Breakup of air bubbles in water: Memory and breakdown of cylindrical symmetry

Nathan C. Keim; Peder Møller; Wendy W. Zhang; Sidney R. Nagel

doi:10.1103/PhysRevLett.97.144503

Breakup of air bubbles in water: Memory and breakdown of cylindrical symmetry

Nathan C. Keim
, Peder Møller
, Wendy W. Zhang
, Sidney R. Nagel

Physics

Research output: Contribution to journal › Article › peer-review

87 Scopus citations

Abstract

Using high-speed video, we have studied air bubbles detaching from an underwater nozzle. As a bubble distorts, it forms a thin neck which develops a singular shape as it pinches off. As in other singularities, the minimum neck radius scales with the time until the breakup. However, because the air-water interfacial tension does not drive the breakup, even small initial cylindrical asymmetries are preserved throughout the collapse. This novel, nonuniversal singularity retains a memory of the nozzle shape, size, and tilt angle. In the last stages, the air appears to tear instead of pinch.

Original language	English (US)
Article number	144503
Journal	Physical review letters
Volume	97
Issue number	14
DOIs	https://doi.org/10.1103/PhysRevLett.97.144503
State	Published - 2006

All Science Journal Classification (ASJC) codes

General Physics and Astronomy

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10.1103/PhysRevLett.97.144503

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abstract = "Using high-speed video, we have studied air bubbles detaching from an underwater nozzle. As a bubble distorts, it forms a thin neck which develops a singular shape as it pinches off. As in other singularities, the minimum neck radius scales with the time until the breakup. However, because the air-water interfacial tension does not drive the breakup, even small initial cylindrical asymmetries are preserved throughout the collapse. This novel, nonuniversal singularity retains a memory of the nozzle shape, size, and tilt angle. In the last stages, the air appears to tear instead of pinch.",

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AU - Nagel, Sidney R.

PY - 2006

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AB - Using high-speed video, we have studied air bubbles detaching from an underwater nozzle. As a bubble distorts, it forms a thin neck which develops a singular shape as it pinches off. As in other singularities, the minimum neck radius scales with the time until the breakup. However, because the air-water interfacial tension does not drive the breakup, even small initial cylindrical asymmetries are preserved throughout the collapse. This novel, nonuniversal singularity retains a memory of the nozzle shape, size, and tilt angle. In the last stages, the air appears to tear instead of pinch.

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Breakup of air bubbles in water: Memory and breakdown of cylindrical symmetry

Abstract

All Science Journal Classification (ASJC) codes

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