Abstract: Methods for eliminating early exposure of a conductive layer in a dual damascene structure and for etching a dielectric barrier layer in the dual damascene structure are provided. In one embodiment, a method for etching a dielectric barrier layer disposed on a substrate includes patterning a substrate having a dielectric bulk insulating layer disposed on a dielectric barrier layer using a hardmask layer disposed on the dielectric bulk insulating layer as an etching mask, exposing a portion of the dielectric barrier layer after removing the dielectric bulk insulating layer uncovered by the dielectric bulk insulating layer, removing the hardmask layer from the substrate, and subsequently etching the dielectric barrier layer exposed by the dielectric bulk insulating layer.

Abstract: A method is provided for forming an interconnect structure for use in semiconductor devices. The method starts with forming a low-k bulk dielectric layer on a substrate and then forming a trench in the low-k bulk dielectric layer. A liner layer is formed on the low-k bulk dielectric layer being deposited conformally to the trench. A copper layer is formed on the liner layer filling the trench. Portions of the copper layer and liner layer are removed to form an upper surface of the low-k bulk dielectric layer, the liner layer, and the copper layer. A metal containing dielectric layer is formed on the upper surface of the low-k bulk dielectric layer, the liner layer, and the copper layer.

Abstract: A method for forming an air gap structure in an integrated layer stack includes dry etching a mold layer disposed on the stack in a processing system under vacuum. The mold layer is disposed between one or more interconnects, and the process of dry etching of the mold layer exposes at least a portion of the interconnects. The method also includes depositing a liner layer over the exposed portion of the interconnects. In another embodiment, a method for forming an air gap structure in an integrated layer stack includes dry etching an oxide mold layer disposed on the stack in an a first processing chamber in a processing system under vacuum. The method also includes depositing a low-k material liner layer over the interconnects, wherein the liner has a thickness of less than about 2 nanometers. The methods disclosed herein are performed in a processing system without breaking vacuum.

Abstract: Embodiments described herein generally provide methods for reducing undesired low-k damages during a damascene process using a sacrificial dielectric material and optionally a barrier/capping layer. In one embodiment, a damascene structure is formed through a sacrificial dielectric material deposited over a dielectric base layer. The damascene structure is filled with a suitable metal such as copper. The sacrificial dielectric material filled in trench areas between the copper damascene is then removed, followed by a barrier/cap layer which conformally or selectively covers exposed surfaces of the copper damascene structure. Ultra low-k dielectric materials may then fill the trench areas that were previously filled with sacrificial dielectric material. The invention prevents the ultra low-k material between the metal lines from exposing to various damaging processes during a damascene process such as etching, stripping, wet cleaning, pre-metal cleaning or CMP process.

Abstract: Embodiments of the present invention generally relate to methods for forming a metal structure and passivation layers. In one embodiment, metal columns are formed on a substrate. The metal columns are doped with manganese, aluminum, zirconium, or hafnium. A dielectric material is deposited over and between the metal columns and then cured to form a passivation layer on vertical surfaces of the metal columns.

Abstract: Embodiments described herein generally provide methods for reducing undesired low-k damages during a damascene process using a sacrificial dielectric material and optionally a barrier/capping layer. In one embodiment, a damascene structure is formed through a sacrificial dielectric material deposited over a dielectric base layer. The damascene structure is filled with a suitable metal such as copper. The sacrificial dielectric material filled in trench areas between the copper damascene is then removed, followed by a barrier/cap layer which conformally or selectively covers exposed surfaces of the copper damascene structure. Ultra low-k dielectric materials may then fill the trench areas that were previously filled with sacrificial dielectric material. The invention prevents the ultra low-k material between the metal lines from exposing to various damaging processes during a damascene process such as etching, stripping, wet cleaning, pre-metal cleaning or CMP process.

Abstract: A method and apparatus for processing a semiconductor substrate including depositing a capping layer upon a conductive material formed on the substrate, reducing oxide formation on the capping layer, and then depositing a dielectric material. A method and apparatus for processing a semiconductor substrate including depositing a capping layer upon a conductive material formed on a substrate, exposing the capping layer to a plasma, heating the substrate to more than about 100° C., and depositing a low dielectric constant material.

Abstract: A method and apparatus for forming narrow vias in a substrate is provided. A pattern recess is etched into a substrate by conventional lithography. A thin conformal layer is formed over the surface of the substrate, including the sidewalls and bottom of the pattern recess. The thickness of the conformal layer reduces the effective width of the pattern recess. The conformal layer is removed from the bottom of the pattern recess by anisotropic etching to expose the substrate beneath. The substrate is then etched using the conformal layer covering the sidewalls of the pattern recess as a mask. The conformal layer is then removed using a wet etchant.

Abstract: A method and apparatus for processing a semiconductor substrate including depositing a capping layer upon a conductive material formed on the substrate, reducing oxide formation on the capping layer, and then depositing a dielectric material. A method and apparatus for processing a semiconductor substrate including depositing a capping layer upon a conductive material formed on a substrate, exposing the capping layer to a plasma, heating the substrate to more than about 100° C., and depositing a low dielectric constant material.

