A chuck for testing an integrated circuit includes an upper conductive layer having a lower surface and an upper surface suitable to support a device under test. An upper insulating layer has an upper surface at least in partial face-to-face contact with the lower surface of the upper conductive lay
A chuck for testing an integrated circuit includes an upper conductive layer having a lower surface and an upper surface suitable to support a device under test. An upper insulating layer has an upper surface at least in partial face-to-face contact with the lower surface of the upper conductive layer, and a lower surface. A middle conductive layer has an upper surface at least in partial face-to-face contact with the lower surface of the upper insulating layer, and a lower surface.
대표청구항▼
1. A chuck comprising: (a) an upper conductive layer having a lower surface and an upper surface suitable to contact and support a device under test, wherein said upper surface of said upper conductive layer includes thereon a vacuum distribution for holding said device under test, wherein the vacuu
1. A chuck comprising: (a) an upper conductive layer having a lower surface and an upper surface suitable to contact and support a device under test, wherein said upper surface of said upper conductive layer includes thereon a vacuum distribution for holding said device under test, wherein the vacuum distribution is configured to selectively and independently apply a vacuum to multiple distinct zones of the upper surface of the upper conductive layer;(b) an upper insulating layer having an upper surface at least in partial face-to-face contact with said lower surface of said upper conductive layer, and a lower surface, wherein the upper insulating layer is horizontally distinct from the upper conductive layer; and(c) a middle conductive layer having an upper surface at least in partial face-to-face contact with said lower surface of said upper insulating layer, and a lower surface, wherein the middle conductive layer is horizontally distinct from the upper insulating layer. 2. The chuck of claim 1, wherein said vacuum distribution comprises a plurality of vacuum holes positioned across said upper surface of said upper conductive layer and close enough to one another to have overlapping areas of full vacuum effect so as to provide uninterrupted vacuum across zones of said upper surface of said upper conductive layer. 3. The chuck of claim 2, wherein said plurality of vacuum holes is uniformly spaced on said upper surface of said upper conductive layer. 4. The chuck of claim 2, wherein each of said plurality of vacuum holes is less than 0.38 inches away from a closest other vacuum hole of the plurality of vacuum holes. 5. The chuck of claim 2, wherein the plurality of vacuum holes is positioned to provide uninterrupted vacuum across said upper surface of said upper conductive layer. 6. The chuck of claim 2, wherein the chuck further includes a plurality of cross-drilled inner channels, wherein each of the plurality of cross-drilled inner channels is configured to conduct a respective vacuum to a respective subset of the plurality of vacuum holes. 7. The chuck of claim 2, wherein said lower surface of said upper conductive layer includes a plurality of channels and a plurality of machined holes, wherein each of the plurality of machined holes interconnects a selected one of the plurality of vacuum holes with a corresponding one of the plurality of channels. 8. The chuck of claim 2, wherein the plurality of vacuum holes includes a plurality of machined vacuum holes. 9. The chuck of claim 1, wherein the vacuum distribution includes a plurality of vacuum lines defined by the upper conductive layer, wherein the vacuum distribution further includes a plurality of vacuum holes positioned across said upper surface of said upper conductive layer, and further wherein each of the plurality of vacuum lines is configured to apply a corresponding vacuum to a corresponding subset of the plurality of vacuum holes. 10. The chuck of claim 9, wherein each corresponding subset of the plurality of vacuum holes is distinct from each other corresponding subset of the plurality of vacuum holes. 11. The chuck of claim 9, wherein the multiple zones are arranged in concentric circles on the upper surface of the upper conductive layer. 12. The chuck of claim 9, wherein the plurality of vacuum holes includes a plurality of machined vacuum holes. 13. The chuck of claim 1, wherein said vacuum distribution comprises a porous sintered metal layer having at least as small as one micron sized pores through which a vacuum is drawn. 14. The chuck of claim 1, wherein said vacuum distribution comprises micro-grooves at least as small as 50 microns wide and 15 microns deep, said micro-grooves formed upon said upper surface of said upper conductive layer with close enough spacing so as to provide a substantially continuous vacuum field across zones of said upper surface of said upper conductive layer. 15. The chuck of claim 1, wherein no vacuum path is provided that extends from said upper surface of said upper insulating layer to said lower surface of said upper insulating layer. 16. The chuck of claim 1, wherein said upper insulating layer includes a recess defined therein, wherein said recess is proximate an exterior peripheral surface of at least one of said upper conductive layer and said middle conductive layer and extends around a majority of a circumference of said upper insulating layer. 