Abstract: The present invention comprises a brim surrounding a wafer or wafer-like object during plasma etching in a non-contact wafer holder, such brim facilitating uniform flow of the plasma discharge around the edge of the wafer during plasma etching. The brim of the present invention avoids plasma instability and non-uniform flow typical of conventional plasma etching near the edges of the wafer being etched. The brim of the present invention, by facilitating uniform and stable plasma flows, decreases non-uniform etching. One embodiment of the present invention permits the brim to move in the axial direction from a position substantially. This permits the etching process to be controlled for more uniform and precise wafer etching as lowering the brim tends to shadow the edge region of the wafer from the plasma, reducing etching in the edge region while not significantly affecting etching in the central regions of the wafer.

Abstract: To fabricate contacts on a wafer backside, openings (124) are formed in the face side of the wafer (104). A dielectric layer (140) and some contact material (150), e.g. metal, are deposited into the openings. Then the backside is etched until the contacts (150C) are exposed and protrude out. The protruding portion of each contact has an outer sidewall (150V). At least a portion of the sidewall is vertical or sloped outwards with respect to the opening when the contact is traced down. The contact is soldered to an another structure (410), e.g. a die or a PCB. The solder (420) reaches and at least partially covers the sidewall portion which is vertical or sloped outwards. The strength of the solder bond is improved as a result. The dielectric layer protrudes around each contact. The protruding portion (140P) of the dielectric becomes gradually thinner around each contact in the downward direction.

Abstract: To fabricate back side contact pads that are suitable for use in a vertical integrated circuit, vias are made in the face side of a wafer, and dielectric and contact pad metal are deposited into the vias. Then the wafer back side is etched until the metal is exposed. When the etch exposes the insulator at the via bottoms, the insulator is etched slower than the wafer material (e.g. silicon). Therefore, when the dielectric is etched off and the metal is exposed, the dielectric protrudes down from the wafer back side around the exposed metal contact pads, by about 8 &mgr;m in some embodiments. The protruding dielectric portions improve insulation between the wafer and the contact pads when the contact pads are soldered to an underlying circuit. In some embodiments, before the contact pads are soldered, additional dielectric is grown on the wafer back side without covering the contact pads.

Abstract: A clock distribution network (110) is formed on a semiconductor interposer (320) which is a semiconductor integrated circuit. An input terminal (120) of the clock distribution network is formed on one side of the interposer, and output terminals (130) of the clock distribution network are formed on the opposite side of the interposer. The interposer has a through hole (360), and the clock distribution network includes a conductive feature going through the through hole. The side of the interposer which has the output terminals (130) is bonded to a second integrated circuit (310) containing circuitry clocked by the clock distribution network. The other side of the interposer is bonded to a third integrated circuit or a wiring substrate (330). The interposer contains a ground structure, or ground structures (390, 510), that shield circuitry from the clock distribution network. Conductive lines (150) in an integrated circuit are formed in trenches (610) in a semiconductor substrate.

Abstract: A clock distribution network (110) is formed on a semiconductor interposer (320) which is a semiconductor integrated circuit. An input terminal (120) of the clock distribution network is formed on one side of the interposer, and output terminals (130) of the clock distribution network are formed on the opposite side of the interposer. The interposer has a through hole (360), and the clock distribution network includes a conductive feature going through the through hole. The side of the interposer which has the output terminals (130) is bonded to a second integrated circuit (310) containing circuitry clocked by the clock distribution network. The other side of the interposer is bonded to a third integrated circuit or a wiring substrate (330). The interposer contains a ground structure, or ground structures (390, 510), that shield circuitry from the clock distribution network. Conductive lines (150) in an integrated circuit are formed in trenches (610) in a semiconductor substrate.

Abstract: To move an article in and out of plasma during plasma processing, the article is rotated by a first drive around a first axis, and the first drive is itself rotated by a second drive. As a result, the article enters the plasma at different angles for different positions of the first axis. The plasma cross-section at the level at which the plasma contacts the article is asymmetric so that those points on the article that move at a greater linear velocity (due to being farther from the first axis) move longer distances through the plasma. As a result, the plasma processing time becomes more uniform for different points on the article surface. In some embodiments, two shuttles are provided for loading and unloading the plasma processing system. One of the shuttles stands empty waiting to unload the processed articles from the system, while the other shuttle holds unprocessed articles waiting to load them into the system.

