Ogunyinka, Oladayo Wright, Alexander Bolognesi, Guido Iza, Felipe Bandulasena, Hemaka An integrated microfluidic chip for generation and transfer of reactive species using gas plasma <p></p><p>Reactive species produced by atmospheric pressure plasma (APP) are useful in many applications including disinfection, pretreatment, catalysis, detection and chemical synthesis. Most highly reactive species produced by plasma, such as <b><sup>·</sup></b>OH, <sup>1</sup>O<sub>2</sub> and , are short-lived; therefore, in-situ generation is essential to transfer plasma products to the liquid phase efficiently. A novel microfluidic device that generates a dielectric barrier discharge (DBD) plasma at the gas-liquid interface and disperses the reactive species generated using microbubbles of ca. 200 µm in diameter has been developed and tested. As the bubble size affects the mass transfer performance of the device, the effect of operating parameters and plasma discharge on generated bubbles size has been studied. The mass transfer performance of the device was evaluated by transferring the reactive species generated to an aqueous solution containing dye and measuring percentage degradation of the dye. Monodisperse microbubbles (polydispersity index between 2 - 7%) were generated under all examined conditions but for gas flow rate exceeding a critical value, a secondary break-up event occurred after bubble formation leading to multiple monodisperse bubble populations. The generated microbubble size increased by up to ~ 8% when the device was operated with the gas plasma in the dispersed phase compared to the case without the plasma due to thermal expansion of the feed gas. At the optimal operating conditions, initial dye concentration was reduced by ~60% in a single pass with a residence time of 5-10 s. This microfluidic chip has the potential to play a significant role in lab-on-a-chip devices where highly reactive species are essential for the process. </p><br><p></p> Nanoscience & Nanotechnology;Nanotechnology;Interdisciplinary Engineering;Microfluidics;Flow-focusing;Microbubbles;DBD plasma;Plasma-liquid interface 2020-01-24
    https://repository.lboro.ac.uk/articles/journal_contribution/An_integrated_microfluidic_chip_for_generation_and_transfer_of_reactive_species_using_gas_plasma/11653668