Size control of vapor bubbles on a silver film by a tuned CW laser

Zheng, Yilin; Wang, Y.; Liu, H.; Zhu, Cheng‐Ye; Wang, S. M.; Cao, Jingxiao; Zhu, Shining

doi:10.1063/1.4730929

Cited by 9 publications

(12 citation statements)

References 20 publications

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“…The importance of studying the bubble dynamics comes from its plentiful applications which can be appeared in many branches of sciences and technology like in biomedical applications as damaging of cells [7], explaining some symptoms of some diseases like DCS (Decompression Sickness) [15], explaining volcanic eruptions [4], laser applications [26], thermal ink-jet printer [1], actuation [9], mixing [23], pumping [25] and many others.…”

Section: Introductionmentioning

confidence: 99%

Growth of a Vapour Bubble in a Superheated Liquid of Variable Surface Tension and Viscosity Between Two-phase Flow

Mohammadein¹,

Mohamed²

2013

Appl. Math. Inf. Sci.

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Abstract:The growth of a vapour bubble in a superheated liquid of variable surface tension and viscosity between two finite boundaries is introduced. The problem is solved analytically using the modified method of Plesset and Zwick method. The pressure difference is described in terms of temperature difference and initial pressure difference. The surface tension, viscosity, and initial and final time of bubble growth are derived in terms of some physical parameters. The growth of bubble radius is proportional to the thermal diffusivity, the initial pressure difference and its coefficient. On contrary the growth is inversely proportional to the initial void fraction and the density ratio. Moreover, better agreements with some experimental data are achieved rather than some of previous theoretical efforts.

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Section: Introductionmentioning

confidence: 99%

Growth of a Vapour Bubble in a Superheated Liquid of Variable Surface Tension and Viscosity Between Two-phase Flow

Mohammadein¹,

Mohamed²

2013

Appl. Math. Inf. Sci.

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“…More importantly, since the fiber guided laser power is mostly absorbed in the titanium film, the laser irradiation to the sample fluids will be minimal, which makes the device a safe choice for the manipulation of biological samples. In addition, unlike other microfluidic devices demonstrated for laser bubble generation, 3,19 there is no need for metal film deposition on substrates for chip fabrication, which allows for flexible chip design and simple fabrication with only polymer processes.…”

Section: Introductionmentioning

confidence: 99%

“…These vapor bubbles can be generated in a controlled manner at a designated location with an adjustable shape, size, and duration. [1][2][3][4] The controlled vapor bubbles have great potential to be used as micro-actuators, which have no mechanical moving parts, thus allow for simple actuator structure design and easy fabrication process. The vapor bubble-based micro-actuators have been widely utilized as microvalves, 5,6 micropumps, 7-9 micromixers, 10,11 bio-particle manipulators, 12 and droplet generators.…”

Section: Introductionmentioning

confidence: 99%

“…Electronic mail: mmyu@umd.edu typically used as mediums in microfluidic chips for converting optical energy to thermal energy. 3,19 However, the large optical power loss due to the light transmission through the optical path to the light absorbing medium is inevitable. Furthermore, the unwanted exposure of laser to the sample fluids poses another potential limitation, which can be especially harmful for biological samples.…”

Section: Introductionmentioning

confidence: 99%

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Optofluidic microvalve-on-a-chip with a surface plasmon-enhanced fiber optic microheater

et al. 2014

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We present an optofluidic microvalve utilizing an embedded, surface plasmonenhanced fiber optic microheater. The fiber optic microheater is formed by depositing a titanium thin film on the roughened end-face of a silica optical fiber that serves as a waveguide to deliver laser light to the titanium film. The nanoscale roughness at the titanium-silica interface enables strong light absorption enhancement in the titanium film through excitation of localized surface plasmons as well as facilitates bubble nucleation. Our experimental results show that due to the unique design of the fiber optic heater, the threshold laser power required to generate a bubble is greatly reduced and the bubble growth rate is significantly increased. By using the microvalve, stable vapor bubble generation in the microchannel is demonstrated, which does not require complex optical focusing and alignment. The generated vapor bubble is shown to successfully block a liquid flow channel with a size of 125 lm Â 125 lm and a flow rate of $10 ll/min at $120 mW laser power.

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“…In 2012, Hühn et al [19] studied bubble generation around nanoparticles under CW heating and to hypothesize superheating. Zheng et al [20] investigated a vapor bubble created by a focused CW laser beam on the surface of a silver film and changed the diameter and velocity of the vapor bubble by tuning the laser power. In 2013, Oara et al [21] described the bubble generation around metal nanoparticles under illumination theoretically, based on simple thermodynamics considerations.…”

mentioning

confidence: 99%

Behavior of microbubbles on spatially controlled golden nanoparticles

Liu

Jiao

2016

中国光学快报

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Incipient plasmonic bubble formation is observed around gold nanopillars with different inter-nanopillar separations. The experimental measurements and theoretical analysis show that the nanobubble formation is due to the enhanced plasmonic resonance rather than from the laser heating. Inter-nanopillar distribution may lead to threshold fluence variations. The lifetime of plasmonic bubbles can reach several minutes. Furthermore, both the radius and the growth rate of the plasmonic nanobubble increase as the inter-nanopillar distribution decreases. Smaller-spacing distributed arrays produced larger bubbles. The maximum growth rate of the bubbles can be reached at about 883.5 × 10 −6 m∕s on 1 μm nanopillars, but it is only 56.9 × 10 −6 m∕s on 4 μm nanopillars.

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Size control of vapor bubbles on a silver film by a tuned CW laser

Cited by 9 publications

References 20 publications

Growth of a Vapour Bubble in a Superheated Liquid of Variable Surface Tension and Viscosity Between Two-phase Flow

Growth of a Vapour Bubble in a Superheated Liquid of Variable Surface Tension and Viscosity Between Two-phase Flow

Optofluidic microvalve-on-a-chip with a surface plasmon-enhanced fiber optic microheater

Behavior of microbubbles on spatially controlled golden nanoparticles

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