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Honours ProjectsProfessor Peter MayPosition: Chair Extr Mtllrgy/Head of School
Email: P.May@murdoch.edu.au
Phone:
9360 2203
Room: PhSc/2.014
ResearchSolution Chemistry, Chemical Speciation, Computer Application ProjectsChemistry of Aluminate Solutions (In collaboration with Associate Professor Glenn Hefter) The properties of concentrated caustic aluminate solutions are of great interest to the alumina industry as models for Bayer liquors. In recent years at Murdoch University we have developed world class facilities for studying the properties of such solutions under the sponsorhip of the Australian alumina industry and the AJ Parker Cooperative Research Centre for Hydrometallurgy. A wide range of techniques are now available including calorimetry, viscometry, potentiometry and spectroscopic techniques such as NMR, FTIR and Raman. A variety of projects are available covering various aspects of aluminate chemistry including the following:
Concentrated electrolyte solutions are widely used in hydrometallurgy for the recovery and purification of many metals. However, our ability to model the behaviour of such solutions is limited by our understanding of their nature. New insights are being gained by the application of new experimental and theoretical techniques. Cyanide in the Environment Improving our current understanding of cyanide behaviour in the environment is needed to achieve best practice in waste management by the mining industry. The chemistry of metal complexation by cyanide and of cyanide volatization, oxidation and adsorptiion onto minerals determines cyanide ecotoxicity. This project will measure the quantitative data required for technical decision-making to minimise the adverse effects of cyanide in the environment. Modelling will play a key role in the interpretation of experiments and in predicting the environmental consequences of cyanide disposal. Chelation in Biological Fluids The interaction of drugs with metal ions in body fluids such as blood plasma, saliva and intestinal juice (either by design or as a side-effect) is of increasing concern in pharmaceutical research. Currently, emphasis is being given to experimental characterization of metal binding to macromolecules such as proteins using fulvic acid as a model system and to the development of a computer simulation of the physiological distribution and turnover of trace elements in mammalian systems. Applied Chemical Speciation Studies (In collaboration with Associate Professor Glenn Hefter) Chemical speciation: the exact chemical form of an element, plays a dominant role in determining how that element interacts with its physical and biological environment. Such effects are of widespread importance in industry, the environment and medicine. The measurement of chemical equilibria, coupled to computer modelling techniques, provides the best method of studying chemical speciation phenomena. Present areas of interest are:
Solution Equilibria and Transport The aim of these studies is to understand, and thus to control the equilibrium and kinetic processes which determine the chemical properties of biological, geological and industrial solutions. The work is highly interdisciplinary both in its theoretical and its experimental content. Strong emphasis is placed on the use of mainframe and microcomputers. Current areas of research include the following:
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