Generation and Control of Electrohydrodynamic Flows in Aqueous Electrolyte Solutions
Summary
The rectification of ion transport pathways is an effective method to generate one-directional ion-dragged electrohydrodynamic flows. By setting an ion-exchange membrane in a flow channel, an electrically polarized condition is generated and causes a liquid flow to be driven when an electric field is externally applied.
Abstract
To drive electrohydrodynamic (EHD) flows in aqueous solutions, the separation of cation and anion transport pathways is essential because a directed electric body force has to be induced by ionic motions in liquid. On the other hand, positive and negative charges attract each other, and electroneutrality is maintained everywhere in equilibrium conditions. Furthermore, an increase in an applied voltage has to be suppressed to avoid water electrolysis, which causes the solutions to become unstable. Usually, EHD flows can be induced in non-aqueous solutions by applying extremely high voltages, such as tens of kV, to inject electrical charges. In this study, two methods are introduced to generate EHD flows induced by electrical charge separations in aqueous solutions, where two liquid phases are separated by an ion-exchange membrane. Due to a difference in the ionic mobility in the membrane, ion concentration polarization is induced between both sides of the membrane. In this study, we demonstrate two methods. (i) The relaxation of ion concentration gradients occurs via a flow channel that penetrates an ion-exchange membrane, where the transport of the slower species in the membrane selectively becomes dominant in the flow channel. This is a driving force to generate an EHD flow in the liquid. (ii) A long waiting time for the diffusion of ions passing through the ion-exchange membrane enables the generation of an ion-dragged flow by externally applying an electric field. Ions concentrated in a flow channel of a 1 x 1 mm2 cross-section determine the direction of the liquid flow, corresponding to the electrophoretic transport pathways. In both methods, the electric voltage difference required for an EHD flow generation is drastically reduced to near 2 V by rectifying the ion transport pathways.
Introduction
Recently, liquid flow control techniques have attracted much attention because of interest in the applications of micro- and nanofluidic devices1,2,3,4,5,6,7,8,9,10,11,12,13,14,15. In polar solutions, such as aqueous solutions and ionic liquids, ions and electrically charged particles usually bring about electrical charges in liquid flows. The transport of such polarized particles provides an expansion of various applications, such as single-molecule manipulation6,10,11,13,14,15,16,17, ion diode devices12,18, and liquid flow control19,20,21,22. EHD flow has been an applicable phenomenon for liquid flow control systems since Stuetzer1,2 invented the ion drag pump. Melcher and Taylor3 published an important article in which the theoretical framework of EHD flow was well reviewed and some outstanding experiments were also demonstrated. Saville4 and his coworkers23,24 contributed to the following expansion of EHD technologies in liquids. However, there were some limitations to inducing liquid flows driven by electric forces, because tens of kV have to be applied in liquids to inject electrical charges in non-polar solutions, such as oils, to polarize them1,2,3. This is a disadvantage for aqueous solutions because the water electrolysis that is induced by an electric potential higher than 1.23 V changes the characteristics of solutions and makes the solutions unstable.
In micro- and nanofluidic channels, surface charges of channel walls cause the concentration of counterions that effectively induce electroosmotic flows (EOFs) under externally applied electric fields25,26,27,28,29. Using EOFs, some liquid pumping techniques have been applied in aqueous solutions, reducing the electric voltages30,31,32. On the other hand, EOFs are limited to being generated in micro- and nanospaces in which surface areas become more dominant than liquid volumes. Furthermore, depending on the transport of highly concentrated ions very near the wall surfaces, such as in electric double layers, the slip boundary only causes the liquid flow, which may not be sufficient to make pressure gradients7,8,22,26,27. Fine tuning, such as to channel dimensions and salt concentrations, is required for the applications of EOF. In contrast, EHD flows driven by body forces seem to be available to transport masses and energies if the application voltages can be reduced to avoid degrading solvents. Recently, some researchers have suggested applications of EHD flows with low voltages33,34,35,36. Although these technologies have not yet been implemented, the frontiers are expected to expand.
