Browsing by Author "Rolph, Catherine"
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Item Open Access Data for the paper "From full-scale biofilters to bioreactors: engineering biological metaldehyde removal"(Cranfield University, 2019-07-17 11:45) Hassard, Francis; Jefferson, Bruce; Villa, Raffaella; Brookes, Adam; Choya, Andoni; Iceton, Gregg; Rolph, CatherineDatasets for Rolph, C.A., Villa, R., Jefferson, B., Brookes, A., Choya, A., Iceton, G. and Hassard, F., 2019. From full-scale biofilters to bioreactors: engineering biological metaldehyde removal. Science of the Total Environment, 685, pp.410-41.Item Open Access Metaldehyde removal from drinking water by adsorption on to filtration media and polymeric sorbents: mechanisms and optimisation(Cranfield University, 2018-10-22 11:54) Hassard, Francis; Rolph, Catherine; Jefferson, Bruce; Villa, Raffaella; Rolph, Catherine; Jefferson, Bruce; Villa, Raffaella; Hassard, FrancisThis study sheds light into adsorption of metaldehyde to different polymeric sorbents. Biologically active carbon had the greatest metaldehyde adsorption capacity. Natural organic matter reduced metaldehyde removal in competitive sorption environments. We theorized that microbial biofilms and thermal hydrolysis represent effective strategies for improving metaldehyde removal and reducing the rapid saturation of filtration media.Item Open Access Supplementary data to Metaldehyde removal from drinking water by adsorption on to filtration media and polymeric sorbents: mechanisms and optimisation(Cranfield University, 2018-10-22 11:55) Rolph, Catherine; Jefferson, Bruce; Villa, Raffaella; Hassard, FrancisThis study sheds light into adsorption of metaldehyde to different polymeric sorbents. Biologically active carbon had the greatest metaldehyde adsorption capacity. Natural organic matter reduced metaldehyde removal in competitive sorption environments. We theorized that microbial biofilms and thermal hydrolysis represent effective strategies for improving metaldehyde removal and reducing the rapid saturation of filtration media.