Analyses of acoustofluidic field in ultrasonic needle–liquid–substrate system for micro-/nanoscale material concentration

Research Paper
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Abstract

The ultrasonic needle–liquid–substrate system, in which an ultrasonically vibrating steel needle is inserted into an aqueous suspension film of micro-/nanoscale materials on a nonvibration silicon substrate, has large potential applications in micro-/nanoconcentration. However, research on its detailed concentration mechanism and the structural parameters’ effect on concentration characteristics has been scarce. In this work, the acoustic streaming field and acoustic radiation force in an ultrasonic needle–liquid–substrate system, which are generated by a vibrating needle parallel to the substrate, are numerically investigated by the finite element method. The computational results show that the ultrasonic needle’s vibration can generate the acoustic streaming field capable of concentrating micro-/nanoscale materials, and the acoustic radiation force has little contribution to the concentration. The computation results well explain the experimental phenomena that the micro-/nanoscale materials can be concentrated at some conditions and cannot at others. The computational results clarify the effects of the distance between the needle center and substrate surface, the needle’s radius, the water film’s height and radius and the shape of the needle’s cross section on the acoustic streaming field and concentration capability.

Keywords

Ultrasound Vortex Micro-/nanoscale material Concentration FEM 

Notes

Acknowledgements

This work is supported by the following funding organizations in China: National Basic Research Program of China (973 Program, Grant No. 2015CB057501), National Natural Science Foundation of China (Grant 51505222), State Key Lab of Mechanics and Control of Mechanical Structures (Grant No. MCMS-0318K01), Postgraduate Research and Practice Innovation Program of Jiangsu Province (No. KYCX17_0237) and the Fundamental Research Funds for the Central Universities.

