurement of the fiber temperature. A portable cold fiber SPME device was made by using a car battery as the power supply. The cold fiber SPME device with thermoelectric cooling was applied in quantitative analysis of off-flavors in rice. Hexanal, nonanal, and undecanal were chosen as three test analytes in rice. These analytes were identified according to their retention times and analyzed with a GC/FID instrument. Headspace extraction conditions (i.e. extraction temperature and extraction time) were optimized. Standard addition calibration graphs were obtained at the optimized conditions and the concentrations of the three analytes were calculated. The developed method was compared to a conventional solvent extraction method. The applicability of the portable cold fiber SPME with TEC for field sampling was tested. The effect of cooling on extraction recovery and the reproducibility of extraction were examined for extractions from an n-alkane flow through system. It was found that the extraction recoveries were significantly higher when the fiber was cooled. To further investigate the effect of cooling on the sensitivity of SPME in field sampling, the portable cold fiber SPME was used for extraction of volatile components from living wisteria flowers. Both the number of identified compounds and the related peak areas increased for extractions with cold PDMS fiber relative to without cooling and commercial PDMS and PA fibers. The portable cold fiber SPME device was also used for field sampling of volatile components of living lily-of-the-valley flowers and the extracted compounds were analyzed with GC/MS. The desorption kinetics of hydrophobic organic compounds (HOCs) from environmental solid matrices was investigated using cold fiber SPME with CO2 cooling. Polycyclic aromatic hydrocarbons (PAHs) and selected volatile organic compounds (i.e. toluene, ethylbenzene, o-xylene) were used as test analytes. Sand, silica gel, and clay were used as laboratory model solid matrices and were contaminated by the test analytes. Certified sediments were used as naturally contaminated samples. In this approach, the organic compounds, released from contaminated solid samples at different elevated temperatures, were exhaustively extracted with cold fiber SPME over different extraction times. The extraction data were used to obtain desorption and Arrhenius plots. The rate constants of desorption and activation energies of desorption were measured for each contaminant using these plots. The results were comparable to those reported in the literature.

Solid Phase Microextraction

Thermoelectric coolers

Food Analysis

Fragrance analysis

Kinetic study

Chemistry

Cold Fiber Solid Phase Microextraction

Hosseinzadeh Haddadi, Shokouh

January 2008

A cold fiber solid phase microextraction device was designed and constructed based on the use of a thermoelectric cooler (TEC). A three-stage thermoelectric cooler was used for cooling a copper rod coated with a polydimethylsiloxane (PDMS) hollow fiber, which served as the SPME fiber. The copper rod was mounted on a commercial SPME plunger and exposed to the cold surface of the TEC, which was enclosed in a small aluminum box. A heat sink and a fan dissipated the generated heat at the hot side of the TEC. By applying an appropriate DC voltage to the TEC, the upper part of the copper rod, which was in contact to the cold side of the TEC, was cooled and the hollow fiber reached a lower temperature through heat transfer. A thermocouple was embedded in the cold side of the TEC for indirect measurement of the fiber temperature. A portable cold fiber SPME device was made by using a car battery as the power supply. The cold fiber SPME device with thermoelectric cooling was applied in quantitative analysis of off-flavors in rice. Hexanal, nonanal, and undecanal were chosen as three test analytes in rice. These analytes were identified according to their retention times and analyzed with a GC/FID instrument. Headspace extraction conditions (i.e. extraction temperature and extraction time) were optimized. Standard addition calibration graphs were obtained at the optimized conditions and the concentrations of the three analytes were calculated. The developed method was compared to a conventional solvent extraction method. The applicability of the portable cold fiber SPME with TEC for field sampling was tested. The effect of cooling on extraction recovery and the reproducibility of extraction were examined for extractions from an n-alkane flow through system. It was found that the extraction recoveries were significantly higher when the fiber was cooled. To further investigate the effect of cooling on the sensitivity of SPME in field sampling, the portable cold fiber SPME was used for extraction of volatile components from living wisteria flowers. Both the number of identified compounds and the related peak areas increased for extractions with cold PDMS fiber relative to without cooling and commercial PDMS and PA fibers. The portable cold fiber SPME device was also used for field sampling of volatile components of living lily-of-the-valley flowers and the extracted compounds were analyzed with GC/MS. The desorption kinetics of hydrophobic organic compounds (HOCs) from environmental solid matrices was investigated using cold fiber SPME with CO2 cooling. Polycyclic aromatic hydrocarbons (PAHs) and selected volatile organic compounds (i.e. toluene, ethylbenzene, o-xylene) were used as test analytes. Sand, silica gel, and clay were used as laboratory model solid matrices and were contaminated by the test analytes. Certified sediments were used as naturally contaminated samples. In this approach, the organic compounds, released from contaminated solid samples at different elevated temperatures, were exhaustively extracted with cold fiber SPME over different extraction times. The extraction data were used to obtain desorption and Arrhenius plots. The rate constants of desorption and activation energies of desorption were measured for each contaminant using these plots. The results were comparable to those reported in the literature.