In previous studies, we also conducted experimental and theoretical work on EHD flows in aqueous solutions37,38,39,40. It was supposed that the rectification of ion transport pathways was effective to generate electrically charged solutions that cause electric body forces under electric fields. By using an ion-exchange membrane and a flow channel crossing the membrane, we were able to rectify ionic currents. When applying an anion-exchange membrane, cations concentrated in the flow channel dragged the solvents and developed an EHD flow37,38,39. A difference in the mobility of ion species was an important factor when separating the cationic and anionic currents. Ion-exchange membranes effectively worked to modulate the mobility due to the ion selectivity. Ion transport phenomena were also investigated from the viewpoint of ionic current density influenced by applied electric fields41. These studies have been fruitful for developing manipulation techniques for single molecules, namely, micro- and nanoparticles, whose motions are strongly affected by thermal fluctuations11,16,17. EOFs and EHD flows are expected to expand the variety of precise flow control methods as well as pressure gradients.
In this study, we demonstrate two methods to drive EHD flows in aqueous solutions. First, an NaOH solution is used for a working fluid to drive an EHD flow37,38,39. An anion-exchange membrane separates the liquid into two parts. A polydimethylsiloxane (PDMS) flow channel with a cross-section of 1 x 1 mm and a length of 3 mm penetrates the membrane. By applying an electric potential of 2.2 V, the electrophoretic transport of Na+, H+, and OH− ions is induced along the electric fields. An anion-exchange membrane and a flow channel effectively work to separate the ion transport pathways, where anions dominantly pass through the membrane and cations concentrate in the flow channel, although both species usually move in opposite directions, maintaining the electroneutrality. Thus, such a condition does not cause a driving force for liquid flows. This structure is crucial to generating an EHD flow whose flow speed reaches on the order of 1 mm/s in the channel because highly concentrated cations accelerated by external electric fields drag solvent molecules. EHD flows are observed and recorded by using a microscope and a high-speed camera as shown in Figure 1. Second, a concentration difference between two liquid phases separated by an ion-exchange membrane causes an electrically polarized condition to be generated crossing an ion-exchange membrane40. In this study, we find the importance of a considerable waiting time to equilibrate ion distributions and a corresponding electric potential, which cause preferable conditions to apply to a body force in a liquid. Crossing the ion-exchange membrane, a weakly polarized condition is achieved. In such a condition, an externally applied electric field induces directional ion transport that generates a body force in a liquid, and as a result, the momentum transfer from the ions to the solvent develops an EHD flow.
As mentioned above, the present devices succeed in drastically decreasing the applied voltage difference to a few volts, and thus this method is can be used for aqueous solutions, although the conventional electrical charge injection methods required tens of kV and are limited to an application to non-aqueous solutions.
Protocol
Representative Results
Discussion
The purpose of this study was to separate cations and anions in aqueous solutions in terms of spatial distributions and transport numbers. Using an anion-exchange membrane, the transport of anions and cations could be rectified in the membrane and in a flow channel that penetrates the membrane, respectively. Alternatively, a cation-exchange membrane that separated high and low concentration solutions worked to generate electrically polarized solutions after a considerable waiting time. As a result, rectified ionic curren…
Declarações
The authors have nothing to disclose.
Acknowledgements
The authors have no acknowledgments.
Materials
| Sylgard 184 | Dow Corning Corp. | 3097366-0516, 3097358-1004 | PDMS |
| Acetone | Wako Pure Chemical Industries, Ltd. | 012-00343 | |
| Ethanol | Wako Pure Chemical Industries, Ltd. | 054-00461 | |
| 0.1 mol/L Sodium Hydroxide Solution | Wako Pure Chemical Industries, Ltd. | 196-02195 | |
| Pottasium Chloride | Wako Pure Chemical Industries, Ltd. | 163-03545 | |
| Tris-EDTA buffer 100x concentrate | Sigma-Aldrich Co. LLC. | T9285-10014L | |
| 2.93 μm polystyrene particle | Merck KGaA | L300 Rouge | Tracer particle |
| 1.01 μm polystyrene particle | Merck KGaA | K100(23716) | Tracer particle |
| Anion exchange membrane | ASTOM Corp. | Neosepta AHA | |
| Gold (Au) | Furuuchi Chemical Corp. | AUT-13301X | Sputtering target metal |
| Titanium | Furuuchi Chemical Corp. | TIT-72301X | Sputtering target metal |
| Chromium | Furuuchi Chemical Corp. | CRT-24301X | Sputtering target metal |
| Hight-speed CMOS camera | Keyence Corp. | VW-600M | |
| Microscope | Keyence Corp. | VW-9000 | |
| Data logger | Keyence Corp. | NR-500, NR-HA08 | |
| Laser displacement meter | Keyence Corp. | LK-G5000, LK-H008W | |
| PIV and PTV software | DITECT Co. Ltd. | Flownizer 2D | |
| Potentiostat | AMTEK Inc. | VersaSTAT4 | |
| Inverted microscope | Olympus Corp. | IX73 | |
| High-speed CMOS camera | Andor Technology Ltd. | Zyla 5.5 sCMOS | |
| Function generator | NF Corp. | WF1945B | |
| Function generator | NF Corp. | WF1973 | |
| Ultrasonic cleaner | AS ONE Corp. | AS22GTU | |
| Rotary pump | ULVAC, Inc. | G-100S | Degas liquid PDMS |
| Rotary pump | ULVAC, Inc. | GLD-201A | Sputtering |
| Molecular diffusion pump | ULVAC, Inc. | VPC-400 | Sputtering |
Referências
- Stuetzer, O. M. Ion drag pressure generation. Journal of Applied Physics. 30, 984-994 (1959).
