Abstract: An integrated circuit memory device, in one embodiment, includes a substrate having a plurality of bit lines. A first and second inter-level dielectric layer are successively disposed on the substrate. Each of a plurality of source lines and staggered bit line contacts extend through the first inter-level dielectric layer. Each of a plurality of source line vias and a plurality of staggered bit line vias extend through the second inter-level dielectric layer to each respective one of the plurality of source lines and the plurality of staggered bit line contacts. The source lines and staggered bit line contacts that extend tit rough the first inter-level dielectric layer are formed together by a first set of fabrication processes. The source line vias and staggered bit line contacts that extend through the second inter-level dielectric layer are also formed together by a second set of fabrication processes.

Abstract: At integrated circuit memory device, in one embodiment, includes a substrate having a plurality of bit lines. A first and second inter-level dielectric layer are successively disposed on the substrate. Each of a plurality of source lines and staggered bit line contacts extend through the first inter-level dielectric layer. Each of a plurality of source line vias and a plurality of staggered bit line vias extend through the second inter-level dielectric layer to each respective one of the plurality of source lines and the plurality of staggered bit line contacts. The source lines and staggered bit line contacts that extend through the first inter-level dielectric layer are formed together by a first set of fabrication processes. The source line vias and staggered bit line contacts that extend through the second inter-level dielectric layer are also formed together by a second set of fabrication processes.

Abstract: An integrated circuit memory device, in one embodiment, includes a substrate having a plurality of bit lines. A first and second inter-level dielectric layer are successively disposed on the substrate. Each of a plurality of source lines and staggered bit line contacts extend through the first inter-level dielectric layer. Each of a plurality of source line vias and a plurality of staggered bit line vias extend through the second inter-level dielectric layer to each respective one of the plurality of source lines and the plurality of staggered bit line contacts. The source lines and staggered bit line contacts that extend through the first inter-level dielectric layer are formed together by a first set of fabrication processes. The source line vias and staggered bit line contacts that extend through the second inter-level dielectric layer are also formed together by a second set of fabrication processes.

Abstract: At integrated circuit memory device, in one embodiment, includes a substrate having a plurality of bit lines. A first and second inter-level dielectric layer are successively disposed on the substrate. Each of a plurality of source lines and staggered bit line contacts extend through the first inter-level dielectric layer. Each of a plurality of source line vias and a plurality of staggered bit line vias extend through the second inter-level dielectric layer to each respective one of the plurality of source lines and the plurality of staggered bit line contacts. The source lines and staggered bit line contacts that extend through the first inter-level dielectric layer are formed together by a first set of fabrication processes. The source line vias and staggered bit line contacts that extend through the second inter-level dielectric layer are also formed together by a second set of fabrication processes.

Abstract: An integrated circuit memory device, in one embodiment, includes a substrate having a plurality of bit lines. A first and second inter-level dielectric layer are successively disposed on the substrate. Each of a plurality of source lines and staggered bit line contacts extend through the first inter-level dielectric layer. Each of a plurality of source line vias and a plurality of staggered bit line vias extend through the second inter-level dielectric layer to each respective one of the plurality of source lines and the plurality of staggered bit line contacts. The source lines and staggered bit line contacts that extend through the first inter-level dielectric layer are formed together by a first set of fabrication processes. The source line vias and staggered bit line contacts that extend through the second inter-level dielectric layer are also formed together by a second set of fabrication processes.

Abstract: A method of fabricating an integrated circuit memory device including forming a first and second inter-level dielectric layer, an anti-reflective coating layer, and a plurality of electrical connections is disclosed.

Abstract: A semiconductor component and a method for manufacturing the semiconductor component that are suitable for use with low temperature processing. A semiconductor substrate is provided and an optional layer of silicon nitride is formed on the semiconductor substrate using Atomic Layer Deposition (ALD). A layer of dielectric material is formed on the silicon nitride layer using Sub-Atmospheric Chemical Vapor Deposition (SACVD) at a temperature below about 450° C. When the optional layer of silicon nitride is not present, the SACVD dielectric material is formed on the semiconductor substrate. A contact hole having sidewalls is formed through the SACVD dielectric layer, through the silicon nitride layer, and exposes a portion of the semiconductor substrate. A layer of tungsten nitride is formed on the exposed portion of the semiconductor substrate and along the sidewalls of the contact hole. Tungsten is formed on the layer of tungsten nitride.

Abstract: A method of forming a contact in a semiconductor device provides a titanium contact layer in a contact hole and a MOCVD-TiN barrier metal layer on the titanium contact layer. Impurities are removed from the MOCVD-TiN barrier metal layer by a plasma treatment in a nitrogen-hydrogen plasma. The time period for plasma treating the titanium nitride layer is controlled so that penetration of nitrogen into the underlying titanium contact layer is substantially prevented, preserving the titanium contact layer for subsequently forming a titanium silicide at the bottom of the contact.

Abstract: A composite ?-Ta/graded tantalum nitride/TaN barrier layer is formed in Cu interconnects with a controlled surface roughness for improved adhesion, electromigration resistance and reliability. Embodiments include lining a damascene opening, such as a dual damascene opening in a low-k interlayer dielectric, with an initial layer of TaN, forming a graded tantalum nitride layer on the initial TaN layer and then forming an ?-Ta layer on the graded TaN layer, the composite barrier layer having an average surface roughness (Ra) of about 25 ? to about 50 ?. Embodiments further include controlling the surface roughness of the composite barrier layer by varying the N2 flow rate and/or ratio of the thickness of the combined ?-Ta and graded tantalum nitride layers to the thickness of the initial TaN layer.