Solid Phase Microextraction

Thermoelectric coolers

Food Analysis

Fragrance analysis

Kinetic study

Chemistry

Asymmetric transfer hydrogenation of ketones : Catalyst development and mechanistic investigation

Ahlford, Katrin

January 2011

The development of ligands derived from natural amino acids for asymmetric transfer hydrogenation (ATH) of prochiral ketones is described herein. In the first part, reductions performed in alcoholic media are examined, where it is found that amino acid-derived hydroxamic acids and thioamides, respectively, are simple and versatile ligands that in combination with [RhCp*Cl2]2 efficiently catalyze this particular transformation. Selectivities up to 97% ee of the corresponding secondary alcohols are obtained, and it is furthermore observed that the two different ligand classes, albeit based on the same amino acid scaffold, give rise to products of opposite configuration. The highly interesting enantioswitchable nature of the two abovementioned catalysts is studied in detail by mechanistic investigations. A structure/activity correlation analysis is performed, which reveals that the diverse behavior of the catalysts arise from different interactions between the ligands and the metal. Kinetic studies furthermore stress the catalyst divergence, since a difference in the rate determining step is established from initial rate measurements. In addition, rate constants are determined for each step of the overall reduction process. In the last part, catalyst development for ATH executed in water is discussed. The applicability of hydroxamic acid ligands is further extended, and catalysts based on these compounds are found to be efficient and compatible with aqueous conditions. The structurally even simpler amino acid amide is also evaluated as a ligand, and selectivities up to 90% ee are obtained in the reduction of a number of aryl alkyl ketones. The very challenging reduction of dialkyl ketones is moreover examined in the Rh-catalyzed aqueous ATH, where a modified surfactant-resembling sulfonylated diamine is used as ligand, and the reaction is carried out in the presence of SDS-micelles. A positive effect is to some extent found on the catalyst performance upon addition of phase-transfer components, especially regarding the catalytic activity in the reduction of more hydrophobic substrates. / At the time of the doctoral defense, the following paper was unpublished and had a status as follows: Paper 4: In press.

Asymmetric catalysis

reduction

amino acid

rhodium

mechanistic investigation

kinetic study

Organic chemistry

Organisk kemi

Synthèse et étude mécanistique de nanocristaux d'InP et formation d'hétérostructures / Synthesis and mechanistic study of InP nanocrystals and formation of heterostructures

