Abstract: An electronic device, including an integrated circuit, can include a buried conductive region and a semiconductor layer overlying the buried conductive region, wherein the semiconductor layer has a primary surface and an opposing surface lying closer to the buried conductive region. The electronic device can also include a first doped region and a second doped region spaced apart from each other, wherein each is within the semiconductor layer and lies closer to primary surface than to the opposing surface. The electronic device can include current-carrying electrodes of transistors. A current-carrying electrode of a particular transistor includes the first doped region and is a source or an emitter and is electrically connected to the buried conductive region. Another current-carrying electrode of a different transistor includes the second doped region and is a drain or a collector and is electrically connected to the buried conductive region.

Abstract: A process of forming an electronic device can include providing a workpiece comprising a substrate, including an underlying doped region, and a semiconductor portion overlying the underlying doped region, wherein the semiconductor portion has a primary surface spaced apart from the underlying doped region. The process can further include forming a vertically-oriented conductive region extending from the primary surface towards the underlying doped region, forming a horizontally-oriented doped region adjacent to the primary surface, and forming a conductive electrode over, spaced-apart from, and electrically insulated from the vertically-oriented doped region. The process can still further include forming a gate electrode after forming the conductive electrode. The electronic device can include a transistor that includes the underlying doped region, the vertically-oriented conductive region, the horizontally-oriented doped region, and the gate electrode.

Abstract: A semiconductor device (10) having a stacked-gate buffer (30) wherein the stacked-gate buffer (30) has a substrate (65) and a top substrate region (70) both with the same first conductivity type. The buffer (30) also has two transistors (95.105), each with a current carrying electrode and a control electrode (90, 100). A deep doped region (120) lies between the first (90) and second (100) control electrodes where the deep doped region (120) is another current carrying electrode for the first transistor (95) and another current carrying electrode for the second transistor (105) and the deep doped region (120) has a second conductivity that is opposite the first conductivity type. A deeper doped region (80) is also part of the stacked-gate buffer which has a second conductivity type and lies between the first (90) and second (100) control electrodes and is deeper than the deep doped region (120). A method of forming the device is also provided herein.

Abstract: A dual inlaid copper interconnect structure uses a plasma enhanced nitride (PEN) bottom capping layer and a silicon rich silicon oxynitride intermediate etch stop layer. The interfaces (16a, 16b, 20a, and 20b) between these layers (16 and 20) and their adjacent dielectric layers (18 and 22) are positioned in the stack (13) independent of the desired aspect ratio of trench openings of the copper interconnect in order to improve optical properties of the dielectric stack (13). Etch processing is then used to position the layers (16) and (20) at locations within the inlaid structure depth that result in one or more of reduced DC leakage current, improved optical performance, higher frequency of operation, reduced cross talk, increased flexibility of design, or like improvements.

Abstract: The reliability of integrated circuits fabricated with trench isolation is improved by forming a trench isolation structure with a void-free trench plug (36). In one embodiment, a polysilicon layer (28) is formed within a trench (22) and then subsequently oxidized to form a first dielectric layer (30). The first dielectric layer (30) is then etched and a second dielectric layer (34) is subsequently formed over the etched dielectric layer (32). A portion of the second dielectric layer (34) is then removed using chemical-mechanical polishing to form a void-free trench plug (36) within the trench (22). In addition, reliability is also improved by minimizing subsequent etching of trench plug (36) after it has been formed.

Abstract: A process for forming a capacitor with a high-k dielectric or ferroelectric layer within a semiconductor device is used to reduce the likelihood of oxidation or materials interactions between that layer and an underlying layer. A first electrode layer includes atoms that form along grain boundaries within the first electrode layer to reduce the oxidation of a conductive plug or undesired materials interactions.

Abstract: An electroplating system (30) and process makes electrical current density across, a semiconductor device substrate (20) surface more uniform during plating to allow for a more uniform or tailored deposition of a conductive material. The electrical current density modifiers (364 and 37) reduce the electrical current density near the edge of the substrate (20). By reducing the current density near the edge of the substrate (20), the plating becomes more uniform or can be tailored so that slightly more material is plated near the center of the substrate (20). The system can also be modified so that the material that electrical current density modifier portions (364) on structures (36) can be removed without having to disassemble any portion of the head (35) or otherwise remove the structures (36) from the system. This in-situ cleaning reduces the amount of equipment downtime, increases equipment lifetime, and reduces particle counts.

