Calum Ryan
Department / Institute
RESEARCH PROFILE
As a PhD Student at Eindhoven University of Technology, Calum Ryan will be primarily researching the fluid dynamic properties of various liquid targets, with a focus on water samples, undergoing interactions with non thermal atmospheric pressure plasma jets (APPJ), and how different flow properties can be obtained and manipulated by varying the parameters of both the plasma jet and liquid target that are being used. The topic of flow has had a limited exploration within research in this field, and understanding the basic fluid properties in interactions is of paramount importance to then being able to improve the wide variety of applications of APPJ’s; for example understanding how the various plasma parameters within the system effect the physical and flow properties of the target will allow for optimization in choosing the correct jet for the required system. From wound treatment in medical physics, to enhancing seed germination in agriculture, the growing of understanding these systems would be a benefit that a wide variety of fields could take advantage of. Ryan is doing his PhD within the group Elementary Processes in Gas Discharges.
ACADEMIC BACKGROUND
Having previously worked within plasma physics during his time as a Masters student at the University of Strathclyde in Scotland, Ryan achieved the integrated Masters degree of MPhys in Physics with distinction. During his time at Strathclyde he worked on the theory of properties of plasmas generated in intense laser-solid interactions, and on the correlation of varying target properties to the growth rate of quasi-static magnetic field structures, whose growth have previously been shown to relate to the growth of plasma instabilities within these systems. By working out how to create targets that will reduce the growth of these instabilities, the efficiency of laser-solid interactions for thin target systems, and the subsequent generation of proton beams, can be improved.
Recent Publications
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Electrical properties determine the liquid flow direction in plasma-liquid interactions
Scientific Reports (2024) -
Investigating Plasma Induced Liquid Surface Shear Stresses with Respect to Ion Drift Velocity
(2024) -
Dynamic Flow Direction Switching in Plasma-Electrolyte Interactions
(2024) -
Surface Effects Drive Plasma Induced Flow in Purified Aqueous Solutions
(2024) -
Atmospheric Plasmas Induce Electrolytic-Like Flows In Grounded Solutions
(2023)
Ancillary Activities
No ancillary activities