6 research outputs found
Observation of the Curie Transition in Palladium Bionanomaterial Using Muon Spin Rotation Spectroscopy
Palladium bionanomaterial was manufactured using the sulfate-reducing bacterium, Desulfovibrio
desulfuricans, to reduce soluble Pd(II) ions to cell-bound Pd(0). The material was examined using a
Superconducting Quantum Interference Device (SQUID) to observe bulk magnetisation over the
temperature range 10 – 300 K and by Muon Spin Rotation (μSR), which is a probe of the local magnetic
environment inside the sample, over the temperature range 200 – 700 K. Results from SQUID were used
to model the temperature dependence of ferromagnetic and paramagnetic components of the bulk
magnetisation and, by extrapolation, to predict the Curie transition temperature. Results from μSR
confirmed the accuracy of the prediction to within 20 K. The Curie transition, which started at 528 K, was
shown to be spread over a wide ( 100 K) range. This was attributed to dependence of the transition on
particle size and the range of particle sizes in the population. A competing contribution to the overall
magnetisation was observed due to partial thermal decomposition of the organic component of the
material.
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Applications of bacterial hydrogenases in waste decontamination, manufacture of novel bionanocatalysts and in sustainable energy
Bacterial hydrogenases have been harnessed to the removal of heavy metals from solution by reduction to less soluble metal species. For Pd(II), its bioreduction results in the deposition of cell-bound Pd(0)-nanoparticles that are ferromagnetic and have a high catalytic activity. Hydrogenases can also be used synthetically in the production of hydrogen from sugary wastes through breakdown of formate produced by fermentation. The Bio-H2 produced can be used to power an electrical device using a fuel cell to provide clean electricity. Production of hydrogen from confectionery wastes by one organism (Escherichia coli) can be used as the electron donor for the production of Bio-Pd0 from soluble Pd(II) by a second organism. The resulting Bio-Pd0 can then be used as a bioinorganic catalyst in the remediation of Cr(VI)-contaminated solutions or polychlorinated biphenyls at the expense of Bio-H2, as a hydrogenation catalyst for industry or as a component of a fuel cell electrode
Does soil biology hold the key to optimized slurry management? A manifesto for research
The application of agricultural biosolids to land is likely to increase on farms as pressures intensify to manage nutrients and carbon, especially with regard to slurry. Although much work has been carried out in this area, it has tended to focus on specific aspects of the application-use cycle, without a coherent framework and notably the role of soil biology has been little studied in this context, or considered appropriately in the development and application of slurry management systems. In this review article we present a hypothesis that the configuration of the soil microbial community is determined by the history of long-term inputs to which the community has been subjected and that the resultant configuration determines the instantaneous responses of the associated soil to the presence of slurries, and posit a set of critical questions which would effectively test this.</p