An experimental study of Mesler entrainment on a surfactant‐covered interface: The effect of drop shape and Weber number

Mills, Brantley; Saylor, J. R.; Testik, Firat Yener

doi:10.1002/aic.12573

Cited by 16 publications

(49 citation statements)

References 36 publications

(57 reference statements)

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“…These internal drop dynamics can explain the large central bubble appearing in some of the earlier studies, e.g. figure 7(a) in Mills et al (2012).…”

Section: Bottom Puncturing By a Liquid Jetmentioning

confidence: 69%

“…The edge moves much more rapidly up away from the ruptures, again suggesting a significantly thinner air layer along the sides. Similar formation of multiple holes along a ring may explain the bubble chandeliers observed in water (Sigler & Mesler 1990;Liow & Cole 2007;Mills et al 2012). Thoroddsen, M.-J.…”

Section: Bubble Morphology: Hanging Necklaces and Bubble Chandeliersmentioning

confidence: 96%

“…Thoraval, K. Takehara and T. G Thoroddsen, Etoh & Takehara (2003) imaged detailed dynamics of the entrapment of a central bubble, along with a handful of realizations for film breakup for water drops. However, Mills, Saylor & Testik (2012) showed convincingly that the water case suffers from highly random film ruptures and is not repeatable, even if surfactants are included. Recently, Saylor & Bounds (2012) have shown that air film formation and breakup are much more repeatable for silicone oils than for water.…”

Section: Introductionmentioning

confidence: 99%

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Micro-bubble morphologies following drop impacts onto a pool surface

et al. 2012

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When a drop impacts at low velocity onto a pool surface, a hemispheric air layer cushions and can delay direct contact. Herein we use ultra-high-speed video to study the rupture of this layer, to explain the resulting variety of observed distribution of bubbles. The size and distribution of micro-bubbles is determined by the number and location of the primary punctures. Isolated holes lead to the formation of bubble necklaces when the edges of two growing holes meet, whereas bubble nets are produced by regular shedding of micro-bubbles from a sawtooth edge instability. For the most viscous liquids the air film contracts more rapidly than the capillary–viscous velocity through repeated spontaneous ruptures of the edge. From the speed of hole opening and the total volume of micro-bubbles we conclude that the air sheet ruptures when its thickness approaches ${\ensuremath{\sim} }100~\mathrm{nm} $.

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“…These internal drop dynamics can explain the large central bubble appearing in some of the earlier studies, e.g. figure 7(a) in Mills et al (2012).…”

Section: Bottom Puncturing By a Liquid Jetmentioning

confidence: 69%

Section: Bubble Morphology: Hanging Necklaces and Bubble Chandeliersmentioning

confidence: 96%

Section: Introductionmentioning

confidence: 99%

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Micro-bubble morphologies following drop impacts onto a pool surface

et al. 2012

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“…Beilharz and others frequently named Mesler entrainment (Sigler & Mesler 1990). Mills, Saylor & Testik (2012) showed that the breakup of this air layer is inherently random for water, while Saylor & Bounds (2012) demonstrated that the thin air films are much more stable for some other liquids, such as silicone oils and ethanol (Sundberg-Anderson & Saylor 2014). This repeatability allowed Thoroddsen et al (2012) to study details of the air-film breakup, employing triggered imaging with an ultra-high-speed CCD video camera (Etoh, Poggemann & Kreider 2003).…”

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confidence: 99%

Antibubbles and fine cylindrical sheets of air

Beilharz

Guyon

et al. 2015

J. Fluid Mech.

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Drops impacting at low velocities onto a pool surface can stretch out thin hemispherical sheets of air between the drop and the pool. These air sheets can remain intact until they reach submicron thicknesses, at which point they rupture to form a myriad of microbubbles. By impacting a higher-viscosity drop onto a lower-viscosity pool, we have explored new geometries of such air films. In this way we are able to maintain stable air layers which can wrap around the entire drop to form repeatable antibubbles, i.e. spherical air layers bounded by inner and outer liquid masses. Furthermore, for the most viscous drops they enter the pool trailing a viscous thread reaching all the way to the pinch-off nozzle. The air sheet can also wrap around this thread and remain stable over an extended period of time to form a cylindrical air sheet. We study the parameter regime where these structures appear and their subsequent breakup. The stability of these thin cylindrical air sheets is inconsistent with inviscid stability theory, suggesting stabilization by lubrication forces within the submicron air layer. We use interferometry to measure the air-layer thickness versus depth along the cylindrical air sheet and around the drop. The air film is thickest above the equator of the drop, but thinner below the drop and up along the air cylinder. Based on microbubble volumes, the thickness of the cylindrical air layer becomes less than 100 nm before it ruptures.

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“…The Mesler entrainment region is characterized by a number of tiny air bubbles with diameters that are 50 μm or less. 8,[12][13][14][15] Recently, it was found that daughter bubbles cascaded from the rupture of huge floating bubbles 16 can also contribute to the generation of small bubbles that are less than 1 mm. This greatly enhances the dissolution rate of gas into a liquid pool (owing to the high pressure within the tiny bubbles) and also closely tied to the climate considering aerosol droplets that form from bursting of huge bubbles.…”

mentioning

confidence: 99%

Do we understand the bubble formation by a single drop impacting upon liquid surface?

2013

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Large bubble formation by a single drop impacting upon a liquid surface with low impact energy is conventionally considered to be unimportant and not a cause for small bubble(s) generation. Our experiments contradict three widely accepted concepts about bubble formation. First, this paper presents results that give evidence of much wider existence of large bubble entrainment. Second, there is no closed characteristic regime for regular large bubble generation. Third, for the first time, there are results of bubble pair generation in sequence that show the direct formation of smaller bubble(s) due to a single large bubble rupturing without external disturbances. Additionally, this work demonstrates that the shape of an oscillating prolate drop at impact is the missing factor that helps predict large bubble formation. At the end, this paper presents a new characteristic map for large bubble formation that is based on the theoretical oscillation model.

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An experimental study of Mesler entrainment on a surfactant‐covered interface: The effect of drop shape and Weber number

Cited by 16 publications

References 36 publications

Micro-bubble morphologies following drop impacts onto a pool surface

Micro-bubble morphologies following drop impacts onto a pool surface

Antibubbles and fine cylindrical sheets of air

Do we understand the bubble formation by a single drop impacting upon liquid surface?

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