- Stuetzer, O. M. Ion drag pumps. Journal of Applied Physics. 31, 136-146 (1960).
- Melcher, J. R., Taylor, G. I. Electrohydrodynamics: A review of the role of interfacial shear stresses. Annual Review of Fluid Mechanics. 1, 111-146 (1969).
- Saville, D. A. Electrohydrodynamics: The Taylor-Melcher leaky dielectric model. Annual Review of Fluid Mechanics. 29, 27-64 (1997).
- Stein, D., Kruithof, M., Dekker, C. Surface-charge-governed ion transport in nanofluidic channels. Physical Review Letters. 93, 035901 (2004).
- Dekker, C. Solid-state nanopores. Nature Nanotechnology. 2, 209-215 (2007).
- Schoch, R. B., Han, J., Renaud, P. Transport phenomena in nanofluidics. Reviews of Modern Physics. 80, 839-883 (2008).
- Iverson, B. D., Garimella, S. V. Recent advances in microscale pumping technologies: A review and evaluation. Microfluidics and Nanofluidics. 5, 145-174 (2008).
- Sparreboom, W., van den Berg, A., Eijkel, J. C. T. Principles and applications of nanofluidic transport. Nature Nanotechnology. 4, 713-720 (2009).
- Venkatesan, B. M., Bashir, R. Nanopore sensors for nucleic acid analysis. Nature Nanotechnology. 6, 615-624 (2011).
- Uehara, S., Shintaku, H., Kawano, S. Electrokinetic flow dynamics of weakly aggregated λDNA confined in nanochannels. Journal of Fluids Engineering. 133, 121203 (2011).
- Guan, W., Reed, M. A. Electric field modulation of the membrane potential in solid-state ion channels. Nano Letters. 12, 6441-6447 (2012).
- Yasui, T., et al. DNA manipulation and separation in sublithographic-scale nanowire array. ACS Nano. 7, 3029-3035 (2013).
- Ren, Y., et al. Particle rotational trapping on a floating electrode by rotating induced-charge electroosmosis. Biomicrofluidics. 10, 054103 (2016).
- Ren, Y., et al. Flexible particle flow-focusing in microchannel driven by droplet-directed induced-charge electroosmosis. ELECTROPHORESIS. 39, 597-607 (2018).
- Qian, W., Doi, K., Uehara, S., Morita, K., Kawano, S. Theoretical study of the transpore velocity control of single-stranded DNA. International Journal of Molecular Sciences. 15, 13817-13832 (2014).
- Qian, W., Doi, K., Kawano, S. Effect of polymer length and salt concentration on the transport of ssDNA in nanofluidic channels. Biophysical Journal. 112, 838-849 (2017).
- Liu, W., et al. A universal design of field-effect-tunable microfluidic ion diode based on a gating cation-exchange nanoporous membrane. Physics of Fluids. 29, 112001 (2017).
- Liu, W., et al. Control of two-phase flow in microfluidics using out-of-phase electroconvective streaming. Physics of Fluids. 29, 112002 (2017).
