摘要:
A new method is provided for the creation of copper interconnects. A pattern of copper interconnects is created, a protective layer of semiconductor material is deposited over the surface of the created copper interconnects. The protective layer is patterned and etched, exposing the surface of the pattern of copper interconnects. The exposed copper surface is Ar sputtered after which a first barrier layer is deposited. The patterned and etched layer of protective material is removed, leaving in place overlying the pattern of copper interconnects a protective layer of first barrier material. A dielectric barrier layer, in the form of a layer of etch stop material, is deposited after which additional layers of dielectric interspersed with layers of etch stop material are deposited. Via and trench patterns are etched aligned with a copper pattern to which an electrical contact is to be established, the copper pattern being protected by the first layer of barrier material. A second barrier layer is deposited, the via and trench pattern is filled with copper after which excess copper is removed by polishing the surface of the deposited layer of copper.
摘要:
An embodiment of the invention shows a process to form a damascene opening preferably without hardmask overhang or dielectric layer undercut/void. The low-k dielectric material can be sandwiched in two hardmask films to form the dielectric film through which an interconnect opening is etched. A first example embodiment comprises the following. We form a lower interconnect and an insulating layer over a semiconductor structure. We form a first hardmask a dielectric layer, and a second hardmask layer, over the lower interconnect and insulating layer. We etch a first interconnect opening in the first hardmask, the dielectric layer and the second hardmask layer. Lastly, we form an interconnect in the first interconnect opening.
摘要:
An integration approach to improve electromigration resistance in a semiconductor device is described. A via hole is formed in a stack that includes an upper dielectric layer, a middle TiN ARC, and a lower first metal layer and is filled with a conformal diffusion barrier layer and a second metal layer. A key feature is that the etch process can be selected to vary the shape and location of the via bottom. A round or partially rounded bottom is formed in the first metal layer to reduce mechanical stress near the diffusion barrier layer. On the other hand, a flat bottom which stops on or in the TiN ARC is selected when exposure of the first metal layer to subsequent processing steps is a primary concern. Electromigration resistance is found to be lower than for a via structure with a flat bottom formed in a first metal layer.
摘要:
An integration approach to improve electromigration resistance in a semiconductor device is described. A via hole is formed in a stack that includes an upper dielectric layer, a middle TiN ARC, and a lower first metal layer and is filled with a conformal diffusion barrier layer and a second metal layer. A key feature is that the etch process can be selected to vary the shape and location of the via bottom. A round or partially rounded bottom is formed in the first metal layer to reduce mechanical stress near the diffusion barrier layer. On the other hand, a flat bottom which stops on or in the TiN ARC is selected when exposure of the first metal layer to subsequent processing steps is a primary concern. Electromigration resistance is found to be lower than for a via structure with a flat bottom formed in a first metal layer.
摘要:
An integration approach to improve electromigration resistance in a semiconductor device is described. A via hole is formed in a stack that includes an upper dielectric layer, a middle TiN ARC, and a lower first metal layer and is filled with a conformal diffusion barrier layer and a second metal layer. A key feature is that the etch process can be selected to vary the shape and location of the via bottom. A round or partially rounded bottom is formed in the first metal layer to reduce mechanical stress near the diffusion barrier layer. On the other hand, a flat bottom which stops on or in the TiN ARC is selected when exposure of the first metal layer to subsequent processing steps is a primary concern. Electromigration resistance is found to be lower than for a via structure with a flat bottom formed in a first metal layer.
摘要:
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.
摘要:
An embodiment of the invention shows a process to form a damascene opening preferably without hardmask overhang or dielectric layer undercut/void. The low-k dielectric material can be sandwiched in two hardmask films to form the dielectric film through which an interconnect opening is etched. A first example embodiment comprises the following. We form a lower interconnect and an insulating layer over a semiconductor structure. We form a first hardmask a dielectric layer, and a second hardmask layer, over the lower interconnect and insulating layer. We etch a first interconnect opening in the first hardmask, the dielectric layer and the second hardmask layer. Lastly, we form an interconnect in the first interconnect opening.
摘要:
A method to form a barrier layer and contact plug using a touch up RIE. In a first embodiment, we form a first barrier layer over the dielectric layer and the substrate in the contact hole. The first barrier layer is comprised of Ta. A second barrier layer is formed over the first barrier layer. The second barrier layer is comprised of TaN or WN. We planarize a first conductive layer to form a first contact plug in the contact hole. We reactive ion etch ( e.g., W touch up etch) the top surfaces using a Cl and B containing etch. Because of the composition of the barrier layers and RIE etch chemistry, the barrier layers are not significantly etched selectively to the dielectric layer. In a second embodiment, a barrier film is comprised of WN.
摘要:
A new method is provided for the creation of damascene copper interconnects. A method is provided whereby created copper surfaces are capped with a layer of barrier material. With the cap structure of barrier material, the surface of the created copper interconnect is shielded against outside influences such as effects of processing chemicals. As a result of the creation of a cap of barrier material, conventional concerns of copper oxidation, copper back-sputtering and the like are eliminated.
摘要:
A method to form a barrier layer and contact plug using a touch up RIE. In a first embodiment, we form a first barrier layer over the dielectric layer and the substrate in the contact hole. The first barrier layer is comprised of Ta. A second barrier layer is formed over the first barrier layer. The second barrier layer is comprised of TaN or WN. We planarize a first conductive layer to form a first contact plug in the contact hole. We reactive ion etch (e.g., W touch up etch) the top surfaces using a Cl and B containing etch. Because of the composition of the barrier layers and RIE etch chemistry, the barrier layers are not significantly etched selectively to the dielectric layer. In a second embodiment, a barrier film is comprised of WN.