Factors affecting the alkaline hydrolysis of carbaryl in the presence of cationic surfactants

Peroza Meza, Carlos Arturo

01 May 2016

Alkaline degradation of Carbaryl in the presence of CTAB micelles has been reported as the most efficient method; however, the factors accounting for it are not yet clear. The main objective of this work was to study some of the factors affecting the alkaline degradation of Carbaryl in the presence of cetyl trimethylammonium bromide (CTAB). Three specific aims were researched in order to address the main objective. Solubility studies, UV-vis, fluorescence, and 1D-HNMR and 2D-HNMR spectroscopies were used to research the solubilization of carbaryl in CTAB micelles. Solubility studies showed that carbaryl partitions into CTAB micelles with a binding constant of 553 ± 8 M-1, and each mole of micellized surfactant incorporates about 0.336 moles of carbaryl. Spectroscopy studies showed that carbaryl does not interact electrostatically with micelles but does through van der Waals interactions. 1D-HNMR and 2D-HNMR indicated solubilization in the Stern layer, oriented with its hydrophilic moiety towards the Goüy-Chapman layer and the hydrophobic moiety towards the core of the micelle. Kinetic studies as a function of the surfactant concentration along with micellar kinetic models were used to calculate micellar rate constants (k’M) for each of four different cationic surfactants: cetyl trimethylammonium hydroxide (CTAOH), cetyl trimethylammonium bromide (CTAB), cetyl trimethylammonium chloride (CTACl), and cetyl pyridinium chloride (CPCl), and compared to the corresponding rate constants (k’W) in water; the results in all cases showed k’M / k’W > 1. This fact led to the conclusion that additional factors beyond solubilization of substrates are playing a role. Solubility studies revealed the following binding constant order and solubilization capacity order: CPCl > CTAOH ≈ CTAB > CTACl, CPCl > CTAOH ≈ CTAC > CTAB, indicating that for CPCl, Coulombic interactions, such as charge-transfer complexes, may be favoring the concentration effects, while for other surfactants, such as CTAOH, the [–OH] as the micelle counterion increases Carbaryl’s concentration in the Stern layer compared to its bulk concentration. In contrast, large, weakly-hydrated polarizable ions such as Br– displace hydrophilic ions, providing less enhancement. Kinetic experiments as a function of the surfactant head’s charge led to the conclusion that cationic and zwitterionic surfactants have a catalytic effect of the alkaline hydrolysis of carbaryl, while nonionic and anionic surfactants have inhibitory effects: kobs (cationic) > kobs (zwitterionic) > kobs(nonionic) > kobs (anionic). A similar order for solubility parameters (Ks and SC) was observed from equilibrium solubility studies. Experiments as a function of the polarity of the medium in the presence of both polar and nonpolar solvents showed that the hydrolysis rate is inversely proportional to the medium polarity. Ionic strength experiments showed that the hydrolysis rate is inversely proportional to the ion concentration.

Carbaryl

Catalysis

Micellar catalysis

Pharmacy and Pharmaceutical Sciences

Kationické povrchově aktivní látky a hodnocení jejich vlastností / Cationic surface active compounds and evaluation of its properties

Pekařová, Kateřina

January 2018

Charles University Faculty of Pharmacy in Hradec Králové Department of Biophysics and Physical Chemistry Consultant: PharmDr. Jan Marek, Ph.D. Supervisor: doc. PharmDr. Veronika Nováková, Ph.D. Student: Kateřina Pekařová Title of Thesis: Cationic surface active compounds and evaluation of its properties Quaternary ammonium salts are used as surfactants in many branches of the food, pharmaceutical and chemical industries. The basic properties of these substances were studied in the thesis. The critical micellar concentration of the homologous series of five substances was determined using the conductometric method. The theory of declining critical micellar concentration with the increasing length of the side alkyl chain has been verified. The hydrolytic activity of two commonly used cationic surfactants benzalconium chloride and benzoxonium chloride for the decomposition of the organophosphorus pesticide fenitrothion was tested. For these two substances, the effect of pH and temperature changes was evaluated. The influence of tenside concentration was also monitored. Benzoxonium chloride at 50 řC and pH 11was found as the most effective hydrolytic catalyst for the decomposition of the organophosphorus pesticide fenitrothione.

Étude de ligands de type biguanide dans le couplage de Suzuki-Miyaura dans l'eau

Fortun, Solène

12 1900

No description available.

