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Dr GEORGIOS DIMITRAKIS's Outputs (44)

Enhanced ‘in situ’ catalysis via microwave selective heating: catalytic chain transfer polymerisation (2014)
Journal Article
Adlington, K., McSweeney, R., Dimitrakis, G., Kingman, S. W., Robinson, J. P., & Irvine, D. J. (2014). Enhanced ‘in situ’ catalysis via microwave selective heating: catalytic chain transfer polymerisation. RSC Advances, 4(31), 16172-16180. https://doi.org/10.1039/c4ra00907j

An extremely facile, single stage, ‘in-situ’, Catalytic Chain Transfer Polymerisation (CCTP) process has been identified, where the optimal polymerisation process was shown to depend upon a combination of catalyst characteristics (i.e. solubility, se... Read More about Enhanced ‘in situ’ catalysis via microwave selective heating: catalytic chain transfer polymerisation.

Continuous and direct 'in situ' reaction monitoring of chemical reactions via dielectric property measurement: Controlled polymerisation (2014)
Journal Article
Lester, E., Kamaruddin, M. J., Nguyen, N. T., Robinson, J., El harfi, J., Irvine, D., Binner, E. R., DIMITRAKIS, G., & Kingman, S. W. (2014). Continuous and direct 'in situ' reaction monitoring of chemical reactions via dielectric property measurement: Controlled polymerisation. RSC Advances, 4(11), 5709-5717. https://doi.org/10.1039/c3ra46941g

Separation of oil/water emulsions in continuous flow using microwave heating (2013)
Journal Article
Binner, E., Robinson, J. P., Kingman, S., Lester, E., Azzopardi, B. J., Dimitrakis, G., & Briggs, J. (2013). Separation of oil/water emulsions in continuous flow using microwave heating. Energy and Fuels, 27(6), https://doi.org/10.1021/ef400634n

This work studies a continuous flow microwave system to enhance gravity settling of water-in-oil emulsions. Settling times were found to be dependent upon the applied power, flowrate and energy input. Power and energy input are linked to liquid flowr... Read More about Separation of oil/water emulsions in continuous flow using microwave heating.