Abstract: A semiconductor device substrate (600, 900) includes a semiconductor device (310, 314, 405, 424, 506, 912, 914, 918) and an alignment structure (508, 902) lying near the semiconductor device. The substrate (600, 900) includes a reflective layer (506, 510) and an antireflective layer (316, 926). The antireflective layer (316, 926) has a positional relationship with respect to the reflective layer (506, 510). The positional relationship is either such that the antireflective layer (316, 926) overlies all the reflective layer (506, 510) or such that none of the antireflective layer (316, 926) overlies the reflective layer (506, 510). The alignment structure (508, 902) includes an alignment feature (512), such as an alignment key.

Abstract: Selective placement of polishing dummy feature patterns, rather than indiscriminate placement of polishing dummy feature patterns, is used. Both low frequency (hundreds of microns and larger) and high frequency (10 microns and less) of topography changes are examined. The polishing dummy feature patterns can be specifically tailored to a semiconductor device and polishing conditions used in forming the semiconductor device. When designing an integrated circuit, polishing effects for the active features can be predicted. After polishing dummy feature pattern(s) are placed into the layout, the planarity can be examined on a local level (a portion but not all of the device) and a more global level (all of the device, devices corresponding to a reticle field, or even an entire wafer).

Abstract: A refractory Metal Nitride and a refractory metal Silicon Nitride layer (64) can be formed using metal organic chemical deposition. More specifically, tantalum nitride (TaN) (64) can be formed by a Chemical Vapor Deposition (CVD) using Ethyltrikis (Diethylamido) Tantalum (ETDET) and ammonia (NH3). By the inclusion of silane (SiH4), tantalum silicon nitride (TaSiN) (64) layer can also be formed. Both of these layers can be formed at wafer temperatures lower than approximately 400° C. with relatively small amounts of carbon (C) within the film. Therefore, the embodiments of the present invention can be used to form tantalum nitride (TaN) or tantalum silicon nitride (TaSiN) (64) that is relatively conformal and has reasonably good diffusion barrier properties.

Abstract: A method of forming a hard mask for use in the formation of a refractory radiation mask including providing a membrane structure, forming a radiation absorbing layer to be patterned on the membrane structure, forming a hard mask layer on the surface of the membrane structure, the hard mask layer including a material system having a nominally zero stress and therefore reduced distortion of the membrane structure, and patterning the hard mask layer.

Abstract: Conductive bumps (32) are formed to overlie a semiconductor die (11). The conductive bumps (32) typically have reduced levels of lead, flow at a temperature no greater than 260° C., and have reduced problems associated with alpha particles. In one embodiment, the conductive bump (32) includes a mostly tin (20) with a relatively thin layer of lead (30). The lead (30) and a portion of the tin (20) interact to form a relatively low melting solder close to the eutectic point for lead and tin. Most of the tin (20) remains unreacted and can form a stand off between the semiconductor die (11) and the packaging substrate (42). Other metals and impurities can be used to improve the mechanical or electrical properties of the conductive bumps (32).

Abstract: In one embodiment, a conductive interconnect (38) is formed in a semiconductor device by depositing a dielectric layer (28) on a semiconductor substrate (10). The dielectric layer (28) is then patterned to form an interconnect opening (29). A tantalum nitride barrier layer (30) is then formed within the interconnect opening (29). A catalytic layer (31) comprising a palladium-tin colloid is then formed overlying the tantalum nitride barrier layer (30). A layer of electroless copper (32) is then deposited on the catalytic layer (31). A layer of electroplated copper (34) is then formed on the electroless copper layer (32), and the electroless copper layer (32) serves as a seed layer for the electroplated copper layer (34). Portions of the electroplated copper layer (34) are then removed to form a copper interconnect (38) within the interconnect opening (29).

Abstract: Programmable cells (22, 24, 26, 28) may have discontinuous storage elements (228, 248, 268, 288) as opposed to a continuous floating gate. Each cell further includes first and second current carry electrodes (222, 226, 242, 246, 262, 266, 282, 286) and a control gate electrode (224, 244, 264, 284). In one embodiment, potentials for programming can be selected to program a programmable cell relatively quickly without the need for relatively high potentials. Alternatively, programming can be achieved by flowing current in one direction and then in the opposite direction. In some embodiments, time-variant signals can used during an operation. Embodiments of the present invention can be used with different types of programmable cells including those used in memory arrays and in field programmable gate arrays.