Chimie verte

Catalyse dans l’eau

Couplage de Suzuki-Miyaura

Biguanide

Recyclage

Catalyse micellaire

Ligands de type pinceur

β-Cyclodextrine

Green chemistry

Catalysis in water

Suzuki-Miyaura coupling

Biguanide

Recycling

Micellar catalysis

Pincer-like ligands

β-Cyclodextrin

Estudo das condições de hidrólise de álcoois primários sulfatados. / A study on the susceptibility to acid-catalysed hydrolysis of primary alcohol ether sulfates in concentrated aqueous mixtures.

Oliveira, Maria Rita Perez de

04 April 2011

Álcoois primários sulfatados de cadeia longa, usualmente na forma de sais de sódio, são tensoativos de grande interesse comercial utilizados em diversas formulações de higiene pessoal e limpeza doméstica. Eles são produzidos comercialmente através da reação de álcoois etoxilados com trióxido de enxofre seguida de imediata neutralização com hidróxido de sódio. O produto formado é uma solução neutra de álcool primário etoxilado sulfatado em água. Sabe-se que a armazenagem desse produto por longos períodos de tempo em temperaturas elevadas pode levar à hidrólise completa, mas, em condições normais de uso e temperatura ambiente é esperado que o produto seja resistente à hidrólise. No entanto observou-se que algumas amostras comerciais de lauril éter sulfato de sódio que foram estocadas por diferentes períodos de tempo em frascos fechados à temperatura ambiente sofreram hidrólise em intervalos de tempo relativamente curtos. Isso leva à hipótese de que o comportamento de hidrólise seria influenciado por outras variáveis além da temperatura e do tempo de estocagem. O presente trabalho consistiu em identificar as variáveis de maior impacto na reação de hidrólise por meio de experimentos planejados. O teor de ativos foi acompanhado ao longo da reação para avaliar o efeito da presença de eletrólitos, de material insulfatado, em diferentes temperaturas, variando-se o pH inicial por meio da adição de ácido clorídrico. O comportamento da reação de hidrólise observado foi compatível com aquele descrito na literatura para o dodecil sulfato de sódio. A hidrólise apresentou-se como sendo autocatalítica, com a aceleração da taxa de reação provavelmente causada pela presença de íons hidrogênio liberados na reação. Foi possível identificar que as variáveis de maior efeito na reação foram: pH inicial, o teor de cloreto de sódio e a temperatura. O modelo de troca iônica em pseudo-fase foi utilizado para o tratamento dos resultados experimentais e mostrou-se adequado tendo sido, portanto, utilizado para prever o comportamento de estabilidade do produto à temperatura ambiente e nas condições em que o produto é normalmente comercializado. Um modelo empírico de redes neurais foi desenvolvido com sucesso para prever o comportamento do pH ao longo do tempo para as condições estudadas. / Long-chain primary alkyl sulfuric acids, usually as their sodium salts, are important commercial surfactants used in a large number of household and personal care formulations. They are commercially produced by treatment of mixtures of ethoxylated fatty alcohols with sulfur trioxide followed by immediate neutralization with sodium hydroxide, a neutral aqueous mixture of sodium primary alkyl ether sulfate is obtained. It is known that prolonged storage of the material at elevated temperature can lead to complete hydrolysis but under normal use and typical environmental conditions the product is expected to be resistant to hydrolysis. In spite of that it has been observed that some commercial samples of sodium lauryl ether sulfate stored for different periods of time in sealed containers at room temperature have undergone hydrolysis in a relatively short period of time which leads to the hypothesis that the hydrolysis behavior would be strongly influenced by variables other than temperature and storage time. The present work consisted of identifying the process variables with the most significant effect on the acid hydrolysis by using experimental design. The rate of hydrolysis has been followed acidimetrically to evaluate the effect of electrolytes as well as the concentration of unsulfated matter at different temperatures, over a wide initial pH range, under the presence of added hydrochloric acid. The pattern of kinetic behaviour observed was broadly the same as previously described for the sodium dodecyl sulfate. The hydrolysis presented the characteristic autocatalytic form, the catalysis presumably arising from the production of hydrogen sulfate ions. It was possible to observe that the most significant effects on the rate of hydrolysis were the initial pH, the total amount of sodium chloride and the temperature. The results were also discussed in terms of the ion-exchange pseudophase model of the micelle reaction. Accordingly to the fitting of parameters that was carried out it is possible to conclude that the pseudo-phase ion-exchange theory is found to account satisfactorily for the results reported and it was used to predict the stability behavior of the product at room temperature and under normal commercial conditions. A neural network based model was also successfully developed in order to predict the pH behavior in the conditions studied.