Abstract: To move an article in and out of plasma during plasma processing, the article is rotated by a first drive around a first axis, and the first drive is itself rotated by a second drive. As a result, the article enters the plasma at different angles for different positions of the first axis. The plasma cross-section at the level at which the plasma contacts the article is asymmetric so that those points on the article that move at a greater linear velocity (due to being farther from the first axis) move longer distances through the plasma. As a result, the plasma processing time becomes more uniform for different points on the article surface. In some embodiments, two shuttles are provided for loading and unloading the plasma processing system. One of the shuttles stands empty waiting to unload the processed articles from the system, while the other shuttle holds unprocessed articles waiting to load them into the system.

Abstract: To fabricate contacts on a wafer backside, openings (124) are formed in the face side of the wafer (104). A dielectric layer (140) and some contact material (150), e.g. metal, are deposited into the openings. Then the backside is etched until the contacts (150C) are exposed and protrude out. The protruding portion of each contact has an outer sidewall (150V). At least a portion of the sidewall is vertical or sloped outwards with respect to the opening when the contact is traced down. The contact is soldered to an another structure (410), e.g. a die or a PCB. The solder (420) reaches and at least partially covers the sidewall portion which is vertical or sloped outwards. The strength of the solder bond is improved as a result. The dielectric layer protrudes around each contact. The protruding portion (140P) of the dielectric becomes gradually thinner around each contact in the downward direction.

Abstract: A plasma apparatus separately measures multiple plasma jets upstream of where the plasma jets converge into a combined plasma stream. The separate plasma jets can be separately adjusted to place the separate jets in a configuration that provides the combined stream with desired properties for a plasma treatment. The system can include an injector for a neutral jet that becomes part of the combined plasma stream. With an injector, the positions of the plasma jets can be measured relative to the injector so that the plasma jets and the neutral jet are properly aligned to form a combine plasma stream having the properties desired.

Abstract: A semiconductor wafer is diced before thinning. The wafer is diced only part of the way through, to form grooves which are at least as deep as the final thickness of each chip to be obtained from the wafer. Then the wafer backside is etched with a dry etch, for example, atmospheric pressure plasma etch. The wafer is thinned until the grooves are exposed from the backside. The dry etch leaves the chip's backside smooth. After the grooves have been exposed, the dry etch is continued to remove damage from the chip sidewalls and to round the chips' bottom edges and corners. The grooves' aspect ratio is large to reduce the lateral etch rate of the chip sidewalls and thus allow more area for on-chip circuitry.

Abstract: In some embodiments, a circuit structure comprises a semiconductor substrate, an opening passing through the substrate between a first side of the substrate and a second side of the substrate, and a plurality of conductive layers in the opening. In some embodiments, one conductive layer provides an electromagnetic shield that shields the substrate from AC signals carried by a contact pad made from another conductive layer on a backside of the substrate. The conductive layers can also be used to form capacitor/rectifier networks. Manufacturing methods are also provided.

Abstract: A plasma apparatus separately measures multiple plasma jets upstream of where the plasma jets converge into a combined plasma stream. The separate plasma jets can be separately adjusted to place the separate jets in a configuration that provides the combined stream with desired properties for a plasma treatment. The system can include an injector for a neutral jet that becomes part of the combined plasma stream. With an injector, the positions of the plasma jets can be measured relative to the injector so that the plasma jets and the neutral jet are properly aligned to form a combine plasma stream having the properties desired.

Abstract: To fabricate back side contact pads that are suitable for use in a vertical integrated circuit, vias are made in the face side of a wafer, and dielectric and contact pad metal are deposited into the vias. Then the wafer back side is etched until the metal is exposed. When the etch exposes the insulator at the via bottoms, the insulator is etched slower than the wafer material (e.g. silicon). Therefore, when the dielectric is etched off and the metal is exposed, the dielectric protrudes down from the wafer back side around the exposed metal contact pads, by about 8 &mgr;m in some embodiments. The protruding dielectric portions improve insulation between the wafer and the contact pads when the contact pads are soldered to an underlying circuit. In some embodiments, before the contact pads are soldered, additional dielectric is grown on the wafer back side without covering the contact pads.

