Centre for Nano Science and Engineering (CeNSE), Indian Institute of Science, Bangalore, Karnataka, India.
Centre for Nano Science and Engineering (CeNSE), Indian Institute of Science, Bangalore, Karnataka, India.
J Colloid Interface Sci. 2018 Nov 15;530:223-232. doi: 10.1016/j.jcis.2018.05.090. Epub 2018 Jun 28.
Coalescence time depends on the drainage rate of the fluid-bridge separating the droplets. Drainage rate is determined by external forcing and properties of the surrounding fluid. Modulating external forcing using electrowetting induced interface motion should allow control of the drainage rate, thereby affecting the coalescence time. Hence, quick coalescence or prolonged non-coalescence can be obtained for compound droplets on the microfluidic lab-on-chip systems.
Using high-speed imaging, we have investigated the effect of electrowetting induced capillary oscillations on the coalescence of compound droplets consisting of water core encapsulated in an oil shell. A systematic study was performed by varying the shell viscosity and actuation parameters (i.e. amplitude, frequency and waveform).
For actuated interface, we observed specific regimes of coalescence or non-coalescence, whereas in absence of actuation, coalescence was observed in finite time. Non-coalescence was attributed to the continuous modulation of the oil-bridge width, which was caused by the interface motion. Oil-bridge width modulation was seen to be dependent on the amplitude and shape of the excited capillary modes (axisymmetric and non-axisymmetric). These modes were tuned by the actuation parameters. This is the first report of controlling coalescence dynamics by using electrowetting induced interface motion.
聚并时间取决于分隔液滴的液桥的排液速率。排液速率由外部作用力和周围流体的性质决定。使用电润湿诱导的界面运动来调制外部作用力,应该能够控制排液速率,从而影响聚并时间。因此,可以在微流控片上系统的复合液滴上实现快速聚并或延长非聚并。
我们使用高速成像技术研究了电润湿诱导的毛细振荡对由水芯包裹在油壳中的复合液滴聚并的影响。通过改变壳粘度和激励参数(即幅度、频率和波形)进行了系统研究。
对于激励的界面,我们观察到了特定的聚并或不聚并的状态,而在没有激励的情况下,观察到了有限时间的聚并。不聚并归因于油桥宽度的连续调制,这是由界面运动引起的。油桥宽度调制被认为取决于激励的毛细模式的幅度和形状(轴对称和非轴对称)。这些模式可以通过激励参数进行调整。这是首次通过使用电润湿诱导的界面运动来控制聚并动力学的报告。
