Scholarly Work - Center for Biofilm Engineering
Permanent URI for this collectionhttps://scholarworks.montana.edu/handle/1/9335
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Item Biofouling control in recycled cooling water with bromo chloro dimethlhydantoin(1983-01) Matson, J. V.; Characklis, William G.A fouling monitor system was installed on a slip-stream from the cooling water return line to monitor biofouling and to determine effectiveness of various biocide treatments. Its purpose was to simulate conditions in the main system and provide a real time readout of the extent of biofouling as measured by reduction in heat transfer. The total halogen residual in the cooling water was measured six times per day by the DPD colorimetric method.Item Diffusion and reaction in microbial aggregates(1974) Characklis, William G.; Pipes, D. M.; Matson, J. V.Item Mathematical model for biological reactor design incorporating characteristics of cell aggregates(1973) Matson, J. V.; Characklis, William G.; Rios, R. A.Item Oxygen supply limitations in full scale biological treatment systems(1972) Matson, J. V.; Characklis, William G.; Busch, A. W.Item Diffusion into microbial aggregates(1976) Matson, J. V.; Characklis, William G.Theoretical work in the biological waste treatment field has been directed at modeling substrate removal processes in fluidized and fixed film microbial systems in terms of the basic rate processes. Much of the research has been directed at delineating the rate limiting steps to simplify the problem. Various researchers have shown that the rate limiting step can be mass transfer through the microbial aggregate to the active sites at the cells. Therefore, any mechanistic model that incorporates mass transfer must be sensitive to variations in the reactant diffusion coefficient through floc material. A direct measure of mass flux has been developed to determine the variations in the diffusion coefficients of glucose and oxygen through microbial aggregates grown under various experimental conditions. A factorial analysis indicated significant changes in the molecular diffusion coefficient with variations in sludge age and carbon-nitrogen ratio in the growth media. Oxygen diffusivity varied from 20 to 100% of its value in water, glucose from 30 to 50%. A simple zero order diffusion-reaction kinetic model for spherical floc was constructed. It indicated that oxygen diffusion limitations are possible in the high rate activated sludge processes with large floc particles.