Eddie Gonzales Jr. – MessageToEagle.com – “It has been documented since the Renaissance that an air bubble rising in water will deviate from its straight, steady path to perform a periodic zigzag or spiral motion once the bubble is above a critical size,” write researchers in their paper.
Leonardo da Vinci observed five centuries ago that air bubbles, if large enough, periodically deviate in a zigzag or spiral from straight-line movement.
Sketch by Leonardo da Vinci showing the spiral motion of an ascending bubble (from his manuscript known as the Codex Leicester). Image credit: Universidad de Sevilla
However, no quantitative description of the phenomenon or physical mechanism to explain this periodic motion had ever been found.
Researchers from the universities of Seville and Bristol have resolved this mystery regarding the instability of the trajectory of an air bubble rising in water.
Prof. Miguel Ángel Herrada, from the University of Seville, and Prof. Jens G. Eggers, from the University of Bristol, have discovered a mechanism to explain the unstable movement of bubbles rising in water. According to the researchers, the results, which are published in the prestigious journal PNAS, may be useful to understand the motion of particles whose behaviour is intermediate between a solid and a gas.
The authors of this new paper have developed a numerical discretisation technique to characterise precisely the bubble’s air-water interface, which enables them to simulate its motion and explore its stability.
Their simulations closely match high-precision measurements of unsteady bubble motion and show that bubbles deviate from a straight trajectory in water when their spherical radius exceeds 0.926 millimetres, a result within 2% of experimental values obtained with ultrapure water in the 90s.
The researchers propose a mechanism for the instability of the bubble trajectory whereby periodic tilting of the bubble changes its curvature, thus affecting the upward velocity and causing a wobble in the bubble’s trajectory, tilting up the side of the bubble whose curvature has increased.
Then, as the fluid moves faster and the fluid pressure falls around the high-curvature surface, the pressure imbalance returns the bubble to its original position, restarting the periodic cycle.
Original story – University of Seville – via EurekAlert
Written by Eddie Gonzales Jr. – MessageToEagle.com Staff