Buffard, Aude

30 September 2016

Ce travail de thèse porte sur la synthèse de nanocristaux d’InP et la compréhension des mécanismes en jeu ainsi que sur l’amélioration des propriétés optiques de ces objets. Les nanocristaux d’InP sont des matériaux prometteurs pour des applications optoélectroniques et biomédicales grâce à leur faible toxicité et leur large gamme spectrale atteignable. Cependant, la synthèse de ces nanoparticules est mal contrôlée et ne permet pas, jusqu’à présent, l’obtention d’objets de grande taille avec des propriétés optiques comparables aux nanocristaux de CdSe. Le précurseur de phosphore couramment utilisé présente une grande toxicité et un coût important. Nous avons choisi d’utiliser des aminophosphines comme précurseurs alternatifs puisqu’elles présentent une toxicité réduite et un faible coût. Une étude sur les différents paramètres de synthèse a permis de mettre en évidence le rôle clé des amines primaires. Et grâce à des études mécanistiques et cinétiques détaillées, la compréhension des réactions a permis d’améliorer les qualités des nanocristaux synthétisés. Afin d’améliorer les qualités optiques des nanocristaux synthétisés, des hétérostructures ont été formées. Les systèmes InP/ZnS permettent une augmentation de la fluorescence. Cependant, le dépôt effectif en matériau est limité. En parallèle, une hétérostructure alternative hybride a été étudiée. Celle-ci a été développée sur des nanoplaquettes de CdSe/CdS comme système modèle. Les nanocristaux sont entourés de silice puis d’or ce qui permet une bonne protection des nanoparticules vis-à-vis de l’environnement. De plus, le couplage entre le plasmon de l’or et la fluorescence augmente les propriétés optiques du matériau. / This manuscript focuses on the synthesis of InP nanocrystals, their understanding of the mechanisms and the improvement of the optical properties of these objects. The nanocrystals of InP are promising materials for optoelectronic and biomedical applications due to their low toxicity and wide reachable spectral range. However, the synthesis of these nanoparticles is poorly controlled and does not allow to obtain large objects with optical properties comparable to CdSe nanocrystals. The phosphorus precursor commonly used presents a high toxicity and a high cost. The aminophosphine are phosphorus precursors of choice to replace the current one since it has a reduced toxicity and a low cost. A study of different synthesis parameters enabled to highlight the role of some reagents such as primary amines. Through a detailed mechanistic and kinetic study, the understanding of the reactions allows to improve the quality of the synthesized nanocrystals. In order to improve the optical qualities of the synthesized nanocrystals, heterostructures can be formed. InP/ZnS systems allow an increase in fluorescence. However, the deposition material is low. With a view to improve their fluorescence, hybrid heterostructure has been developed. This was developed on nanoplatelets CdSe/CdS as a template. The nanocrystals are surrounded by silica and gold layers which provide good protection concerning the environmental medium. The coupling between the plasmon of the gold and the fluorescence increases the optical properties of the material.

Nanocristaux

Semi-Conducteurs

Synthèse

Aminophosphine

Étude cinétique

Mécanisme chimique

Fluorescence.

Nanocrystals

Aminophosphine

Kinetic study

541.3

Design of Embedded Metal Catalysts via Reverser Micro-Emulsion System: a Way to Suppress Catalyst Deactivation by Metal Sintering

Al Mana, Noor

19 June 2016

The development of highly selective and active, long-lasting, robust, low-cost and environmentally benign catalytic materials is the greatest challenge in the area of catalysis study. In this context, core-shell structures where the active sites are embedded inside the protecting shell have attracted a lot of researchers working in the field of catalysis owing to their enhanced physical and chemical properties suppress catalyst deactivation. Also, a new active site generated at the interface between the core and shell may increases the activity and efficiency of the catalyst in catalytic reactions especially for oxide shells that exhibit redox properties such as TiO2 and CeO2. Moreover, coating oxide layer over metal nanoparticles (NPs) can be designed to provide porosity (micropore/mesopore) that gives selectivity of the various reactants by the different gas diffusion rates. In this thesis, we will discuss the concept of catalyst stabilization against metal sintering by a core-shell system. In particular we will study the mechanistic of forming core-shell particles and the key parameters that can influence the properties and morphology of the Pt metal particle core and SiO2 shell (Pt@SiO2) using the reverse micro-emulsion method. The Pt@SiO2 core-shell catalysts were investigated for low-temperature CO oxidation reaction. The study was further extended to other catalytic applications by varying the composition of the core as well as the chemical nature of the shell material. The Pt NPs were embedded within another oxide matrix such as ZrO2 and TiO2 for CO oxidation reaction. These materials were studied in details to identify the factors governing the coating of the oxide around the metal NPs. Next, a more challenging system, namely, bimetallic Ni9Pt NPs embedded in TiO2 and ZrO2 matrix were investigated for dry reforming of methane reaction at high temperatures. The challenges of designing Ni9Pt@oxide core-shell structure with TiO2 and ZrO2 and their tolerance of the structure to the conditions of dry reforming of methane will be discussed.

Core-Shell

Pt@SiO2

CO oxidation

micro-emulsion

Pt on SiO2

kinetic Study

Quantitative Analysis of Phase-Transition Process of Light-Activatable Theranostic Agents by Pulsed Laser

Zhang, Zhe

January 2018

No description available.

Chemical Engineering

phase transition

Arrhenius equation

kinetic study

perfluorocarbon

nanodroplets

pulsed laser

Kinetic study of low temperature sulfur dioxide and hydrogen chloride removal using calcium-based sorbents

Zhan, Rijing

January 1999

No description available.

Engineering, Chemical

Kinetic Study

calcium-based sorbents

low temperature sulfur dioxide

hydrogen chloride