Nonylphenol- and octylphenol-ethoxylates in surfactant products : need control or not? : an overview of their consumption, environmental fate and risks and public awareness in Hong Kong as compared to overseas countries

Leung, Sau-mei, Teresa, 梁秀媚

January 2013

Nonylphenol ethoxylates (NPEO) and octylphenol ethoxylates (OPEO), both are alkylphenol ethoxylates (APEO), a type of non-ionic surfactants commonly used in synthetic detergents for household and industrial cleaning purposes. These compounds and their degraded intermediates are xenoestrogens ubiquitously found in runoffs, sewage discharge and sludge. Not only that they persist in our surface waters and sediment, they are also found in the bodies of wildlife and human worldwide. Because of their high volume consumed and their nature as semi-persistent pollutants as well as endocrine disruptors, many developed countries have renounced their use on voluntary basis or through regulatory measure. Hong Kong is situated at the estuary of Pearl River Delta, which is one of the pollution hotspots. It is susceptible to its own water pollutants from municipal sewage (~1,054 million m3/year) and also the discharge (~3.0x109m3/ year) along the river from the industrialized and urbanized Mainland China cities. The local environment and human health are exposed to risks of these chemicals ascribed to rising consumption of detergents and their insufficient removal by sewage treatment, in addition to food intake in particular seafood. However, public awareness about APEO and endocrine disrupting chemicals is low due to no mandatory disclosure and control of these chemicals as well as the uncertainties about their chronic toxicity, based on the survey results of online questionnaires. Several recommendations have been made with reference to overseas regulatory measures and good practices to control and reduce the use of these chemicals. / published_or_final_version / Environmental Management / Master / Master of Science in Environmental Management

Stabilization of dispersions in carbon dioxide and in other low-permittivity media

Smith, Peter Griffin

28 August 2008

Not available / text

Electrochemistry

Electrostatics

Emulsions

Dispersion

Carbon dioxide

Surface active agents

Vibrational spectroscopy and surface characterisation of polymer films and surfactants

Pedley, Michael Ewan

January 2009

No description available.

540

The role of surfactants in kraft pulping of different wood species /

Chen, Dezhi, 1982-

January 2007

A unique penetration instrument has been developed to evaluate the role of surfactants in kraft pulping process. This instrument can screen surfactants which can improve the wood impregnation more effectively and much faster than pilot-plant experiment. The role of surfactants in wood penetration has been explored. Surfactants can improve wood impregnation by dispersing the extractives in the wood structure and optimizing the interfacial properties between wood surface and kraft liquor. The addition of two blends of anionic and nonionic surfactants into kraft pulping process results in a significant reduction of the screen rejects and an increase of screened yield at the same delignification rate. / Six wood species were tested in this study including both non-resinous and resinous wood species. Both sapwood and heartwood of these species were tested. Surfactants were found to have no improvement on sapwood, but a significant improvement on heartwood. The critical micelle concentrations (CMC) of surfactants in kraft liquor were determined. The best dosages of surfactants based on CMC were also determined in this study.

Sulfate pulping process.

The effect of solid micro particles on mass transfer in agitated dispersions.

January 2008

The industrial application of gas-liquid contactors has made effective design and optimisation of these processes a very important topic. In order to sustain a competitive advantage, rate limiting steps must be clearly understood. Hydrodynamics, heat transfer and mass transfer are complicated features of gas-liquid contactors and require a fundamental understanding. The mechanism of mass transfer in the presence of a small concentration of solid micro particles has been the subject of debate. The adsorption of gas by solid particles ("shuttle mechanism") is the traditional explanation. Recent experimental evidence suggests that the introduction of micro particles removes trace surface active impurities from the system and allows the true mass transfer coefficient to be measured. The objective of this study was to confirm the surfactant removal theory. Mass transfer is a field characterised by imprecise empirical relationships and difficult to obtain experimental parameters. This puts into context the significant challenge posed in preparing the careful set of measurements and analyses presented in this study to lend support to the surfactant removal mechanism. The study began with a review of mass transfer models. These models are based on concepts such as surface renewal and idealised turbulence. It is, however, difficult to choose between the models as they predict similar values despite being based on different mechanisms. The overall mass transfer coefficient is composed of the gas-phase coefficient (kGa) and liquid-phase coefficient (kLa). As the values of the coefficients are comparable and the solubility of oxygen or hydrogen is very Iow, the overall mass transfer coefficient is approximately equal to the liquid side coefficient. The relationship of kL with the diffusion coefficient (D) is one of the limited ways of choosing between the models. Mass transfer models predict k j • u:. D" . n is predicted to be % for a rigid surface (contaminated interface region) and Y2 for a mobile surface (clean interface region). If the surfactant removal mechanism applies, the introduction of solid particles will be accompanied by a reduction of n from % to 1/2. The effect of particles on n can be calculated from precise measurement of kL of gases with significantly different diffusion coefficients. A review of experimental methods was made to find precise methods to characterise mass transfer in the presence of solid micro particles. The chemical sulphite, gas-interchange and pressure step methods were identified as appropriate methods. These were implemented in a stirred cell (0.5 !) and an agitated tank (6 I). The chemical sulphite measurements were used to confirm that the enhancement of kLa is due to an enhancement of kL and not the specific interfacial area (a). Flat surface experiments were made using water and 0.8 M sodium sulphate batches. The reduction of n from % to Y2 was confirmed in both apparatuses after the addition of solid particles. The data were very well correlated and the dependence of kr on the energy dissipation rate per unit volume (e) is similar to the theoretically predicted value of 114 for the exponent. Observation of the reduction of n from % to Y2 was extended to agitated dispersions. The stirred cell kLa data were measured by the gas interchange method and are of excellent quality. The agitated tank results were measured by pressure step methods. The pressure dependence of the polarographic probes affected the precision of the results and the effect was within the experimental uncertainty. The effect of particles on n could not, therefore, be conclusively confirmed in the agitated tank. By relating precisely measured mass transfer coefficients to the diffusion coefficients; the surfactant removal theory is confirmed. The result is valid for a flat mass transfer area as well as for agitated dispersion where the nature of the interface region changes with time due to the accumulation of surfactants on an initially clean interface. / Thesis (Ph.D.)-University of KwaZulu-Natal, Durban, 2008.

