Patent ID: 6702950
Filing Date: 2004-03-09
Classification: B05B,H01J,Y10S

Abstract:
A method for fabricating a liquid chromatography microelectromechanical device, comprising the steps of:a) providing a silicon substrate having an introduction surface on an introduction side of said substrate and an opposing separation surface on a separation side of said substrate; b) forming first and second silicon oxide layers on said introduction and separation surfaces of said substrate, respectively; c) doping a portion of said introduction surface through said first silicon oxide layer with a dopant of a same conductivity type as a conductivity type of said substrate; d) forming a silicon nitride film on said first silicon oxide layer; e) patterning and etching said silicon nitride film to form at least one silicon nitride contact area on said first silicon oxide layer; f) oxidizing said substrate, after step (e), to increase said first and second silicon oxide layers; g) coating a first photoresist layer on said introduction side; h) defining a first pattern on said first photoresist layer, said first pattern consisting of an introduction channel and an introduction-side exit channel; i) transferring said first pattern onto said first silicon oxide layer; j) etching said first pattern into said silicon substrate; k) removing said first photoresist layer; l) coating a second photoresist layer on said separation side; m) defining and transferring a second pattern onto said second silicon oxide layer, said second pattern including a separation channel, a separation channel terminus, and a plurality of separation posts; n) removing said second photoresist layer; o) coating a third photoresist layer on said separation side; p) defining and transferring a third pattern consisting of a fluid reservoir and a separation-side exit channel onto said second silicon oxide layer when said second pattern does not include said fluid reservoir, such that said reservoir is substantially aligned with said introduction channel and said separation-side exit channel is substantially aligned with said introduction-side exit channel; otherwise, defining said third pattern onto said separation surface when said fluid reservoir is also included in said second pattern, such that said reservoir is substantially aligned with said introduction channel and said separation-side exit channel is substantially aligned with said introduction-side exit channel; q) etching said third pattern into said silicon substrate so that said reservoir connects with said introduction channel and said separation-side exit channel connects with said introduction-side exit channel; r) removing said third photoresist layer; s) etching said second pattern into said silicon substrate; t) forming, after step (s), an isolation layer on all silicon surfaces of said silicon substrate; u) attaching, after step (t), a cover substrate to said separation surface of said silicon substrate; v) removing, after step (u), said silicon nitride from said at least one silicon nitride contact area and removing any of said first silicon oxide layer beneath said at least one silicon nitride contact area, thereby forming at least one contact area on said first surface; and w) depositing a metal on said at least one contact area.