2015
DOI: 10.1007/s00348-015-2029-0
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Near-wall measurements of the bubble- and Lorentz-force-driven convection at gas-evolving electrodes

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Cited by 33 publications
(10 citation statements)
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References 45 publications
(58 reference statements)
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“…The MHD convecz E-mail: Dominik.Baczyzmalski@unibw.de tion in an electrode-parallel field is characterized by a strong shear flow with high flow velocities close to the electrode surface as shown by measurements of the velocity field in the electrode gap of an alkaline electrolyzer. 21,22 Thus, the enhanced bubble detachment for parallel fields was generally attributed to the effect of the strong MHD convection along the electrode, similar to the findings of other studies investigating the bubble detachment dynamics under forced convection. 23,24 However, the situation for a magnetic field perpendicular to the electrode is unclear.…”
supporting
confidence: 85%
“…The MHD convecz E-mail: Dominik.Baczyzmalski@unibw.de tion in an electrode-parallel field is characterized by a strong shear flow with high flow velocities close to the electrode surface as shown by measurements of the velocity field in the electrode gap of an alkaline electrolyzer. 21,22 Thus, the enhanced bubble detachment for parallel fields was generally attributed to the effect of the strong MHD convection along the electrode, similar to the findings of other studies investigating the bubble detachment dynamics under forced convection. 23,24 However, the situation for a magnetic field perpendicular to the electrode is unclear.…”
supporting
confidence: 85%
“…The second is entrainment of the microbubbles in the wake of the millimeter bubble. Because for the Type A surface the mean diameter of largesized bubbles is more than 4 mm, almost all of them show a wobbling motion (e.g., Baczyzmalski et al [33]). When a millimeter-sized bubble with wobbling motion rises near the wall, its wake causes significant diffusion of microbubbles near the wall (Fig.…”
Section: Behavior Of Bubble Layermentioning
confidence: 99%
“…In particular, references [49][50] contain treatment of various magnetoelectrolysis problems by way of simulations and experiments, examining different orientations of the Lorentz force with respect to the buoyancy force. Baczymalski and co-authors dealt with Lorentz-force effects in bubbledriven convection at gas-evolving electrodes [51][52]. In an experimental study, they showed that applying a magnetic field to a cell for water electrolysis can improve its efficiency by enhancing bubble detachment [51].…”
Section: Accepted Manuscriptmentioning
confidence: 99%
“…Baczymalski and co-authors dealt with Lorentz-force effects in bubbledriven convection at gas-evolving electrodes [51][52]. In an experimental study, they showed that applying a magnetic field to a cell for water electrolysis can improve its efficiency by enhancing bubble detachment [51]. In another paper [52], they examined the effect of buoyancy and Lorentz forces on the evolution of a single H2 bubble via both simulations and experiments.…”
Section: Accepted Manuscriptmentioning
confidence: 99%