Abstract: A semiconductor device includes a semiconductor substrate, an isolation structure disposed in the semiconductor substrate, a conductive layer disposed over the isolation structure, a capacitor disposed over the isolation structure, the capacitor including a top electrode, a bottom electrode, and a dielectric disposed between the top electrode and the bottom electrode, and a first contact electrically coupling the conductive layer and the bottom electrode, the bottom electrode substantially engaging the first contact on at least two faces.

Abstract: A method for forming a semiconductor device is provided. The method includes the following steps. A substrate having a first contact is provided. A layered structure is formed on the substrate. A recess is formed into the layered structure to expose at least a portion of the first contact. A glue layer is formed on the layered structure and the at least a portion of the first contact. The glue layer is removed from the at least a portion of the first contact. A second contact is formed contacting the first contact and the glue layer.

Abstract: A method of forming a contact plug of an eDRAM device includes the following steps: forming a tungsten layer with tungsten seam on a dielectric layer to fill a contact hole; removing the tungsten layer from the top surface of the dielectric layer, recessing the tungsten layer in the contact hole to form a recess of about 600˜900 Angstroms in depth below the top surface of the dielectric layer, depositing a conductive layer on the dielectric layer and the recessed tungsten plug to fill the recess; and removing the conductive layer from the top surface of the dielectric layer to form a conductive plug on the recessed tungsten plug in the contact hole.

Abstract: A novel SOC structure and method of making the same are provided. An SOC comprises a logic region, an SRRM and a DRAM region. The storage capacitor in a DRAM cell is formed in the first dielectric layer in an MIM (metal-insulator-metal) configuration, having a large vertical surface area. A butted contact, formed in said first dielectric layer, comprises a bottom portion abutting a first and second conductive region in an SRAM cell, and a vertically aligned top portion coupled to a first metal layer. The top portion has a substantially larger depth than that of the bottom portion, while substantially smaller in size. Forming this SOC structure does not require adding complex, error-prone additional processing steps on an existing CMOS manufacturing process, thus having little impact on the overall SOC product yield.

Abstract: Semiconductor devices having a dual polysilicon electrode and a method of manufacturing are provided. The semiconductor devices include a first polysilicon layer deposited on a second polysilicon layer. Each polysilicon layer may be doped individually. The method also allows for some semiconductor devices on a wafer to have a single polysilicon wafer and other devices to have a dual polysilicon layer. In one embodiment, the semiconductor devices are utilized to form a memory device wherein the storage capacitors and transistors located in the cell region are formed with a dual polysilicon layer and devices in the periphery region are formed with a single polysilicon layer.

Abstract: Within a method for fabricating a capacitor structure within a microelectronic fabrication there is formed a capacitor structure comprising a pair of capacitor plate layers separated by a capacitor dielectric layer. Within the method, at least one of the pair of capacitor plates is formed of a doped amorphous silicon material formed incident to isotropic etching within an etchant solution comprising aqueous ammonium hydroxide, without hydrogen peroxide.

Abstract: Within a method for fabricating a capacitor structure within a microelectronic fabrication there is formed a capacitor structure comprising a pair of capacitor plate layers separated by a capacitor dielectric layer. Within the method, at least one of the pair of capacitor plates is formed of a doped amorphous silicon material formed incident to isotropic etching within an etchant solution comprising aqueous ammonium hydroxide, without hydrogen peroxide.

Abstract: Semiconductor devices having a dual polysilicon electrode and a method of manufacturing are provided. The semiconductor devices include a first polysilicon layer deposited on a second polysilicon layer. Each polysilicon layer may be doped individually. The method also allows for some semiconductor devices on a wafer to have a single polysilicon wafer and other devices to have a dual polysilicon layer. In one embodiment, the semiconductor devices are utilized to form a memory device wherein the storage capacitors and transistors located in the cell region are formed with a dual polysilicon layer and devices in the periphery region are formed with a single polysilicon layer.

Abstract: A method of fabricating an STI structure comprising the following steps. A silicon structure having a pad oxide layer formed thereover is provided. A hard mask layer is formed over the pad oxide layer. The hard mask layer and the pad oxide layer are patterned to form an opening exposing a portion of the silicon structure. The opening having exposed side walls. A spacer layer is formed over the patterned hard mask layer, the exposed side walls of the opening and lining the opening. The structure is subjected to an STI trench etching process to: (1) remove the spacer layer from over the patterned hard mask layer; form spacers over the side walls; (2) the spacers being formed in-situ from the spacer layer; and (3) etch an STI trench within the silicon structure wherein the spacers serve as masks during at least a portion of time in which the STI trench is formed. The STI trench having corners. Any remaining portion of the spacers are removed.

Abstract: Within a method for fabricating a capacitor structure within a microelectronic fabrication there is formed a capacitor structure comprising a pair of capacitor plate layers separated by a capacitor dielectric layer. Within the method, at least one of the pair of capacitor plates is formed of a doped amorphous silicon material formed incident to isotropic etching within an etchant solution comprising aqueous ammonium hydroxide, without hydrogen peroxide.

Abstract: A process for fabricating an alternate fin type capacitor structure, used to increase capacitor surface area has been developed. The process features the formation of fin shaped, storage node structures, located in fin type capacitor openings, which are in turn defined in a group of composite insulator layers. A first fin type capacitor opening is formed by selectively creating lateral recesses in first type insulator layers, exposed in a first capacitor opening in the composite insulator layers, while an adjacent, second fin type capacitor opening is formed by selectively creating lateral recesses in second type insulator components, exposed in a second capacitor opening located in the same composite insulator layers. Portions of the lateral recesses in the first and second fin type capacitor openings overlay, allowing intertwined or alternate, storage node structures to be realized, thus reducing the space needed for the capacitor structure.

Abstract: A method for forming a self-aligned capping layer over a metal filled feature in a multi-layer semiconductor device including providing an anisotropically etched feature included in a substrate; blanket depositing a first barrier layer over the anisotropically etched feature to prevent diffusion of a metal species into the substrate; filling the anisotropically etched feature with a metal to form a metal filled feature substantially filled with metal; planarizing the substrate surface to include forming an exposed surface of the metal filled feature; and, selectively depositing a second barrier layer to cover the exposed surface of the metal filled feature to form a capping layer.

Abstract: A method of fabricating an STI, comprising the following steps. A silicon structure having a pad oxide layer formed thereover is provided. An undoped poly buffer layer is formed over the pad oxide layer. A hard mask layer is formed over the undoped poly buffer layer. The hard mask layer, the undoped poly buffer layer and the pad oxide layer are patterned to form an opening exposing a portion of the silicon structure within an active area. The opening having exposed side walls. Inorganic spacers are formed over the exposed side walls. Using the patterned hard mask layer and the spacers as hard masks, the silicon structure is etched to form an STI opening within the active area. The inorganic spacers are removed exposing the upper corners of the STI opening. Using an oxidation process, a liner oxide layer is formed within the STI opening, over the upper corners of the STI opening and at least the patterned undoped poly buffer layer exposed by the removal of the inorganic spacers.