Synopsis

Can’t Burst This Bubble

Physics 6, s20
A new theory attempts to explain the exceptionally long life of air nanobubbles on wet surfaces.
Courtesy Michiel van Limbeek and Joost H. Weijs/University of Twente

How long an air bubble lives in water depends critically on its size. Because of surface tension, the smaller the radius of curvature of the bubble, the easier it is for the bubble to leak gas and collapse. Bubbles smaller than 100 nanometers in diameter should last less than a few microseconds. However, recent observations show that on a solid surface covered by water, nanobubbles can live as much as ten orders of magnitude longer than free bubbles (up to days). No satisfactory explanation for this property has been found, but now, writing in Physical Review Letters, Joost H. Weijs and Detlef Lohse at the University of Twente in the Netherlands claim to have solved this riddle.

The authors’ theory is based on conventional diffusion physics but accounts for the specificity of the surface bubble geometry. Two effects play a major role in the model. First, as the bubbles leak gas, they stick to the same area on the surface and get thinner and flatter. The radius of curvature thus increases, making them more stable. Second, a sort of “traffic jam” effect occurs: Since the liquid is typically saturated with gas, an individual bubble can only leak its gas into the liquid if a corresponding amount of gas is released into the atmosphere. This dramatically reduces the speed at which the gas can leave the bubble.

The theory yields lifetimes consistent with previous observations. Should it be validated by further experimental tests, the model may assist a vast array of applications. These range from the transport of anticancer drugs across biological membranes to friction-reduction in nanofluidic devices, where nanobubble coatings could be deposited on the surface of nanochannels to facilitate the passage of fluids. – Matteo Rini


Subject Areas

NanophysicsFluid Dynamics

Related Articles

Windbreaks May Improve Wind Farm Power
Fluid Dynamics

Windbreaks May Improve Wind Farm Power

Simulations suggest that optimally placed barriers could boost wind farm performance by as much as 10%. Read More »

Testing a 150-year-old Hydrodynamics Prediction
Fluid Dynamics

Testing a 150-year-old Hydrodynamics Prediction

A new experiment finds that a sphere with “fins” maintains its orientation in a flowing fluid, despite a 19th century prediction that it would spin. Read More »

Binary Liquid Mixtures Form Flattened Droplets
Soft Matter

Binary Liquid Mixtures Form Flattened Droplets

Droplets made of a mixture of two liquids with different volatilities take on a pancake shape. Read More »

More Articles