- Osman, O. O., Shintaku, H., Kawano, S. Development of micro-vibrating flow pumps using MEMS technologies. Microfluidics and Nanofluidics. 13, 703-713 (2012).
- Osman, O. O., Shirai, A., Kawano, S. A numerical study on the performance of micro-vibrating flow pumps using the immersed boundary method. Microfluidics and Nanofluidics. 19, 595-608 (2015).
- Daiguji, H. Ion transport in nanofluidic channels. Chemical Society Reviews Home. 39, 901-911 (2010).
- Ristenpart, W. D., Aksay, I. A., Saville, D. A. Assembly of colloidal aggregates by electrohydrodynamic flow: Kinetic experiments and scaling analysis. Physical Review E. 69, 021405 (2004).
- Ristenpart, W. D., Aksay, I. A., Saville, D. A. Electrohydrodynamic flow around a colloidal particle near an electrode with an oscillating potential. Journal of Fluid Mechanics. 575, 83-109 (2007).
- Schoch, R. B., Hann, J., Renaud, P. Effect of the surface charge on ion transport through nanoslits. Physics of Fluids. 17, 100604 (2005).
- Ross, D., Johnson, T. J., Locascio, L. E. Imaging of electroosmotic flow in plastic microchannels. Analytical Chemistry. 73, 2509-2515 (2001).
- Hsieh, S. -. S., Lin, H. -. C., Lin, C. -. Y. Electroosmotic flow velocity measurements in a square microchannel. Colloid and Polymer Science. 284, 1275-1286 (2006).
- Rubinstein, I., Zaltzman, B. Electro-osmotically induced convection at a permselective membrane. Physical Review E. 62, 2238-2251 (2000).
- Bard, A. J., Faulkner, L. R. . Electrochemical methods, 2nd ed. , 362-363 (2001).
- Brask, A., Goranović, G., Jensen, M. J., Bruus, H. A novel electro-osmotic pump design for nonconducting liquids: theoretical analysis of flow rate-pressure characteristics and stability. Journal of Micromechanics and Microengineering. 15, 883-891 (2005).
- Takamura, Y., et al. Low-voltage electroosmosis pump for stand-alone microfluidics devices. Electrophoresis. 24, 185-192 (2003).
- Zeng, S., Chen, C. -. H., Mikkelsen, J. C., Santiago, J. G. Fabrication and characterization of electroosmotic micropumps. Sensors and Actuators B: Chemical. 79, 107-114 (2001).
- Bhaumik, S. K., Roy, R., Chakraborty, S., DasGupta, S. Low-voltage electrohydrodynamic micropumping of emulsions. Sensors and Actuators B: Chemical. 193, 288-293 (2014).
- El Moctar, A. O., Aubry, N., Batton, J. Electro-hydrodynamic micro-fluidic mixer. Lab on a Chip. 3, 273-280 (2003).
- Bart, S. F., Tavrow, L. S., Mehregany, M., Lang, J. H. Microfabricated electrohydrodynamic pumps. Sensors and Actuators A: Physical. 21, 193-197 (1990).
- Ashikhmin, I. A., Stishkov, Y. K. Effect of insulating walls on the structure of electrodynamic flows in a channel. Technical Physics. 57, 1181-1187 (2012).
- Yano, A., Doi, K., Kawano, S. Observation of electrohydrodynamic flow through a pore in ion-exchange membrane. International Journal of Chemical Engineering and Applications. 6, 254-257 (2015).
- Doi, K., Yano, A., Kawano, S. Electrohydrodynamic flow through a 1 mm2 cross-section pore placed in an ion-exchange membrane. The Journal of Physical Chemistry B. 119, 228-237 (2015).
- Yano, A., Shirai, H., Imoto, M., Doi, K., Kawano, S. Concentration dependence of cation-induced electrohydrodynamic flow passing through an anion exchange membrane. Japanese Journal of Applied Physics. 56, 097201 (2017).
- Nagura, R., Doi, K., Kawano, S. Characterisation of microparticle transport driven by ionic current conditions in electrically polarized aqueous solutions. Micro & Nano Letters. 12, 526-531 (2017).
- Doi, K., et al. Nonequilibrium ionic response of biased mechanically controllable break junction (MCBJ) electrodes. The Journal of Physical Chemistry C. 118, 3758-3765 (2014).
