AI Article Synopsis
- Ultrasonic technology has rapidly advanced in the last decade, leading to applications like ultrasonic pasteurization and mixing immiscible liquids, driven by extreme conditions generated during bubble collapse.
- The study employs bifurcation theory to map out how gas bubbles behave in different pressure and temperature settings, particularly in viscous environments like glycerine.
- Findings indicate that below a certain temperature, bubble behavior becomes overly damped, leading to less predictable collapse behaviors, alongside the discovery of periodic regions and chaotic behavior that could affect practical applications.
Article Abstract
In the last decade many industrial applications have emerged based on the rapidly developing ultrasonic technology such as ultrasonic pasteurization, alteration of the viscosity of food systems, and mixing immiscible liquids. The fundamental physical basis of these applications is the prevailing extreme conditions (high temperature, pressure and even shock waves) during the collapse of acoustically excited bubbles. By applying the sophisticated numerical techniques of modern bifurcation theory, the present study intends to reveal the regions in the excitation pressure amplitude-ambient temperature parameter plane where collapse-like motion of an acoustically driven gas bubble in highly viscous glycerine exists. We report evidence that below a threshold temperature the bubble model, the Keller-Miksis equation, becomes an overdamped oscillator suppressing collapse-like behaviour. In addition, we have found periodic windows interspersed with chaotic regions indicating the presence of transient chaos, which is important from application point of view if predictability is required.
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| http://dx.doi.org/10.1016/j.ultsonch.2015.05.010 | DOI Listing |
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