Recent Trends in Fluid Mechanics

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In this short report, a brief review on surface-driven microfluidic flow is provided. Also, the maskless lithography and indirect bonding technique are used to fabricate a single SU-8 based glass microfluidic device. Dyed ethylene glycol is prepared as working liquid to test the fabricated device. The surface-driven microfluidic flow of dyed ethylene glycol is recorded by a CMOS camera catching 25 frames per second with a corresponding time-scale resolution of 0.04 second. This short report may be useful in future to control the working liquid inside the microfluidic lab-on-a-chip system. Liquid-microflow is slower at higher surface-area to volume ratio inside the microchannel. The surface-to-volume ratio is generally very high inside any Nanochannel. Therefore, the Liquid-flow may be stopped before the Nanochannel. Hence, only gas-Nanoflow may happen inside the Nanochannel producing the subject of Nanofluidics. Hence, this short report may be useful in future to control the working gas inside the nanofluidic lab-on-a-chip system.

SU-8; Maskless lithography; Indirect bonding; Capillary flow

S. Pati, “Fluid Mechanics and Hydraulic Machines”, 2015, McGraw Hill Education (India) Private Limited, India.

J. M. Cimbala, Y. A. Cengel, “Essentials of Fluid Mechanics: Fundamentals and Applications”, 2013, McGraw Hill Education (India) Private Limited, India.

P. J. Pritchard, J. C. Leylegian, “Fluid Mechanics”, 2014, Wiley India Private Limited, India.

S. Mukhopadhyay, J. P. Banerjee, S. S. Roy, S. K. Metya, M. Tweedie, J. A. McLaughlin, “Effects of Surface Properties on Fluid Engineering Generated by the Surface-Driven Capillary Flow of Water in Microfluidic Lab-on-a-Chip Systems for Bioengineering Applications”, Surface Review and Letters, Vol. 24, No. 3 (2017) Page 1750041.

S. Mukhopadhyay, S. S. Roy, Raechelle A. D'Sa, A. Mathur, R. J. Holmes, J. A. McLaughlin, “Nanoscale Surface Modifications to Control Capillary Flow Characteristics in PMMA Microfluidic Devices”, Nanoscale Research Letters, Vol. 6 (2011) Page 411.

S. Mukhopadhyay, J. P. Banerjee, S. S. Roy, “Effects of Channel Aspect Ratio, Surface Wettability and Liquid Viscosity on Capillary Flow through PMMA Sudden Expansion Microchannels”, Advanced Science Focus, Vol. 1, No. 2 (2013) Pages 139-144.

S. Mukhopadhyay, “Optimisation of the Experimental Methods for the Fabrication of Polymer Microstructures and Polymer Microfluidic Devices for Bioengineering Applications”, Journal of Polymer & Composites, Vol. 4, Issue 3 (2016) Pages 8-26.

S. Mukhopadhyay, “Experimental Investigations on the Durability of PMMA Microfluidic Devices Fabricated by Hot Embossing Lithography with Plasma Processing for Bioengineering Applications”, Emerging Trends in Chemical Engineering, Vol. 3, Issue 3 (2016) Pages 1-18.

W. M. Zhang, G. Meng, X. Wei, “A Review on Slip Models for Gas Microflows”, Microfluid Nanofluid, Vol. 13 (2012) Pages 845-882.

A. Agrawal, S. V. Prabhu, “Deduction of Slip Coefficient in Slip and Transition Regimes from Existing Cylindrical Couette Flow Data”, Exp. Therm. Fluid. Sci., Vol. 32 (2008) Pages 991-996.

A. Agrawal, S. V. Prabhu, “Survey on Measurement of Tangential Momentum Accommodation Coefficient”, J. Vac. Sci. Technol. A, Vol. 26 (2008) Pages 634-645.

C. K. Aidun, J. R. Clausen, “Lattice-Boltzmann Method for Complex Flows”, Annu. Rev. Fluid. Mech., Vol. 42 (2010) Pages 439-472.

S. Albertoni, C. Cercignani, L. Gotusso, “Numerical Evaluation of the Slip Coefficient”, Phys. Fluid, Vol. 6 (1963) Pages 993-996.