Abstract
Surface acoustic waves in combination with microfluidics has become an attractive research field regarding its various medical and biological applications. It is sometimes preferred to solve just the fluid domain and apply some boundary conditions to represent other components rather than performing a coupled numerical solution. To account for the piezoelectric actuation, a conventional velocity distribution built by superposing the left-going and right-going surface waves is commonly used as the boundary condition, its correctness is assessed here by comparing it to a coupled solution. It was shown that the actual leaky surface acoustic wave in coupled solution has different wavelengths in its real and imaginary parts, sometimes gets out of being sinusoidal, and has a different form compared to the superposed formula. For the phase differences other than 0 and π between the left and right electrodes, the distance between the electrodes affects the streaming and acoustic fields in the microchannel thereby leading to deviations in particle traces. Furthermore, the ratio of the horizontal to vertical components of the surface wave was extracted from the coupled solutions and compared to its previously reported values. The sensitivity analysis showed that for small particles, this ratio does not affect the streaming pattern but changes its velocity magnitude causing a time lag. For larger particles, the ratio altered the movement direction. This study suggests not replacing the piezoelectric actuation with the boundary condition to avoid inaccuracy in resulting fields that are being used in calculations of particle tracing and acoustic radiation forces.
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References
Ye. Ai, C.K. Sanders, B.L. Marrone, Separation of Escherichia coli Bacteria from Peripheral Blood Mononuclear Cells Using Standing Surface Acoustic Waves. Anal. Chem. 85(19), 9126–9134 (2013)
R. Barnkob, N. Nama, L. Ren, T.J. Huang, F. Costanzo, C.J. Kähler, Acoustically driven fluid and particle motion in confined and leaky systems. Phys. Rev. Appl. (American Physical Society) 9(1), 014027 (2018)
J. Cheeke, N. David, Fundamentals and Applications of Ultrasonic Waves, Second Edition. Taylor & Francis. (2012)
M.S. Chiriacò et al., Lab-on-chip for exosomes and microvesicles detection and characterization. Sensors (Basel, Switzerland) 18(10), 3175 (2018)
P.K. Das, A.D. Snider, V.R. Bhethanabotla, Acoustothermal heating in surface acoustic wave driven microchannel flow. Phys. Fluids 31(10), 106106 (2019)
C. Devendran, T. Albrecht, J. Brenker, T. Alan, A. Neild, The importance of travelling wave components in standing surface acoustic wave (SSAW) systems. Lab Chip (The Royal Society of Chemistry) 16(19), 3756–3766 (2016)
A. Fakhfouri, C. Devendran, A. Ahmed, J. Soria, A. Neild, The size dependant behaviour of particles driven by a travelling surface acoustic wave (TSAW). Lab Chip (The Royal Society of Chemistry) 18(24), 3926–3938 (2018)
A. Gantner, R.H. Hoppe, D. Köster, K. Siebert, A. Wixforth, Numerical simulation of piezoelectrically agitated surface acoustic waves on microfluidic biochips. Comput. Vis. Sci. 10, 145–161 (2007)
J.C. Hsu, C.H. Hsu, Y.W. Huang, Acoustophoretic control of microparticle transport using dual-wavelength surface acoustic wave devices. Micromachines 10(1), 52 (2019)
D. Köster, Numerical Simulation of Acoustic Streaming on Surface Acoustic Wave-driven Biochips. SIAM J. Sci. Comput. 29(6), 2352–2380 (2007)
T. Laurell, A. Lenshof, Microscale Acoustofluidics (The Royal Society of Chemistry, 2014)
S. Lee, H. Kim, W. Lee, J. Kim, Microfluidic-based cell handling devices for biochemical applications. J. Micromech. Microeng. 28(12), 123001 (2018)
X. Liu, T. Zheng, C. Wang, Three-dimensional modeling and experimentation of microfluidic devices driven by surface acoustic wave. Ultrasonics 129, 106914 (2023)
J. Ma et al., Numerical study of acoustophoretic manipulation of particles in microfluidic channels. Proc. Inst. Mech. Eng. 235(10), 1163–1174 (2021)
Z. Mao et al., Experimental and numerical studies on standing surface acoustic wave microfluidics. Lab Chip (The Royal Society of Chemistry) 16(3), 515–524 (2016)
G. Mezzanzanica, O. Français, Towards a multi-interdigital transducer configuration to combine focusing and trapping of microparticles within a microfluidic platform: a 3D numerical analysis. Proceedings of the 8th International Electronic Conference on Sensors and Applications. Switzerland: MDPI: Basel (2021)
D. Morgan, E.G.S. Paige, 4 - Propagation effects and materials, in Surface Acoustic Wave Filters, 2nd edn. (Academic Press, Oxford, 2007), pp.87–113
N. Nama, R. Barnkob, Z. Mao, C.J. Kähler, F. Costanzo, T.J. Huang, Numerical study of acoustophoretic motion of particles in a PDMS microchannel driven by surface acoustic waves. Lab Chip (The Royal Society of Chemistry) 15(12), 2700–2709 (2015)
Z. Ni et al., Modelling of SAW-PDMS acoustofluidics: physical fields and particle motions influenced by different descriptions of the PDMS domain. Lab Chip (The Royal Society of Chemistry) 19(16), 2728–2740 (2019)
N.R. Skov, P. Sehgal, B.K. Kirby, B. Henrik, Three-dimensional numerical modeling of surface-acoustic-wave devices: acoustophoresis of micro- and nanoparticles including streaming. Physical Review Applied (American Physical Society) 12(4), (2019)
N.R. Skov, H. Bruus, Modeling of microdevices for SAW-based acoustophoresis — a study of boundary conditions. Micromachines 7(10), 182 (2016)
E. Taatizadeh et al., Micron-sized particle separation with standing surface acoustic wave—Experimental and numerical approaches. Ultrason. Sonochem. 76, 105651 (2021)
M. Wu, A. Ozcelik, J. Rufo, Z. Wang, R. Fang, T. Jun Huang, Acoustofluidic separation of cells and particles. Microsyst Nanoeng 5(32), (2019)
M. Wu et al., Separating extracellular vesicles and lipoproteins via acoustofluidics. Lab Chip (The Royal Society of Chemistry) 19(7), 1174–1182 (2019)
Y. Zhou, Comparison of numerical models for bulk and surface acoustic wave-induced acoustophoresis in a microchannel. Eur Phys J Plus 135(9), 696 (2020)
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Jazini Dorcheh: Conceptualization, Methodology, Software, Validation, and Writing the manuscript. Ghassemi: Supervision and Review.
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Jazini Dorcheh, F., Ghassemi, M. A discussion about the velocity distribution commonly used as the boundary condition in surface acoustic wave numerical simulations. Biomed Microdevices 25, 42 (2023). https://doi.org/10.1007/s10544-023-00679-7
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DOI: https://doi.org/10.1007/s10544-023-00679-7