Abstract: A method for manufacturing an integrated circuit system that includes: providing a substrate; forming a mask layer over the substrate; implanting a first well through an opening in the mask layer into the substrate; and implanting a second well through the mask layer and the opening via a single implant into the substrate.

Abstract: An integrated circuit system that includes: providing a substrate; forming a trench within the substrate; forming a liner on a sidewall of the trench; and forming a dielectric material at a trench bottom with a dielectric width dimension that exceeds that of a width dimension of the trench.

Abstract: A method (and semiconductor device) of fabricating a semiconductor device provides a shallow trench isolation (STI) structure or region by implanting ions in the STI region. After implantation, the region (of substrate material and ions of a different element) is thermally annealed producing a dielectric material operable for isolating two adjacent field-effect transistors (FET). This eliminates the conventional steps of removing substrate material to form the trench and refilling the trench with dielectric material. Implantation of nitrogen ions into an STI region adjacent a p-type FET applies a compressive stress to the transistor channel region to enhance transistor performance. Implantation of oxygen ions into an STI region adjacent an n-type FET applies a tensile stress to the transistor channel region to enhance transistor performance.

Abstract: A semiconductor processing system with ultra low-K dielectric is provided including providing a substrate having an electronic circuit, forming an ultra low-K dielectric layer, having porogens, over the substrate, blocking an incoming radiation from a first region of the ultra low-K dielectric layer, evaporating the porogens from a second region of the ultra low-K dielectric layer by projecting the incoming radiation on the second region, and removing the ultra low-K dielectric layer in the first region with a developer.

Abstract: A method of forming shallow trench isolation (STI) structures using a multi-step etch process is disclosed. The first etch step is performed by selectively etching the substrate at a substantially higher etching rate than the mask layer to form preliminary openings having steep taper angles. The second etch step is performed by non-selectively etching the substrate to deepen the preliminary openings to form STI gaps with substantially flat bottoms.

Abstract: A hybrid orientation substrate includes a base substrate having a first orientation, a first surface layer having a first orientation disposed on the base substrate in a first region, and a second surface layer disposed on the base substrate in a second region. The second surface layer has an upper sub-layer having a second orientation, and a lower sub-layer between the base substrate and the upper sub-layer. The lower sub-layer having a first stress induces a second stress on the upper sub-layer.

Abstract: Methods of forming integrated circuit device having electrical interconnects include forming an electrically insulating layer on a substrate and forming a hard mask on the electrically insulating layer. The hard mask and the electrically insulating layer are selectively etched in sequence using a mask to define an opening therein. This opening, which may be a via hole, exposes inner sidewalls of the hard mask and the electrically insulating layer. The inner sidewall of the hard mask is then recessed relative to the inner sidewall of the electrically insulating layer and a sacrificial reaction layer is formed on the inner sidewall of the electrically insulating layer. This reaction layer operates to recess the inner sidewall of the electrically insulating layer. The reaction layer is then removed to define a wider opening having relatively uniform sidewalls. This wider opening is then filled with an electrical interconnect.

Abstract: Methods of forming devices include forming a first electrically insulating layer having a metal interconnection therein, on a substrate and then forming a first electrically insulating barrier layer on an upper surface of the metal interconnection and on the first electrically insulating layer. The first electrically insulating barrier layer is exposed to a plasma that penetrates the first electrically insulating barrier and removes oxygen from an upper surface of the metal interconnection. The barrier layer may have a thickness in a range from about 5 ? to about 50 ? and the plasma may be a hydrogen-containing plasma that converts oxygen on the upper surface of the metal interconnection to water.

Abstract: A processing layer, such as silicon, is formed on a metal silicide contact followed by a metal layer. The silicon and metal layers are annealed to increase the thickness of the metal silicide contact. By selectively increasing the thickness of silicide contacts, Rs of transistors in iso and nested regions can be matched.

Abstract: The present invention relates to integrated circuits. In particular, but not exclusively, the invention relates to a method and apparatus for connecting elements of integrated circuits with interconnects having one or more voids formed between adjacent interconnects. Embodiments of the invention provide apparatus for connecting elements in an integrated circuit device, comprising: at least one interconnect comprising one or more sidewalls; an interconnect sidewall spacer element arranged to provide structural support to the interconnect and formed on at least one of the interconnect sidewalls; and at least one void adjacent said interconnect and extending from the sidewall spacer element.

Abstract: An integrated circuit system that includes: providing a substrate; depositing a dielectric on the substrate; depositing an isolation dielectric on the dielectric; forming a trench through the isolation dielectric and the dielectric to expose the substrate; depositing a dielectric liner over the integrated circuit system; processing the dielectric liner to form a trench spacer; and depositing an epitaxial growth within the trench that includes a crystalline orientation that is substantially identical to the substrate.

