Abstract
We report a novel scheme for steering a high-velocity continuous droplet stream using the dielectrophoretic force. The droplet stream is created using the continuous ink jet method. A liquid jet is ejected from a nozzle at high pressure and is controllably broken up into uniform droplets 30–90 μm in diameter with velocities up to 20 m/s. Voltages up to 2 kV are used to energize a high-voltage probe located downstream from the nozzle to induce the formation of a nonuniform electric field in the vicinity of the probe tip. The stream is passed through the electric field, subjecting the droplets to the dielectrophoretic force in the direction of the electric field maxima. Our scheme provides precise displacement of the droplet stream and requires less hardware than traditional steering methods. Less hardware means the distance between the printing nozzle and receiving substrate is minimized, enabling more accurate droplet positioning and higher print resolution. Other applications of high-voltage dielectrophoresis for droplet steering includes on/off control and manipulation (or removal) of satellite droplets. A simple linear relationship predicts the deflection of the droplet stream in the vicinity of a high-voltage probe as a function of the governing parameters. This relationship holds true for a large range of droplet sizes, stream velocities, geometries, and electric field strengths.
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References
Basaran OA, Gao H, Bhat PP (2013) Nonstandard inkjets. Annu Rev Fluid Mech 45(1):85–113
Blazdell P, Kuroda S (2000) Plasma spraying of submicron ceramic suspensions using a continuous ink jet printer. Surf Coat Technol 123(2–3):239–246
Blazdell PF, Evans JRG, Edirisinghe MJ, Shaw P, Binstead MJ (1995) The computer aided manufacture of ceramics using multilayer jet printing. J Mater Sci Lett 14(22):1562–1565
Calvert P (2001) Inkjet printing for materials and devices. Chem Mater 13(10):3299–3305
Chang H-C, Yeo L (2010) Electrokinetically-driven microfluidics and nanofluidics. Cambridge University Press, New york
Chiarot PR, Jones TB (2009) Dielectrophoretic deflection of ink jets. J Micromech Microeng 19(12):125018
Chiarot PR, Jones TB (2010) Grazing impact of continuous droplet streams with a superhydrophobic surface. Exp Fluids 49(5):1109–1119
Diepold T, Obermeier E, Berchtold A (1998) A micromachined continuous ink jet print head for high-resolution printing. J Micromech Microeng 8(2):144–147
El-Ali J, Sorger PK, Jensen KF (2006) Cells on chips. Nature 442(7101):403–411
Hager DB, Dovichi NJ (1994) Behavior of microscopic liquid droplets near a strong electrostatic field: droplet electrospray. Anal Chem 66(9):1593–1594
Jones TB (1995) Electromechanics of particles. Cambridge University Press, New York
Jones TB, Bliss GW (1977) Bubble dielectrophoresis. J Appl Phys 48(4):1412
Kettle J, Lamminmäki T, Gane P (2010) A review of modified surfaces for high speed inkjet coating. Surf Coat Technol 204(12–13):2103–2109
Kim OV, Dunn PF (2010) Controlled production of droplets by in-flight electrospraying. Langmuir (26)20:15807–15813
Orme M, Courter J, Liu Q, Huang C, Smith R (2000) Electrostatic charging and deflection of nonconventional droplet streams formed from capillary stream breakup. Phys Fluids 12(9):2224
Pohl HA, Crane JS (1971) Dielectrophoresis of cells. Biophys J 11(9):711–727
Rayleigh L (1878) On the instability of jets. Proceedings of the London Mathematical Society s1–10(1):4–13
Sweet RG (1965) High frequency recording with electrostatically deflected ink jets. Rev Sci Instrum 36(2):131
Sweet RG (1971) Fluid droplet recorder, U.S. Patent 3596275
Vaeth KM (2007) Continuous inkjet drop generators fabricated from plastic substrates. J Microelectromech Syst 16(5):1080–1086
Vahey MD, Voldman J (2008) An equilibrium method for continuous-flow cell sorting using dielectrophoresis. Anal Chem 80(9):3135–3143
Weierstall U, Doak RB, Spence JCH, Starodub D, Shapiro D, Kennedy P, Warner J, Hembree GG, Fromme P, Chapman HN (2007) Droplet streams for serial crystallography of proteins. Exp Fluids 44(5):675–689
Yeo L, Lastochkin D, Wang S-C, Chang H-C (2004) A new ac electrospray mechanism by Maxwell-Wagner polarization and capillary resonance. Phys Rev Lett 92(13):133902
Zangl H, Bretterklieber T (2011) A drop generator for the evaluation of automotive rain sensors. IEEE Sens Proc 2011:1409–1412
Acknowledgments
Our thanks to Professor Thomas Jones of the University of Rochester for access to instrumentation used to build the CIJ system. WJD acknowledges the financial support of the Small Scale Systems Integration and Packaging Center (S3IP) at the State University of New York at Binghamton.
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Doak, W.J., Donovan, J.P. & Chiarot, P.R. Deflection of continuous droplet streams using high-voltage dielectrophoresis. Exp Fluids 54, 1577 (2013). https://doi.org/10.1007/s00348-013-1577-4
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DOI: https://doi.org/10.1007/s00348-013-1577-4