报 告 人：关剑辉 (James Guan) (University of North Carolina at Chapel Hill

报告时间：2025-1-17 10：00-11:00

报告地点：致源楼1206

主办单位：深圳大学物理与光电工程学院

报告人简介：

        Dr Jian Hui (James) Guan  received his Ph.D. in Physics from the University of Northumbria at  Newcastle in 2017. He then worked as a post-doctoral research assistant  in the Department of Engineering Science at the University of Oxford.  Currently, he is a post-doctoral research associate in the Mathematics  Department at UNC at Chapel Hill, where he doubles as an Assistant  Teaching Professor in Mathematics. His expertise lies in experimental  fluid mechanics, soft matter physics, and plant sciences. His research  is published in Science Advances, Physical Review Letters, Langmuir,  Soft Matter, Physical Review Applied, Physical Review Fluids, Scientific  Reports, Journal of the Royal Society Interface, and most recently, in  Nature Communications. His research has been recognized by awards such  as the two APS' DFD Gallery of Fluid Motion award (including one Milton  Van Dyke award) and has featured in National Geographic and the cover of  Sciences Advances.

报告摘要:

        In  part one of this three-part talk, I will talk about the world's largest  floating leaves - the giant Amazonian waterlily (genus Victoria). We  studied how the structural form of the vasculature system underpins  gigantism in these extraordinary leaves and inferred how this unique  form of leaf gigantism evolved. Specifically, by means of mechanical  testing and geometrical modelling, we found that the bending resistance  of the Amazonian waterlily is considerably higher than of an elastic  floating sheet of the same amount of material. In the second part, I  will present a spontaneous symmetry-breaking instability that transforms  standing Faraday waves into rapidly traveling waves, rotating either  clockwise or anti-clockwise, in annular geometries. Combining  experiments and simulations, we show that this traveling instability is  driven and significantly enhanced by capillary effects, including  wettability and contact-line dynamics. In the last part, I will  demonstrate that vertically vibrated bubbles near a wall may undergo a  spontaneous symmetry breaking in their harmonic shape oscillations,  leading to steady propulsive motion. We characterize the dynamics of  these self-propelled, or `galloping', bubbles in terms of the key system  parameters, including bubble volume, driving frequency, and  acceleration. Our results reveal that the bubble propulsion is  intimately related to their resonant shape oscillations, which can be  fine-tuned to produce a myriad of dynamics including rectilinear,  orbital, and run-and-tumble motions.