Patent ID: 8446237
Filing Date: 2013-05-21
Classification: H01H,H01L,Y10T

Abstract:
1. A method of forming a MEMS relay comprising: providing a semiconductor structure having a top surface; forming a metal interconnect structure touching the semiconductor structure top surface; depositing a top passivation layer, having top and bottom surfaces, performing a mask and etch process to form openings in the top passivation layer to expose a plurality of conductive pads, wherein the plurality of conductive pads provide points for external electrical connections, and points for electrical connections to overlying devices, wherein a first pad of the plurality of conductive pads is coupled to a first switch contact and a magnetic cantilever, a second pad of the plurality of conductive pads is coupled to a second switch contact, a third pad of the plurality of conductive pads is coupled lower magnetic core section and a first pair of pads are coupled to a magnetic coil; depositing a photoimageable epoxy or polymer forming a first non-conductive layer, having top and bottom surfaces, that touches the top surface of the passivation layer having a second set of openings for switch metal plugs, magnetic coil metal plugs and a lower magnetic core section, formed by a mask and develop process; forming the lower magnetic core section, having top and bottom surfaces, that extends through the first non-conductive layer, touching the top surface of the top passivation layer and communicating with the third pad of the plurality of conductive pads, by depositing a seed layer and then plating the seed layer with a soft magnetic material, wherein the top surface of the lower magnetic core section and the top surface of the first non-conductive layer lie substantially in the same plane; forming a first plurality of metal plugs, having top and bottom surfaces, formed in the second set of openings of the first non-conductive layer for coupling with a switch and a magnetic coil, wherein the top surfaces of the first plurality of metal plugs and the top surface of the first non-conductive layer lie substantially in the same plane; depositing a second non-conductive layer, having top and bottom surfaces, that touches the top surface of the first non-conductive layer and the top surface of the lower magnetic core section with a third set of openings for switch metal plugs and magnetic coil metal plugs and via openings that expose regions on the top surface of the lower magnetic core section formed by a mask and etch process; forming a coil of a continuous series of loops, having top and bottom surfaces, touching the top surface of the second non-conductive layer and the top surfaces of the magnetic switch metal plugs of the first plurality of metal plugs; forming a second plurality of metal plugs, having top and bottom surfaces, formed on and in contact within the second set of openings of the second non-conductive layer for coupling with the switch contact; depositing a photoimageable epoxy or polymer forming a third non-conductive layer, having top and bottom surfaces, that touches the top surface of the second non-conductive layer, the top surface of the lower magnetic core section and covering the coil having a fourth set of openings to expose the tops of the set of switch metal plugs of the second plurality of metal plugs and a pair of core openings to expose regions on the top surface of the lower magnetic core section formed by a mask and develop process; forming first and second magnetic core vias, having top and bottom surfaces, formed in the pair of core openings, by depositing a seed layer and then plating the seed layer with the soft magnetic material, the bottom surfaces of the first and second magnetic core vias touching the top surface of the lower magnetic core section, wherein the tops surfaces of the first and second of magnetic core vias and the top surface of the third non-conductive layer lie substantially in the same plane; depositing a fourth non-conductive member, having a top and bottom surfaces, touches the top surface of the first magnetic core via; forming a first metal trace, having a top and bottom surfaces, touching the top surface of third non-conductive layer the top of the first metal switch plug of the second plurality of metal plugs by a mask and etch process; forming a second metal trace, having a top and bottom surfaces, touching the top surface of third non-conductive layer and the top of the second metal switch plug of the second plurality of metal plugs by a mask and etch process; forming a third metal trace, having a top and bottom surfaces, touching the top surface of the fourth non-conductive member and the first metal trace; wherein the second and third metal traces have first and second metal contact regions respectively, disposed at the ends and top surface of the second metal trace the bottom surface of the third metal trace, forming the switch contacts; forming a magnetic cantilever core section that touches the top surface of the third metal trace; wherein the second contact region is spaced apart from the first contact region when the second contact region is in the first position, the second contact region touching the first contact region when the second contact region is in the second position; and wherein the lower magnetic core section and the third conductive trace are electrically coupled to a holding voltage source to electrostaticaly maintain a closed position after the coil is deenergized.