Abstract: A process of forming an electronic device can include depositing a first layer over a substrate and depositing a second layer over the first layer. In one embodiment, depositing the first layer is performed at a first alternating current (“AC”) power, and depositing the second layer is performed at a second AC power that is different from the first AC power. In another embodiment, the first layer is formed by a physical vapor deposition technique at a first power sufficient to remove the insulating layer using first metal ions, wherein the first layer includes an overhanging portion extending over the bottom of the opening. In a further embodiment, the second layer is formed by the physical vapor deposition technique using second metal ions and a second power sufficient to reduce a lateral dimension of the overhanging portion.

Abstract: A method of forming a contact through a material includes forming a via through a dielectric material and cleaning the via using a dilute hydrofluoric (DHF) acid solution. The method further includes depositing a barrier layer within the via and depositing metal adjacent the barrier layer.

Abstract: A semiconductor component having a titanium silicide contact structure and a method for manufacturing the semiconductor component. A layer of dielectric material is formed over a semiconductor substrate. An opening having sidewalls is formed in the dielectric layer and exposes a portion of the semiconductor substrate. Titanium silicide is disposed on the dielectric layer, sidewalls, and the exposed portion of the semiconductor substrate. The titanium silicide may be formed by disposing titanium on the dielectric layer, sidewalls, and exposed portion of the semiconductor substrate and reacting the titanium with silane. Alternatively, the titanium silicide may be sputter deposited. A layer of titanium nitride is formed on the titanium silicide. A layer of tungsten is formed on the titanium nitride. The tungsten, titanium nitride, and titanium silicide are polished to form the contact structures.

Abstract: A method for forming an integrated circuit system is provided including forming a substrate having a core region and a periphery region, forming a charge storage stack over the substrate in the core region, forming a gate stack with a stack header having a metal portion over the substrate in the periphery region, and forming a memory system with the stack header over the charge storage stack.

Abstract: A memory system includes a substrate, forming an insulator over the substrate, forming a gate layer over the insulator, forming a stability layer over the gate layer, and forming a conductive layer over the stability layer.

Abstract: An integrated circuit system is provided including forming a memory section having a spacer with a substrate, forming an outer doped region of the memory section in the substrate, forming a contact on the outer doped region, thinning the contact for forming a thinned contact, and forming a metal plug on the thinned contact.

Abstract: A method for manufacturing a memory device having a metal nanocrystal charge storage structure. A substrate is provided and a first layer of dielectric material is grown on the substrate. A layer of metal oxide having a first heat of formation is formed on the first layer of dielectric material. A metal layer having a second heat of formation is formed on the metal oxide layer. The second heat of formation is greater than the first heat of formation. The metal oxide layer and the metal layer are annealed which causes the metal layer to reduce the metal oxide layer to metallic form, which then agglomerates to form metal islands. The metal layer becomes oxidized thereby embedding the metal islands within an oxide layer to form a nanocrystal layer. A control oxide is formed over the nanocrystal layer and a gate electrode is formed on the control oxide.

Abstract: A method for manufacturing a memory device having a metal nanocrystal charge storage structure. A substrate is provided and a first layer of dielectric material is grown on the substrate. An absorption layer is formed on the first layer of dielectric material. The absorption layer includes a plurality of titanium atoms bonded to the first layer of dielectric material, a nitrogen atom bonded to each titanium atom, and at least one ligand bonded to the nitrogen atom. The at least one ligand is removed from the nitrogen atoms to form nucleation centers. A metal such as tungsten is bonded to the nucleation centers to form metallic islands. A dielectric material is formed on the nucleation centers and annealed to form a nanocrystal layer. A control oxide is formed over the nanocrystal layer and a gate electrode is formed on the control oxide.

Abstract: A memory device having a metal nanocrystal charge storage structure and a method for its manufacture. The memory device may be manufactured by forming a first oxide layer on the semiconductor substrate, then disposing a porous dielectric layer on the oxide layer and disposing a second oxide layer on the porous dielectric layer. A layer of electrically conductive material is formed on the second layer of dielectric material. An etch mask is formed on the electrically conductive material. The electrically conductive material and the underlying dielectric layers are anisotropically etched to form a dielectric structure on which a gate electrode is disposed. A metal layer is formed on the dielectric structure and the gate electrode and treated so that portions of the metal layer diffuse into the porous dielectric layer. Then the metal layer is removed.

Abstract: A method for manufacturing a semiconductor component that inhibits formation of wormholes in a semiconductor substrate. A contact opening is formed in a dielectric layer disposed on a semiconductor substrate. The contact opening exposes a portion of the semiconductor substrate. A sacrificial layer of oxide is formed on the exposed portion of the semiconductor substrate and along the sidewalls of the contact opening. Silane is reacted with tungsten hexafluoride to form a hydrofluoric acid vapor and tungsten. The hydrofluoric acid vapor etches away the sacrificial oxide layer and a thin layer of tungsten is formed on the exposed portion of the semiconductor substrate. After forming the thin layer of tungsten, the reactants may be changed to more quickly fill the contact opening with tungsten.

Abstract: A composite ?-Ta/graded tantalum nitride/TaN barrier layer is formed in Cu interconnects with a controlled surface roughness for improved adhesion, electromigration resistance and reliability. Embodiments include lining a damascene opening, such as a dual damascene opening in a low-k interlayer dielectric, with an initial layer of TaN, forming a graded tantalum nitride layer on the initial TaN layer and then forming an ?-Ta layer on the graded TaN layer, the composite barrier layer having an average surface roughness (Ra) of about 25 ? to about 50 ?. Embodiments further include controlling the surface roughness of the composite barrier layer by varying the N2 flow rate and/or ratio of the thickness of the combined ?-Ta and graded tantalum nitride layers to the thickness of the initial TaN layer.