Catálise micelar

Hydrolysis of alkyl ether sulfates

Ion-exchange pseudo-phase model

Micellar catalysis

Micelle reaction

Modelo de redes neurais

Modelo de troca iônica em pseudo-fase

Neural network model

Reação micelar

Estudo das condições de hidrólise de álcoois primários sulfatados. / A study on the susceptibility to acid-catalysed hydrolysis of primary alcohol ether sulfates in concentrated aqueous mixtures.

Maria Rita Perez de Oliveira

04 April 2011

Álcoois primários sulfatados de cadeia longa, usualmente na forma de sais de sódio, são tensoativos de grande interesse comercial utilizados em diversas formulações de higiene pessoal e limpeza doméstica. Eles são produzidos comercialmente através da reação de álcoois etoxilados com trióxido de enxofre seguida de imediata neutralização com hidróxido de sódio. O produto formado é uma solução neutra de álcool primário etoxilado sulfatado em água. Sabe-se que a armazenagem desse produto por longos períodos de tempo em temperaturas elevadas pode levar à hidrólise completa, mas, em condições normais de uso e temperatura ambiente é esperado que o produto seja resistente à hidrólise. No entanto observou-se que algumas amostras comerciais de lauril éter sulfato de sódio que foram estocadas por diferentes períodos de tempo em frascos fechados à temperatura ambiente sofreram hidrólise em intervalos de tempo relativamente curtos. Isso leva à hipótese de que o comportamento de hidrólise seria influenciado por outras variáveis além da temperatura e do tempo de estocagem. O presente trabalho consistiu em identificar as variáveis de maior impacto na reação de hidrólise por meio de experimentos planejados. O teor de ativos foi acompanhado ao longo da reação para avaliar o efeito da presença de eletrólitos, de material insulfatado, em diferentes temperaturas, variando-se o pH inicial por meio da adição de ácido clorídrico. O comportamento da reação de hidrólise observado foi compatível com aquele descrito na literatura para o dodecil sulfato de sódio. A hidrólise apresentou-se como sendo autocatalítica, com a aceleração da taxa de reação provavelmente causada pela presença de íons hidrogênio liberados na reação. Foi possível identificar que as variáveis de maior efeito na reação foram: pH inicial, o teor de cloreto de sódio e a temperatura. O modelo de troca iônica em pseudo-fase foi utilizado para o tratamento dos resultados experimentais e mostrou-se adequado tendo sido, portanto, utilizado para prever o comportamento de estabilidade do produto à temperatura ambiente e nas condições em que o produto é normalmente comercializado. Um modelo empírico de redes neurais foi desenvolvido com sucesso para prever o comportamento do pH ao longo do tempo para as condições estudadas. / Long-chain primary alkyl sulfuric acids, usually as their sodium salts, are important commercial surfactants used in a large number of household and personal care formulations. They are commercially produced by treatment of mixtures of ethoxylated fatty alcohols with sulfur trioxide followed by immediate neutralization with sodium hydroxide, a neutral aqueous mixture of sodium primary alkyl ether sulfate is obtained. It is known that prolonged storage of the material at elevated temperature can lead to complete hydrolysis but under normal use and typical environmental conditions the product is expected to be resistant to hydrolysis. In spite of that it has been observed that some commercial samples of sodium lauryl ether sulfate stored for different periods of time in sealed containers at room temperature have undergone hydrolysis in a relatively short period of time which leads to the hypothesis that the hydrolysis behavior would be strongly influenced by variables other than temperature and storage time. The present work consisted of identifying the process variables with the most significant effect on the acid hydrolysis by using experimental design. The rate of hydrolysis has been followed acidimetrically to evaluate the effect of electrolytes as well as the concentration of unsulfated matter at different temperatures, over a wide initial pH range, under the presence of added hydrochloric acid. The pattern of kinetic behaviour observed was broadly the same as previously described for the sodium dodecyl sulfate. The hydrolysis presented the characteristic autocatalytic form, the catalysis presumably arising from the production of hydrogen sulfate ions. It was possible to observe that the most significant effects on the rate of hydrolysis were the initial pH, the total amount of sodium chloride and the temperature. The results were also discussed in terms of the ion-exchange pseudophase model of the micelle reaction. Accordingly to the fitting of parameters that was carried out it is possible to conclude that the pseudo-phase ion-exchange theory is found to account satisfactorily for the results reported and it was used to predict the stability behavior of the product at room temperature and under normal commercial conditions. A neural network based model was also successfully developed in order to predict the pH behavior in the conditions studied.

Catálise micelar

Modelo de redes neurais

Modelo de troca iônica em pseudo-fase

Reação micelar

Hydrolysis of alkyl ether sulfates

Ion-exchange pseudo-phase model

Micellar catalysis

Micelle reaction

Neural network model