Impact and lifecycle of superfluid helium drops on a solid surface
AuthorsWallace, Matthew L.
Aguirre-Pablo, Andres A.
Thoroddsen, Sigurdur T
KAUST DepartmentHigh-Speed Fluids Imaging Laboratory
Mechanical Engineering Program
Physical Science and Engineering (PSE) Division
KAUST Grant NumberURF/1/2621-01-01
Permanent link to this recordhttp://hdl.handle.net/10754/665077
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AbstractWe have used high-speed video and interferometry to investigate the impact, spreading, and eventual contraction of superfluid 4 He drops on a sapphire substrate in a saturated atmosphere of helium vapor. We find that the short-term kinetic spreading of superfluid drops (time t<10 ms) is qualitatively similar to both normal helium and conventional fluids at room temperature. In contrast, the contraction phase of the superfluid drops is highly unusual. Superfluid drops survive for only a few seconds on the substrate due to superflow out of the drop into the surrounding helium film. The drop lifetime is strongly dependent on temperature and diverges at the superfluid transition temperature Tλ∼2.17 K. The contracting drops undergo a geometry-dependent two-phase contraction, which includes a toroidal phase where the radius decreases linearly in time and subsequently a spherical cap phase where the radius decreases with the square root of time. The receding contact angle is temperature dependent and becomes small near Tλ. We also observe that the superfluid outflow causes surprising edge effects, including the emergence of satellite droplets on the perimeter of the expanding drop, as well as ragged and frayed drop edges at lower temperatures.
CitationWallace, M. L., Mallin, D., Milgie, M., Aguirre-Pablo, A. A., Langley, K. R., Thoroddsen, S. T., & Taborek, P. (2020). Impact and lifecycle of superfluid helium drops on a solid surface. Physical Review Fluids, 5(9). doi:10.1103/physrevfluids.5.093602
SponsorsThis research was supported by King Abdullah University of Science and Technology (KAUST) under Grant No. URF/1/2621-01-01.
PublisherAmerican Physical Society (APS)
JournalPhysical Review Fluids