Recapillarity: Electrochemically Controlled Capillary Withdrawal of a Liquid Metal Alloy from Microchannels

This paper describes the mechanistic details of an electrochemical method to control the withdrawal of a liquid metal alloy, eutectic gallium indium (EGaIn), from microfluidic channels. EGaIn is one of several alloys of gallium that are liquid at room temperature and form a thin (nm scale) surface oxide that stabilizes the shape of the metal in microchannels. Applying a reductive potential to the metal removes the oxide in the presence of electrolyte and induces capillary behavior; we call this behavior “recapillarity” because of the importance of electrochemical reduction to the process. Recapillarity can repeatably toggle on and off capillary behavior by applying voltage, which is useful for controlling the withdrawal of metal from microchannels. This paper explores the mechanism of withdrawal and identifies the applied current as the key factor dictating the withdrawal velocity. Experimental observations suggest that this current may be necessary to reduce the oxide on the leading interface of the metal as well as the oxide sandwiched between the wall of the microchannel and the bulk liquid metal. The ability to control the shape and position of a metal using an applied voltage may prove useful for shape reconfigurable electronics, optics, transient circuits, and microfluidic components.

[1]  Shah,et al.  Electrochemical principles for active control of liquids on submillimeter scales , 1999, Science.

[2]  Steve Arscott,et al.  Electrowetting at a liquid metal-semiconductor junction , 2013 .

[3]  R. Wood,et al.  A non-differential elastomer curvature sensor for softer-than-skin electronics , 2011 .

[4]  R. Wood,et al.  Tunable elastic stiffness with microconfined magnetorheological domains at low magnetic field , 2010 .

[5]  John A. Rogers,et al.  Tunable organic transistors that use microfluidic source and drain electrodes , 2003 .

[6]  Howard A. Stone,et al.  ENGINEERING FLOWS IN SMALL DEVICES , 2004 .

[7]  M. Dickey,et al.  Ultrastretchable Fibers with Metallic Conductivity Using a Liquid Metal Alloy Core , 2013 .

[8]  George M Whitesides,et al.  Electrochemical sensing in paper-based microfluidic devices. , 2010, Lab on a chip.

[9]  Michael D. Dickey,et al.  Giant and switchable surface activity of liquid metal via surface oxidation , 2014, Proceedings of the National Academy of Sciences.

[10]  J. Koster,et al.  Directional Solidification and Melting of Eutectic GaIn , 1999 .

[11]  L. Jofre,et al.  Circular Beam-Steering Reconfigurable Antenna With Liquid Metal Parasitics , 2012, IEEE Transactions on Antennas and Propagation.

[12]  W. Choi,et al.  A Super-Lyophobic 3-D PDMS Channel as a Novel Microfluidic Platform to Manipulate Oxidized Galinstan , 2013, Journal of Microelectromechanical Systems.

[13]  R. Shabani,et al.  Active surface tension driven micropump using droplet/meniscus pressure gradient , 2011, 2011 16th International Solid-State Sensors, Actuators and Microsystems Conference.

[14]  D. Xing,et al.  Micropumps, microvalves, and micromixers within PCR microfluidic chips: Advances and trends. , 2007, Biotechnology advances.

[15]  J. Baret,et al.  Electrowetting: from basics to applications , 2005 .

[16]  Arnan Mitchell,et al.  Electrochemically induced actuation of liquid metal marbles. , 2013, Nanoscale.

[17]  Il-Joo Cho,et al.  A surface-tension driven micropump for low-voltage and low-power operations , 2002 .

[18]  W. Choi,et al.  Stretchable and bendable carbon nanotube on PDMS super-lyophobic sheet for liquid metal manipulation , 2014 .

[19]  Jason Heikenfeld,et al.  Reconfigurable liquid metal circuits by Laplace pressure shaping , 2012 .

[20]  Arnan Mitchell,et al.  Liquid Metal Marbles , 2013 .

[21]  V. Hessel,et al.  Micromixers—a review on passive and active mixing principles , 2005 .

[22]  A. Frumkin,et al.  Electrocapillary phenomena on gallium , 1965 .