17. The chuck of claim 1, further comprising an insulated lift pin slidably extendable from a retracted position within a lift pin hole formed within said upper surface of said upper conductive layer, and an insulated lift pin sleeve further interposed between said insulated lift pin and said upper conductive layer, wherein said insulated lift pin sleeve includes a flange projecting radially outward from an axis of said insulated lift pin, said flange adapted in size and shape to increase at least one of an arc distance and a creepage distance characteristic of said chuck. 18. The chuck of claim 1, wherein said middle conductive layer comprises a guard potential held to a predetermined value, wherein said predetermined value is between a signal potential and a shield potential. 19. The chuck of claim 1, wherein said upper insulating layer extends beyond the exterior peripheral surface of said upper conductive layer and the exterior peripheral surface of said middle conductive layer. 20. The chuck of claim 1, wherein said upper insulating layer extends beyond the exterior peripheral surface of said upper conductive layer and the exterior peripheral surface of said middle conductive layer, and wherein said upper conductive layer has a smaller diameter than said middle conductive layer. 21. The chuck of claim 1, wherein the chuck is an assembly of separate parts, wherein the separate parts include the upper conductive layer and the upper insulating layer. 22. A chuck comprising: (a) an upper conductive layer having a lower surface and an upper surface suitable to contact and support a device under test, wherein said upper surface of said upper conductive layer includes thereon a vacuum distribution for holding said device under test, wherein said vacuum distribution comprises a plurality of vacuum holes positioned across said upper surface of said upper conductive layer and close enough to one another to have overlapping areas of full vacuum effect so as to provide uninterrupted vacuum across zones of said upper surface of said upper conductive layer, and further wherein said plurality of vacuum holes is uniformly spaced on said upper surface of said upper conductive layer;(b) an upper insulating layer having an upper surface at least in partial face-to-face contact with said lower surface of said upper conductive layer, and a lower surface, wherein the upper insulating layer is horizontally distinct from the upper conductive layer; and(c) a middle conductive layer having an upper surface at least in partial face-to-face contact with said lower surface of said upper insulating layer, and a lower surface, wherein the middle conductive layer is horizontally distinct from the upper insulating layer. 23. The chuck of claim 22, wherein each of said plurality of vacuum holes is less than 0.38 inches away from a closest other vacuum hole of the plurality of vacuum holes. 24. The chuck of claim 22, wherein the plurality of vacuum holes is positioned to provide uninterrupted vacuum across said upper surface of said upper conductive layer. 25. The chuck of claim 22, wherein the chuck further includes a plurality of cross-drilled inner channels, wherein each of the plurality of cross-drilled inner channels is configured to conduct a respective vacuum to a respective subset of the plurality of vacuum holes. 26. The chuck of claim 22, wherein said lower surface of said upper conductive layer includes a plurality of channels and a plurality of machined holes, wherein each of the plurality of machined holes interconnects a selected one of the plurality of vacuum holes with a corresponding one of the plurality of channels. 27. The chuck of claim 22, wherein the plurality of vacuum holes includes a plurality of machined vacuum holes. 28. The chuck of claim 22, wherein said upper insulating layer includes a recess defined therein, wherein said recess is proximate an exterior peripheral surface of at least one of said upper conductive layer and said middle conductive layer and extends around a majority of a circumference of said upper insulating layer. 29. A chuck comprising: (a) an upper conductive layer having a lower surface and an upper surface suitable to contact and support a device under test, wherein said upper surface of said upper conductive layer includes thereon a vacuum distribution for holding said device under test;(b) an upper insulating layer having an upper surface at least in partial face-to-face contact with said lower surface of said upper conductive layer, and a lower surface, wherein the upper insulating layer is horizontally distinct from the upper conductive layer; and(c) a middle conductive layer having an upper surface at least in partial face-to-face contact with said lower surface of said upper insulating layer, and a lower surface, wherein the middle conductive layer is horizontally distinct from the upper insulating layer;wherein said upper insulating layer includes a recess defined therein, wherein said recess is proximate an exterior peripheral surface of at least one of said upper conductive layer and said middle conductive layer and extends around a majority of a circumference of said upper insulating layer.
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이 특허에 인용된 특허 (28)
Doyle, Paul; Zhao, Guoheng; Belyaev, Alexander; Runyon, J. Rex; Wolters, Christian H.; Dando, Howard W.; Vaez-Iravani, Mehdi, Air bearing for substrate inspection device.
Miller Donald C. (1139 Blair Ave. Sunnyvale CA 94087) Isaac George L. (980 Kiely Blvd. #326 Santa Clara CA 95051), Kelvin chuck apparatus and method of manufacture.
Shibazaki, Yuichi, Substrate holder, stage apparatus, and exposure apparatus with first support part provided in a suction space and second support part.
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