Droplet merging in a straight microchannel using droplet size or viscosity difference

Jin, Byung-Ju; Kim, Y. W.; Lee, Y.; Yoo, Jung Yul

doi:10.1088/0960-1317/20/3/035003

Cited by 70 publications

(52 citation statements)

References 35 publications

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“…7a, c respectively) suggests that the change in topology from S 1 (λ < 1) to S 3 (λ > 1) is attributable to the increase in λ. Droplet circulation is suppressed and a more uniform flow pattern is established in 5 the more viscous S 3 droplets which can be explained on the basis of Equation (1). The observed changes in the droplet flow pattern are also illustrated analytically by Jin et al 38 for capillary droplet flows. Their analytical velocity profiles showed that at low λ, the droplet tended to adopt a parabola-like topology in the bulk-10 volume, whereas with increasing λ, a more uniform distribution was established.…”

mentioning

confidence: 69%

On the flow topology inside droplets moving in rectangular microchannels

Sherwood

Huck

et al. 2014

Lab Chip

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The flow topology in moving microdroplets has a significant impact on the behaviour of encapsulated objects and hence on applications of the technology. This study reports on a systematic investigation of the flow field inside droplets moving in a rectangular microchannel, by means of micro-particle image velocimetry (µPIV). Various water/oil (w/o) fluid mixtures were studied in order to elucidate the effects of a number of parameters such as capillary number (Ca), droplet geometry, viscosity ratio and interfacial 10 tension. A distinct change in flow topology was observed at intermediate Ca ranging from 10 -3 to 10 -1 , in surfactant-laden droplets, which was attributed primarily to the viscosity ratio of the two phases rather than the Marangoni effect expected in such systems. W/o droplet systems of lower inner-to-outer viscosity ratios tend to exhibit the well-known flow pattern characterised by a parabola-like profile in the droplet bulk-volume, surrounded by two counter rotating recirculation zones on either side of the droplet 15 axis. As the viscosity ratio between the two phases is increased, the flow pattern becomes more uniform, exhibiting low velocities in the droplet bulk-volume and higher-reversed velocities along the w/o interface. The Ca and droplet geometry had no effect on the observed flow topology change. The study highlights the complex, three-dimensional (3D) nature of the flow inside droplets in rectangular microchannels and demonstrates the ability to control the droplet flow environment by adjusting the 20 viscosity ratio between the two phases.

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mentioning

confidence: 69%

On the flow topology inside droplets moving in rectangular microchannels

Sherwood

Huck

et al. 2014

Lab Chip

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“…Partially confined, high viscosity droplets undergo a stronger viscous dissipation and therefore move slower than low viscosity droplets of equal radius (and confinement). This allows low viscosity droplets to catch up with high viscosity droplets, resulting in coalescence [27]. Similarly, droplets of different radius behave differently.…”

Section: Drag Force and Viscous Dissipationmentioning

confidence: 99%

Droplet Manipulations in Two Phase Flow Microfluidics

2015

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Even though droplet microfluidics has been developed since the early 1980s, the number of applications that have resulted in commercial products is still relatively small. This is partly due to an ongoing maturation and integration of existing methods, but possibly also because of the emergence of new techniques, whose potential has not been fully realized. This review summarizes the currently existing techniques for manipulating droplets in two-phase flow microfluidics. Specifically, very recent developments like the use of acoustic waves, magnetic fields, surface energy wells, and electrostatic traps and rails are discussed. The physical principles are explained, and (potential) advantages and drawbacks of different methods in the sense of versatility, flexibility, tunability and durability are discussed, where possible, per technique and per droplet operation: generation, transport, sorting, coalescence and splitting.

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“…Since the droplet pairs with different compositions are possible to be formed, it can be used for indexing the concentrations of solutes in a droplet, protein crystallization 13 or used as an initial process in droplet-merging techniques. [14][15][16] The stable formation of droplets is expected in such a way that the miniature volume of each dispersed flow is controllable as accurately as possible. As a result, investigations on the dynamic behavior of multiphase flows in a microfluidic double T-junction device are required in order to determine flow conditions, channel geometries, and fluid properties for generating stable alternating droplets.…”

Section: Introductionmentioning

confidence: 99%

“…In addition, the formation of different droplets by using different viscosities of two dispersed flow streams or different flow rates was shown by Jin et al 14 Empirical formulas of flow rate range of dispersive flow fluids were also proposed in his paper with the aim of choosing the best inflow conditions for alternating droplet formation (ADF). Another form of the double T-junction that includes tapered expansion chamber and two triangular wings placed at T-junction was also used to generated ADF by reducing the flow instability and preventing reagents from back flowing.…”

Section: Introductionmentioning

confidence: 99%

A numerical study on the dynamics of droplet formation in a microfluidic double T-junction

et al. 2015

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In this study, droplet formations in microfluidic double T-junctions (MFDTD) are investigated based on a two-dimensional numerical model with volume of fluid method. Parametric ranges for generating alternating droplet formation (ADF) are identified. A physical background responsible for the ADF is suggested by analyzing the dynamical stability of flow system. Since the phase discrepancy between dispersed flows is mainly caused by non-symmetrical breaking of merging droplet, merging regime becomes the alternating regime at appropriate conditions. In addition, the effects of channel geometries on droplet formation are studied in terms of relative channel width. The predicted results show that the ADF region is shifted toward lower capillary numbers when channel width ratio is less than unity. The alternating droplet size increases with the increase of channel width ratio. When this ratio reaches unity, alternating droplets can be formed at very high water fraction (wf ¼ 0.8). The droplet formation in MFDTD depends significantly on the viscosity ratio, and the droplet size in ADF decreases with the increase of the viscosity ratio. The understanding of underlying physics of the ADF phenomenon is useful for many applications, including nanoparticle synthesis with different concentrations, hydrogel bead generation, and cell transplantation in biomedical therapy. V C 2015 AIP Publishing LLC. [http://dx

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Droplet merging in a straight microchannel using droplet size or viscosity difference

Cited by 70 publications

References 35 publications

On the flow topology inside droplets moving in rectangular microchannels

On the flow topology inside droplets moving in rectangular microchannels

Droplet Manipulations in Two Phase Flow Microfluidics

A numerical study on the dynamics of droplet formation in a microfluidic double T-junction

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