Abstract: Methods of forming integrated circuit devices include depositing an electrically insulating layer onto an integrated circuit substrate having integrated circuit structures thereon. This deposition step results in the formation of an electrically insulating layer having an undulating surface profile, which includes at least one peak and at least one valley adjacent to the at least one peak. A non-uniform thickening step is then performed. This non-uniform thickening step includes thickening a portion of the electrically insulating layer by redepositing portions of the electrically insulating layer from the least one peak to the at least one valley. This redeposition occurs using a sputter deposition technique that utilizes the electrically insulating layer as a sputter target.

Abstract: A method of forming a barrier layer and cap comprised of CuSiN for an interconnect. We provide an interconnect opening in a dielectric layer over a semiconductor structure. We form a CuSiN barrier layer over the sidewalls and bottom of the interconnect opening by reacting with the first copper layer. We then form an interconnect over the CuSiN layer filling the interconnect opening. We can form a CuSiN cap layer on the top surface of the interconnect.

Abstract: Methods of forming integrated circuit devices include forming a field effect transistor having a gate electrode, a sacrificial spacer on a sidewall of the gate electrode and silicided source/drain regions. The sacrificial spacer is used as an implantation mask when forming highly doped portions of the source/drain regions. The sacrificial spacer is then removed from the sidewall of the gate electrode. A stress-inducing electrically insulating layer, which is configured to induce a net tensile stress (for NMOS transistors) or compressive stress (for PMOS transistors) in a channel region of the field effect transistor, is then formed on the sidewall of the gate electrode.

Abstract: Methods of forming integrated circuit devices include forming a trench in a surface of semiconductor substrate and filling the trench with an electrically insulating region having a seam therein. The trench may be filled by depositing a sufficiently thick electrically insulating layer on sidewalls and a bottom of the trench. Curing ions are then implanted into the electrically insulating region at a sufficient energy and dose to reduce a degree of atomic order therein. The curing ions may be ones selected from a group consisting of nitrogen (N), phosphorus (P), boron (B), arsenic (As), carbon (C), argon (Ar), germanium (Ge), helium (He), neon (Ne) and xenon (Xe). These curing ions may be implanted at an energy of at least about 80 KeV and a dose of at least about 5×1014 ions/cm2. The electrically insulating region is then annealed at a sufficient temperature and for a sufficient duration to increase a degree of atomic order within the electrically insulating region.

Abstract: A method of making a semiconductor device is disclosed. A semiconductor body, a gate electrode and source/drain regions are provided. A liner is provided that covers the gate electrode and the source/drain regions. Silicide regions are formed on the semiconductor device by etching a contact hole through the liner.

Abstract: Methods of forming interconnect structures include forming a first metal wiring pattern on a first dielectric layer and forming a capping layer (e.g., SiCN layer) on the first copper wiring pattern. An adhesion layer is deposited on the capping layer, using a first source gas containing octamethylcyclotetrasilane (OMCTS) at a volumetric flow rate in a range from about 500 sccm to about 700 sccm and a second gas containing helium at a volumetric flow rate in a range from about 1000 to about 3000 sccm. The goal of the deposition step is to achieve an adhesion layer having an internal compressive stress of greater than about 150 MPa therein, so that the adhesion layer is less susceptible to etching/cleaning damage and moisture absorption during back-end processing steps. Additional dielectric and metal layers are then deposited on the adhesion layer.

Abstract: An interconnect stack and a method of manufacturing the same wherein the interconnect has vertical sidewall vias. The interconnect stack includes a substrate, a metal interconnect formed in the substrate, an etch stop formed on the substrate and the metal interconnect, and an interlayer dielectric (ILD) layer having at least one via formed therein extending through a transition layer formed on the etch stop layer. The via is formed by etching the ILD to a first depth and ashing the interconnect stack to modify a portion of the ILD between the portion of the via formed by etching and the transition layer. Ashing converts this portion of the ILD to an oxide material. The method includes wet etching the interconnect to remove the oxide material and a portion of the transition layer to form a via extending through the ILD to the etch stop layer.

Abstract: An integrated circuit hard mask processing system is provided including providing a substrate having an integrated circuit; forming an interconnect layer over the integrated circuit; applying a low-K dielectric layer over the interconnect layer; forming a via opening through the low-K dielectric layer to the interconnect layer; and forming a carbon implant region around the via opening, a trench opening, or a combination thereof, for protecting the low-K dielectric layer.

Abstract: A method and structure for a memory device, such as a 1T-SRAM, having a capacitor top plate directly over a doped bottom plate region. An example device comprises the following. An isolation film formed as to surround an active area on a substrate. A gate dielectric and gate electrode formed over a portion of the active area. A source element and a drain element in the substrate adjacent to the gate electrode. The drain element is comprised of a drain region and a bottom plate region. The drain region is between the bottom plate region and the gate structure. A capacitor dielectric and a capacitor top plate are over at least portions of the bottom plate region.