Abstract: A method of forming a dual damascene structure on a substrate having a dielectric layer already formed thereon. In one embodiment the method includes depositing a first hard mask layer over the dielectric layer; depositing a second hard mask layer on the first hard mask layer; depositing a third hard mask layer on the second hard mask layer and completing formation of the dual damascene structure by etching a metal wiring pattern and a via pattern in the dielectric layer and filling the etched metal wiring pattern and via pattern with a conductive material. In one particular embodiment the second hard mask layer is an amorphous carbon layer and the third hard mask layer is a silicon-containing material.

Abstract: A damascene structure, and a method of fabricating same, containing relatively low dielectric constant materials (e.g., k less than 3.8). A silicon-based, photosensitive material, such as plasma polymerized methylsilane (PPMS), is used to form both single and dual damascene structures containing low k materials. During the manufacturing process that forms the damascene structures, the silicon-based photosensitive material is used as both a hard mask and/or an etch stop.

Abstract: A photoresist or a residue of the photoresist may by removed by the hydrogen and water plasma mixture. The process may be performed at a temperature range between about 150° C. and about 450° C., preferably about 250° C., and a power range between about 500 W and about 3000 W, preferably about 1400 W.

Abstract: A method of forming a dual damascene structure on a substrate having a dielectric layer already formed thereon. In one embodiment the method includes depositing a first hard mask layer over the dielectric layer; depositing a second hard mask layer on the first hard mask layer; depositing a third hard mask layer on the second hard mask layer and completing formation of the dual damascene structure by etching a metal wiring pattern and a via pattern in the dielectric layer and filling the etched metal wiring pattern and via pattern with a conductive material. In one particular embodiment the second hard mask layer is an amorphous carbon layer and the third hard mask layer is a silicon-containing material.

Abstract: A photoresist or a residue of the photoresist may by removed by the hydrogen and water plasma mixture. The process may be performed at a temperature range between about 150° C. and about 450° C., preferably about 250° C., and a power range between about 500 W and about 3000 W, preferably about 1400 W.

Abstract: A damascene structure, and a method of fabricating same, containing relatively low dielectric constant materials (e.g., k less than 3.8). A silicon-based, photosensitive material, such as plasma polymerized methylsilane (PPMS), is used to form both single and dual damascene structures containing low k materials. During the manufacturing process that forms the damascene structures, the silicon-based photosensitive material is used as both a hard mask and/or an etch stop.

Abstract: The present invention provides integrated circuit fabrication methods and devices wherein dual damascene structures (332 and 334) are formed in consecutive dielectric layers (314 and 316) having dissimilar etching characteristics. The present invention also provides for such methods and devices wherein these dielectric layers have different dielectric constants. Additional embodiments of the present invention include the use of single layer masks, such as silicon-based photosensitive materials which form a hard mask (622) upon exposure to radiation. In additional embodiments, manufacturing systems (710) are provided for fabricating IC structures. These systems include a controller (700) which is adapted for interacting with a plurality of fabrication stations (720, 722, 724, 726, 728 and 730).

Abstract: A damascene structure, and a method of fabricating same, containing relatively low dielectric constant materials (e.g., k less than 3.8). A silicon-based, photosensitive material, such as plasma polymerized methylsilane (PPMS), is used to form both single and dual damascene structures containing low k materials. During the manufacturing process that forms the damascene structures, the silicon-based photosensitive material is used as both a hard mask and/or an etch stop.

Abstract: The present invention provides Cu lines which are enclosed within Cu diffusion barrier layers, for IC structures such as semiconductor devices. The Cu lines (310) have conventional top (316) and bottom (318) Cu diffusion barrier layers and novel sidewall layers (324 and 326) comprising Cu diffusion barrier materials. The present invention also provides for conductive interconnect lines for semiconductor devices which compensate partly or completely for a misalignment between the line etch pattern and the underlying contact element, such as a via plug. The misalignment tolerant line (430) is formed by fabricating novel sidewalls (438 and 440) on the line wherein the sidewalls have a thickness which equals or exceeds the width of the gap (431) which is caused by the misalignment. The misalignment tolerant line compensates for the misalignment gap and thereby prevents etching a trench in the contact element.

Abstract: A damascene structure, and a method of fabricating same, containing relatively low dielectric constant materials (e.g., k less than 3.8). A silicon-based, photosensitive material, such as plasma polymerized methylsilane (PPMS), is used to form both single and dual damascene structures containing low k materials. During the manufacturing process that forms the damascene structures, the silicon-based photosensitive material is used as both a hard mask and/or an etch stop.

Abstract: The invention generally provides an improved process for providing uniform step coverage on a substrate and planarization of metal layers to form continuous, void-free interconnections in high aspect ratio, sub-half micron applications. The invention provides a multi-step PVD process in which the plasma power is varied for each of the steps to obtain favorable fill characteristics as well as good reflectivity, morphology and throughput. The initial plasma powers are relatively low to ensure good, void-free filling of the aperture and, then, the plasma powers are increased to obtain the desired reflectivity and morphology characteristics. The invention provides an aperture filling process comprising physical vapor depositing a metal over the substrate and varying the plasma power during the physical vapor deposition. Preferably, the plasma power is varied from a first discrete low plasma power to a second discrete high plasma power.