Positioning of organic and inorganic objects by electrophoretic forces, including for microlens alignment

Assignee

• The Regents of the University of California · US

Inventors

• Aaron L. Birkbeck · San Diego, US
• Sadik C. Esener · Solana Beach, US
• Mihrimah Ozkan · San Diego, US
• Erhan Ata · Village of La Jolla, US

Key dates

Classification

• Technology area (CPC G)Physics
• CPC primaryG02B7/027
• WIPO fieldChemical engineering
• WIPO sectorChemistry

Abstract

An adaptive alignment technique provides precise control and active positioning in, preferably, two-dimensions of sub-millimeter-sized objects such as, in one application, spherical mircolenses through the application of electrophoretic forces in a microfluidic wells. A lithographically patterned microfluidic well and electrodes can be addressed to position or align a spherical microlens to a corresponding laser light beam. The motion of the microlens is preferably controlled using CMOS compatible voltages (3V–1 μA) that are preferably applied to opposite electrodes in the microfluidic well, creating an electrical field in a well solution. By applying voltages to opposed electrode pairs, movement of spherical microlenses with sizes ranging from, most typically, 0.87 μm to 40 μm in directions parallel to the electrode surface is realized. Under a bias of 3 volts, the microspheres have electrophoretic velocities ranging from 13 to 16 μm/s. Optical alignment of the spherical microlens, as is preferably accomplished by use of feedback from a photo detector, serves to position the microlens for maximum efficiency. Microlenses or other optical elements may thus be aligned to optical fibe…