References

  1. Barnkob R, Augustsson P, Laurell T, Bruus H (2012) Acoustic radiation- and streaming-induced microparticle velocities determined by microparticle image velocimetry in an ultrasound symmetry plane. Phys Rev E Stat Nonlinear Soft Matter Phys 86(5 Pt 2):056307CrossRefGoogle Scholar
  2. Beyer RT (1965) Nonlinear acoustics. In: Mason WP (ed) Physical acoustics, vol 2B. Academic Press, New York, pp 231–263Google Scholar
  3. Beyer RT (1997) The parameter B/A. In: Hamilton MF, Blackstock DT (eds) Nonlinear acoustics: theory and applications. Academic Press, New York, pp 25–39Google Scholar
  4. Bruus H, Dual J, Hawkes J, Hill M, Laurell T, Nilsson J, Radel S, Sadhal S, Wiklund M (2011) Forthcoming Lab on a Chip tutorial series on acoustofluidics: acoustofluidics-exploiting ultrasonic standing wave forces and acoustic streaming in microfluidic systems for cell and particle manipulation. Lab Chip 11(21):3579–3580CrossRefGoogle Scholar
  5. Buso OP, Colautti P, Moschini G, Hu X, Stievano BM (1984) High sensitivity PIXE determination of selenium in biological samples using a preconcentration technique. Nucl Instrum Methods B 3(1–3):177–180CrossRefGoogle Scholar
  6. Ding X, Lin SS, Kiraly B, Yue H, Li S, Chiang IK, Shi J, Benkovic SJ, Huang TJ (2012) On-chip manipulation of single microparticles, cells, and organisms using surface acoustic waves. Proc Natl Acad Sci USA 109(28):11105–11109CrossRefGoogle Scholar
  7. Gor’Kov LP (1962) On the forces acting on a small particle in an acoustical field in an ideal fluid. Sov Phys Dokl 6(1):773Google Scholar
  8. Hahn P, Leibacher I, Baasch T, Dual J (2015) Numerical simulation of acoustofluidic manipulation by radiation forces and acoustic streaming for complex particle. Lab Chip 15(22):4302–4313CrossRefGoogle Scholar
  9. Hasegawa T, Yosioka K (2005) Acoustic-radiation force on a solid elastic sphere. J Acoust Soc Am 69(4):937–942CrossRefMATHGoogle Scholar
  10. Hasegawa T, Saka K, Inoue N, Matsuzawa K (1988) Acoustic radiation force experienced by a solid cylinder in a plane progressive sound field. J Acoust Soc Am 83(5):1770–1775CrossRefGoogle Scholar
  11. Hawkes JJ, Limaye MS, Coakley WT (1997) Filtration of bacteria and yeast by ultrasound-enhanced sedimentation. J Appl Microbiol 82(1):39–47CrossRefGoogle Scholar
  12. Hu J (2014) Ultrasonic micro/nano manipulations: principles and examples. World Scientific Publishing, SingaporeCrossRefGoogle Scholar
  13. Hu J, Zhu H, Li N, Zhao C (2011) Sound induced lobed pattern in aqueous suspension film of micro particles. Sens Actuat A Phys 167(1):77–83CrossRefGoogle Scholar
  14. Khoo HS, Lin C, Huang SH, Tseng FG (2011) Self-assembly in micro- and nanofluidic devices: a review of recent efforts. Micromachines 2(1):17–48CrossRefGoogle Scholar
  15. Kinsler LE, Frey AR, Coppens AB, Sanders JV (1999) Fundamentals of acoustics. Hamilton Press, Te RapaGoogle Scholar
  16. Kubota N, Yokota M, Mullin JW (2000) The combined influence of supersaturation and impurity concentration on crystal growth. J Cryst Growth 212(3–4):480–488CrossRefGoogle Scholar
  17. Kulkarni GS, Zhong Z (2013) Fabrication of carbon nanotube high-frequency nanoelectronic biosensor for sensing in high ionic strength solutions. Jove J Vis Exp 77:e50438Google Scholar
  18. Kuznetsov YG, Malkin AJ, Mcpherson A (2001) The influence of precipitant concentration on macromolecular crystal growth mechanisms. J Cryst Growth 232(1–4):114–118CrossRefGoogle Scholar
  19. Liebermann LN (1949) The second viscosity of liquids. Phys Rev 75:1415–1422CrossRefGoogle Scholar
  20. Lighthill J (1978) Acoustic streaming. J Sound Vib 61(3):391–418CrossRefMATHGoogle Scholar
  21. Liu P, Hu J (2017) Controlled removal of micro/nanoscale particles in submillimeter-diameter area on a substrate. Rev Sci Instrum 88(10):105003CrossRefGoogle Scholar
  22. Liu H, Zhai J, Jiang L (2006) The research progress in self-assembly of nano-materials. Chin J Inorg Chem 22(4):585–597Google Scholar
  23. Minuth WW, Sittinger M, Kloth S (1998) Tissue engineering: generation of differentiated artificial tissues for biomedical applications. Cell Tissue Res 291(1):1–11CrossRefGoogle Scholar
  24. Muller PB, Barnkob R, Jensen MJ, Bruus H (2012) A numerical study of microparticle acoustophoresis driven by acoustic radiation forces and streaming-induced drag forces. Lab Chip 12(22):4617–4627CrossRefGoogle Scholar
  25. Sittinger M, Schultz O, Keyszer G, Minuth WW, Burmester GR (1997) Artificial tissues in perfusion culture. Int J Artif Organs 20(1):57–62CrossRefGoogle Scholar
  26. Surhone LM, Timpledon MT, Marseken SF, Stokes GG (2010) Stokes’ law. Betascript PublishingGoogle Scholar
  27. Tang Q, Hu J (2015a) Diversity of acoustic streaming in a rectangular acoustofluidic field. Ultrasonics 58:27–34CrossRefGoogle Scholar
  28. Tang Q, Hu J (2015b) Analyses of acoustic streaming field in the probe-liquid-substrate system for nanotrapping. Microfluid Nanofluid 19(6):1395–1408CrossRefGoogle Scholar
  29. Tang Q, Hu J, Qian S, Zhang X (2017a) Eckart acoustic streaming in a heptagonal chamber by multiple acoustic transducers. Microfluid Nanofluid 21:28CrossRefGoogle Scholar
  30. Tang Q, Wang X, Hu J (2017b) Nano concentration by acoustically generated complex spiral vortex field. Appl Phys Lett 110(10):104105CrossRefGoogle Scholar
  31. Vincent B, Destefanis V (2013) Method for fabricating a micro-electronic device equipped with semi-conductor zones on an insulator with a horizontal GE concentration gradient. US Patent, US 8,501,596 B2Google Scholar
  32. Wang H, Lu Y (2012) Morphological control of self-assembly polyaniline micro/nano-structures using dichloroacetic acid. Synth Met 162(15–16):1369–1374CrossRefGoogle Scholar
  33. Yang B, Hu J (2014) Linear concentration of microscale samples under an ultrasonically vibrating needle in water on a substrate surface. Sens Actuat B Chem 193:472–477CrossRefGoogle Scholar
  34. Zhou R, Wang P, Chang H (2006) Bacteria capture, concentration and detection by alternating current dielectrophoresis and self-assembly of dispersed single-wall carbon nanotubes. Electrophoresis 27(7):1376–1385CrossRefGoogle Scholar
  35. Zhou Y, Hu J, Bhuyan S (2013) Manipulations of silver nanowires in a droplet on low-frequency ultrasonic stage. IEEE Trans Ultrason Ferroelectr Freq Control 60(3):622–629CrossRefGoogle Scholar

Copyright information

© Springer-Verlag GmbH Germany, part of Springer Nature 2018

Authors and Affiliations

  1. 1.State Key Lab of Mechanics and Control of Mechanical StructuresNanjing University of Aeronautics and AstronauticsNanjingChina

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