Mass transfer.

Surface active agents.

Theses--Chemical engineering.

Water-based crosslinkable coatings via miniemulsion polymerization of acrylic monomers in the presence of polyester resin

Tsavalas, John George

12 1900

No description available.

Emulsions

Emulsion polymerization

Surface active agents

Sorption and transport of selected nonionic surfactants in soil systems

Martin, Charlotte Anne

05 1900

No description available.

Surface active agents

Soil absorption

Soil science

Bioremediation

Influence of surfactants on the sorption and transport of contaminants in saturated and unsatruated soils

Karagunduz, Ahmet

05 1900

No description available.

Surface active agents

Soil absorption

Soil science

Bioremediation

Evaluation of surfactants for the enhancement of PCB degradation

Howell, Desiree Pearl

05 1900

No description available.

Surface active agents

Surface chemistry

Effect of Gemini surfactant on the formation kinetic behavior of methane hydrate

Mishal, Yeshai.

January 2008

Gas hydrates are a topic of great interest and intense investigation. Traditionally, these compounds have been seen as a nuisance to the oil and gas industry, which can plug pipelines and cause hours of costly downtime. More recently, gas hydrates have been viewed as a possible energy source due to the vast amount of methane trapped in the form of gas hydrate. Many researchers have also proposed the possibility of transporting natural gas in the form of gas hydrate may be safer and more economical than using liquid or compressed natural gas. Gas hydrate may also offer the possibility of reducing greenhouse gas emissions via the sequestration of carbon dioxide. / Surfactants have been found to act as both promoters and inhibitors of hydrate formation. In the present study, the formation rate, solubility and mass transfer conductance of methane in the presence of Gemini surfactant, a new class of surfactants, was studied with varying concentration of Gemini surfactant. The experiments to determine the formation rates of methane hydrate were conducted at 4°C and 6500 kPa. While the experiments to determine solubility and mass conductance were carried out at 4°C and 3800 kPa. The resulting values were used to determine experimental accuracy and reproducibility by comparing the values obtained with literature values and by analyzing the distribution of the data obtained. Solubility measurements were extremely close to literature values with only a 1.4% difference. The distribution of solubility values and formation rates did not deviate significantly between replicates indicating a high degree of reproducibility; however, a lot of variability was observed in mass transfer conductance. This may be attributed to the fact that mass transfer was not determined experimentally by regressing a coefficient to fit a curve, which may be less accurate than other experimentally determined parameters. / In the second part of the study, the formation rate, solubility and mass transfer conductance of methane were determined using aqueous Gemini surfactant solutions. The experiments to determine the formation rates of methane hydrate were conducted at 4°C and 6500 kPa. While the experiments to determine solubility and mass transfer conductance were carried out at 4°C and 3800 kPa. The resulting values were used to determine the effect of Gemini surfactant on the properties of interest by comparing the values obtained with aqueous Gemini surfactant with the values previously obtained for pure water. The results obtained showed that solubility increased with increasing concentrations of Gemini surfactant with solubility increasing by up to 18% for higher concentration of Gemini surfactant. The mass transfer conductance was also found to increase by up to 49%; however other than the existence of an increase, no conclusive relationship could be determined between the concentration of Gemini surfactant and mass transfer conductance. / Finally, the formation rate of gas hydrates was found to decrease slightly, relative to water, at low concentrations, increased linearly at subsequently higher concentrations and ultimately plateau at a maximum. This trend was in agreement with similar experiments found in literature and the increase in formation rate may be attributed to the increase in both solubility and mass transfer conductance when using aqueous Gemini surfactant.

Natural gas -- Hydrates.

Methane.