Abstract: The present invention includes a process for forming an electrical device. In one embodiment, the process includes applying a solid patternable film over a substrate and forming a conductive material over the substrate while the solid patternable film overlies the substrate, wherein the conductive material extends at least partially within an opening in the patternable film. In another embodiment, the process includes applying a patterned film over a substrate having a pad and exposing the patterned film and the substrate to energy. The patterned film includes a first region that includes a conductor and a second region that does not have a conductor. The energy of the exposure forms an electrical connection between the conductor and the pad.

Abstract: A method for forming an oxynitride gate dielectric layer (202, 204) begins by providing a semiconductor substrate (200). This semiconductor substrate is cleaned via process steps (10-28). Optional nitridation and oxidation are performed via steps (50 and 60) to form a thin interface layer (202). Bulk oxynitride gate deposition occurs via a step (70) to form a bulk gate dielectric material (204) having custom tailored oxygen and nitrogen profile and concentration. A step (10) is then utilized to in situ cap this bulk dielectric layer (204) with a polysilicon or amorphous silicon layer (208). The layer (208) ensures that the custom tailors oxygen and nitrogen profile and concentration of the underlying gate dielectric (204) is preserved even in the presence of subsequent wafer exposure to oxygen ambients.

Abstract: Narrow and wide, planar field isolation region (72, 74, 152, 172, 182) is formed by forming trenches (52, 54) within a substrate (10). For wide, planar field isolation regions (72, 152, 172, 182), the trenches (52) define at least one mesa (76, 150, 170, 180) within the field isolation region (72, 152, 172, 182). The trenches (52, 54) are filled with a material (62) that is polished or etched to form the planar field isolation region (72, 74, 152, 172, 182) where the wide, planar field isolation regions (72, 152, 172, 182) include the mesa(s) (76, 150, 170, 180). Etching can be used or by polishing with minimal, if any, dishing occurs because the widths of the trenches (52, 54) are kept relatively narrow (usually no more than five microns wide). Mesas (180) within a wide, planar field isolation region (182) can form linguistic characters to better identify the part number or mask set of the device.

Abstract: A method for forming an improved embedded DRAM structure, that is formed on-chip with CMOS logic portions, begins by forming dual inlaid regions (34a through 34c). The region (34a) is a portion of a dual inlaid region which is filled with an oxidation tolerant material (e.g., iridium or ruthenium) to form a metallic plug (36a). This plug (36a) forms a storage node region for a DRAM and electrically contacts to a current electrode (26) of a DRAM pass transistor. Opening (34b) is filled concurrently with the filling of opening (34a), to form a metallic plug (36b) which forms a bit line contact for the DRAM cell. A top portion of the dual inlaid structure (34c) is filled concurrent with regions (34a and 34b) to enable formation of a bottom electrode of the ferroelectric DRAM capacitor. Since the geometry of the region (36c) is defined by dual inlaid/CMP processing, no RIE-defined sidewall of the bottom capacitor electrode is present whereby capacitor leakage current is reduced.

Abstract: A method for forming a copper interconnect begins by depositing a barrier layer (48) within an in-laid region (18). An edge exclusion protection layer (50) is formed over the barrier layer (48), and this layer (50) is processed so that it only lies within the edge exclusion region (20) of the wafer. The layer (50) is removed from active area portions of the wafer so that contact resistance of copper interconnects is not affected. Wet surface processing is used to form a catalyst (64b) on the wafer surface to enable electroless copper plating within active areas of the wafer to form a copper seed layer (52). The layer (52) is not formed in an edge exclusion region (20). Electroplating is then used to thicken the copper material to form a copper layer (54) over the layer (52) wherein the in-laid copper interconnect is completed.

Abstract: A nonvolatile memory includes five transistors. The memory has an MOS transistor in series with two pairs of transistors, where each pair includes a floating gate transistor and a metal-oxide-semiconductor transistor electrically connected in parallel. The memory structure may be formed with three levels of silicon-containing or metal-containing layers. The memory structure is less susceptible to read disturb errors compared to a prior art dual-bit nonvolatile memory structure.