1. Ice scallops: a laboratory investigation of the ice–water interface
- Author
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Mitchell Bushuk, Callum Gray, Timothy P. Stanton, A. A. Stern, and David M. Holland
- Subjects
Physics::Biological Physics ,010504 meteorology & atmospheric sciences ,Turbulence ,Mechanical Engineering ,Applied Mathematics ,Ripple ,Mechanics ,Condensed Matter Physics ,Quantitative Biology::Other ,01 natural sciences ,Article ,010305 fluids & plasmas ,Physics::Fluid Dynamics ,Flume ,Boundary layer ,Wavelength ,Particle image velocimetry ,Mechanics of Materials ,0103 physical sciences ,Scallop ,Turbulence kinetic energy ,Astrophysics::Earth and Planetary Astrophysics ,Physics::Atmospheric and Oceanic Physics ,Geology ,0105 earth and related environmental sciences - Abstract
Ice scallops are a small-scale (5–20 cm) quasi-periodic ripple pattern that occurs at the ice–water interface. Previous work has suggested that scallops form due to a self-reinforcing interaction between an evolving ice-surface geometry, an adjacent turbulent flow field and the resulting differential melt rates that occur along the interface. In this study, we perform a series of laboratory experiments in a refrigerated flume to quantitatively investigate the mechanisms of scallop formation and evolution in high resolution. Using particle image velocimetry, we probe an evolving ice–water boundary layer at sub-millimetre scales and 15 Hz frequency. Our data reveal three distinct regimes of ice–water interface evolution: a transition from flat to scalloped ice; an equilibrium scallop geometry; and an adjusting scallop interface. We find that scalloped-ice geometry produces a clear modification to the ice–water boundary layer, characterized by a time-mean recirculating eddy feature that forms in the scallop trough. Our primary finding is that scallops form due to a self-reinforcing feedback between the ice-interface geometry and shear production of turbulent kinetic energy in the flow interior. The length of this shear production zone is therefore hypothesized to set the scallop wavelength.
- Published
- 2019
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