Abstract: The present invention comprises a dynamic brake that applies restraining frictional force to a wafer in a wafer holder while the wafer holder is substantially at rest, but releases the restraining force as the processing carousel containing several wafer holders rotates about a central axis of the carousel. This dynamic brake preferably comprises a boot that passes through an opening in the wafer holder to rest on the surface of the wafer in an exclusion zone near the wafer's edge. The exclusion zone is typically no more than about 3 mm in extent. The frictional force between the boot and wafer is sufficient to prevent unwanted motion of the wafer in the holder. As the wafer holder rotates about a central axis of the processing carousel, centrifugal forces applied to the brake arising from such rotation cause the boot to pivot upward, releasing the frictional force on the wafer.

Abstract: A semiconductor wafer is diced before thinning. The wafer is diced only part of the way through, to form grooves which are at least as deep as the final thickness of each chip to be obtained from the wafer. Then, the wafer is placed into a non-contact wafer holder, and the wafer backside is blanket etched with a dry etch, for example, atmospheric pressure plasma etch. The wafer is thinned until the grooves are exposed from the backside. The dry etch leaves the chip's backside smooth. After the grooves have been exposed, the dry etch is continued to remove damage from the chip sidewalls and to round the chips' bottom edges and coners. As a result, the chip becomes more reliable, and in particular more resistant to thermal and other stresses.

Abstract: In some embodiments, a fabrication method comprises: forming a structure that has one or more substrates, wherein the one or more substrates are either a single substrate or a plurality of substrates bonded together, wherein the structure comprises a non-electronically-functioning component which includes at least a portion of the one or more substrates and/or is attached to the one or more substrates; wherein the one or more substrates include a first substrate which has: a first side, an opening in the first side, and a conductor in the opening; wherein the method comprises removing material from the structure so that the conductor becomes exposed on a second side of the first substrate. In some embodiments, the second side is a backside of the first substrate, and the exposed conductor provides backside contact pads.

Abstract: In some embodiments, a circuit structure comprises a semiconductor substrate, an opening passing through the substrate between a first side of the substrate and a second side of the substrate, and a plurality of conductive layers in the opening. In some embodiments, one conductive layer provides an electromagnetic shield that shields the substrate from AC signals carried by a contact pad made from another conductive layer on a backside of the substrate. The conductive layers can also be used to form capacitor/rectifier networks. Manufacturing methods also provided.

Abstract: In some embodiments, a fabrication method comprises: forming a structure that has one or more substrates, wherein the one or more substrates are either a single substrate or a plurality of substrates bonded together, wherein the structure comprises a non-electronically-functioning component which includes at least a portion of the one or more substrates and/or is attached to the one or more substrates; wherein the one or more substrates include a first substrate which has: a first side, an opening in the first side, and a conductor in the opening; wherein the method comprises removing material from the structure so that the conductor becomes exposed on a second side of the first substrate. In some embodiments, the second side is a backside of the first substrate, and the exposed conductor provides backside contact pads.

Abstract: In some embodiments, a circuit structure comprises a semiconductor substrate, an opening passing through the substrate between a first side of the substrate and a second side of the substrate, and a plurality of conductive layers in the opening. In some embodiments, one conductive layer provides an electromagnetic shield that shields the substrate from AC signals carried by a contact pad made from another conductive layer on a backside of the substrate. The conductive layers can also be used to form capacitor/rectifier networks. Manufacturing methods also provided.

Abstract: A plasma apparatus separately measures multiple plasma jets upstream of where the plasma jets converge into a combined plasma stream. The separate plasma jets can be separately adjusted to place the separate jets in a configuration that provides the combined stream with desired properties for a plasma treatment. The system can include an injector for a neutral jet that becomes part of the combined plasma stream. With an injector, the positions of the plasma jets can be measured relative to the injector so that the plasma jets and the neutral jet are properly aligned to form a combine plasma stream having the properties desired.