[23]  Shanliangzi Liu,et al.  Different shades of oxide: from nanoscale wetting mechanisms to contact printing of gallium-based liquid metals. , 2014, Langmuir : the ACS journal of surfaces and colloids.

[24]  S. J. French,et al.  THE SYSTEM GALLIUM-INDIUM , 1937 .

[25]  H. Zeng,et al.  Area-tunable micromirror based on electrowetting actuation of liquid-metal droplets , 2006 .

[26]  Sivaraman Guruswamy,et al.  Reconfigurable liquid metal based terahertz metamaterials via selective erasure and refilling to the unit cell level , 2013 .

[27]  Rebecca K. Kramer,et al.  Direct Writing of Gallium‐Indium Alloy for Stretchable Electronics , 2014 .

[28]  M. J. Regan,et al.  X-ray study of the oxidation of liquid-gallium surfaces , 1997 .

[29]  Rebecca K. Kramer,et al.  Effect of microtextured surface topography on the wetting behavior of eutectic gallium-indium alloys. , 2014, Langmuir : the ACS journal of surfaces and colloids.

[30]  B. Ziaie,et al.  A multiaxial stretchable interconnect using liquid-alloy-filled elastomeric microchannels , 2008 .

[31]  G. Whitesides,et al.  Eutectic gallium-indium (EGaIn): a moldable liquid metal for electrical characterization of self-assembled monolayers. , 2008, Angewandte Chemie.

[32]  Fu-Cheng Wang,et al.  Ultrahigh contrast light valve driven by electrocapillarity of liquid gallium , 2009 .

[33]  D. LaMontagne,et al.  Polarography with a dropping gallium electrode. , 1954, Science.

[34]  J. Muth,et al.  3D Printing of Free Standing Liquid Metal Microstructures , 2013, Advanced materials.

[35]  K. Spells,et al.  The determination of the viscosity of liquid gallium over an extended nrange of temperature , 1936 .

[36]  D. Beebe,et al.  Surface-directed liquid flow inside microchannels. , 2001, Science.

[37]  P. Sen,et al.  A Fast Liquid-Metal Droplet Microswitch Using EWOD-Driven Contact-Line Sliding , 2009, Journal of microelectromechanical systems.

[38]  George M. Whitesides,et al.  Electrical Resistance of AgTS–S(CH2)n−1CH3//Ga2O3/EGaIn Tunneling Junctions , 2012 .

[39]  Mitesh Parmar,et al.  PDMS based coplanar microfluidic channels for the surface reduction of oxidized Galinstan. , 2014, Lab on a chip.

[40]  C. Kim,et al.  Electrostatically actuated metal-droplet microswitches integrated on CMOS chip , 2006, Journal of Microelectromechanical Systems.

[41]  Zhigang Wu,et al.  Microfluidic stretchable RF electronics. , 2010, Lab on a chip.

[42]  G. Lazzi,et al.  A Pressure Responsive Fluidic Microstrip Open Stub Resonator Using a Liquid Metal Alloy , 2012, IEEE Microwave and Wireless Components Letters.

[43]  S. Tang,et al.  Liquid metal enabled pump , 2014, Proceedings of the National Academy of Sciences.

[44]  G. Whitesides,et al.  Eutectic Gallium‐Indium (EGaIn): A Liquid Metal Alloy for the Formation of Stable Structures in Microchannels at Room Temperature , 2008 .

[45]  Ajay Nahata,et al.  Liquid metal-based plasmonics. , 2012, Optics express.

[46]  Chih-Ming Ho,et al.  MICRO-ELECTRO-MECHANICAL-SYSTEMS (MEMS) AND FLUID FLOWS , 1998 .

[47]  Jens Anders Branebjerg,et al.  Microfluidics-a review , 1993 .

[48]  Chang-Jin Kim,et al.  Microscale Liquid-Metal Switches—A Review , 2009, IEEE Transactions on Industrial Electronics.

[49]  M. Dickey,et al.  A frequency shifting liquid metal antenna with pressure responsiveness , 2011 .

[50]  D. Zrnić,et al.  On the resistivity and surface tension of the eutectic alloy of gallium and indium , 1969 .