Simulations of near-field excitation and trapping for integrated near-field optical microfluidic devices

Author

Carlo, Dino Di ; Chang, Wesley ; Lee, Luke P.

Author_Institution

Sensors & Actuators Center, California Univ., Berkeley, CA, USA

fYear

2000

fDate

2000

Firstpage

411

Lastpage

414

Abstract

Simulations of near-field excitation and trapping at 100 nm apertures were conducted to aid design of an integrated near-field optical device for detection and manipulation of molecules in fluidic microchannels. The simulations indicate that optical trapping will occur at near-field aperture edges, and if plane-polarized light is used the trapping edge can be selective. By changing the plane of polarization the position of the trap can be rotated. The near-field apertures have been fabricated inside microchannels using a novel batch micromachining process. The process consists of patterning micron size holes in a silicon nitride membrane, which are then reduced in size through the redeposition of silicon nitride thin films. Nanoholes down to 100 nm in diameter have been fabricated

Keywords

integrated optics; light polarisation; membranes; microfluidics; micromachining; radiation pressure; 100 nm; SiN; batch micromachining process; fluidic microchannels; integrated near-field optical microfluidic devices; nanoholes; near-field excitation; plane-polarized light; silicon nitride membrane; silicon nitride thin films redeposition; trapping; Apertures; Charge carrier processes; Fluidic microsystems; Microchannel; Microfluidics; Optical design; Optical detectors; Optical devices; Optical films; Silicon;

fLanguage

English

Publisher

ieee

Conference_Titel

Microtechnologies in Medicine and Biology, 1st Annual International, Conference On. 2000

Conference_Location

Lyon

Print_ISBN

0-7803-6603-4

Type

conf

DOI

10.1109/MMB.2000.893817

Filename

893817