Abstract: A method of forming structures in semiconductor devices through a buffer or insulator layer comprising the use of a silicon hard mask between a patterned resist layer for etching the structures and an underlying barrier layer. The silicon hard mask acts as a backup to the resist layer, preventing the potential etching of the barrier layer which is protected by the resist layer by acting as an etch stop if the first resist layer is ablated away during the etching of the openings for the structures. This allows for a thinner layer of resist material to be used. After etching, a layer of silicidable material is deposited over the silicon hard mask and the resulting structure is annealed to turn the silicon hard mask into a silicide material. The silicide material is removed by an abrasive method, such as by chemical mechanical planarization.

Abstract: Disclosed is a method for manufacturing an interconnect structure situated on a semiconductor wafer having a substrate assembly thereon. The interconnect structure is formed in a recess such as a trench, a hole, a via, or a combination of a trench and a hole or via within a dielectric material situated on the substrate assembly of the semiconductor wafer. At least one barrier layer is deposited within the recess. A seed layer helping to promote nucleation, deposition, and growth of a material that will be used to fill up the recess is then deposited on the barrier layer. An electrically conductive layer is then formed upon the seed layer. An energy absorbing layer will then be formed upon the conductor layer, where the energy absorbing layer has a greater thermal absorption capacity than that of the electrically conductive layer.

Abstract: A void is defined between adjacent wiring lines to minimize RC coupling. The void has a low dielectric value approaching 1.0. For one approach, hollow silicon spheres define the void. The spheres are fabricated to a known inner diameter, wall thickness and outer diameter. The spheres are rigid enough to withstand the mechanical processes occurring during semiconductor fabrication. The spheres withstand elevated temperatures up to a prescribed temperature range. At or above a desired temperature, the sphere walls disintegrate leaving the void in place. For an alternative approach, adjacent wiring lines are “T-topped” (i.e., viewed cross-sectionally). Dielectric fill is deposited in the spacing between lines. As the dielectric material accumulates on the line and substrate walls, the T-tops grow toward each other. Eventually, the T-tops meet sealing off an internal void.

Abstract: Semiconductor processing methods of forming integrated circuitry, and in particular, methods of forming such circuitry utilizing dual damascene technology, and resultant integrated circuitry constructions are described. In one embodiment, a substrate is provided having a circuit device. At least three layers are formed over the substrate and through which electrical connection is to be made with the circuit device. The three layers comprise first and second layers having an etch stop layer interposed therebetween. A contact opening is formed through the three layers and a patterned masking layer is formed over the three layers to define a conductive line pattern. Material of an uppermost of the first and second layers is selectively removed relative to the etch stop layer and defines a trough joined with the contact opening. Conductive material is subsequently formed within the trough and contact opening.

Abstract: A thermal processing method is described which improves integrated circuit metal polishing and increases conductivity following polish. A method of fabricating a metal layer in an integrated circuit is described which comprises the steps of depositing a layer of metal alloy which contains alloy dopant precipitates, and performing a first anneal of the integrated circuit to drive the alloy dopants into solid solution. The metal is quenched to prevent the alloy dopants from coming out of solution prior to removing excess metal alloy with a polish process. To improve conductivity after polishing, the dopants are allowed to come out of solution. The metal alloy is described as aluminum with alloy dopants of silicon and copper where the first anneal is performed at 400 to 500° C. This process is particularly applicable to fabrication of interconnects formed using a dual damascene process. The integrated circuit is described as any circuit, but can be a memory device such as a DRAM.

Abstract: Disclosed is a novel method for forming an interconnect structure to provide electrical communication to an isolated junction on a semiconductor substrate assembly. Under the method, an interconnect structure opening extending through an insulating layer to an exposed surface of a junction is provided and a cobalt layer is deposited in the bottom of the interconnect structure opening. The semiconductor wafer is then annealed to form a cobalt silicide diffusion barrier layer. A titanium layer may be deposited and used as a diffusion membrane prior to the formation of the cobalt silicide diffusion barrier layer. The titanium layer also removes native oxide from the bottom of the interconnect structure opening and is stripped off after cobalt silicide formation.

Abstract: A thermal processing method is described which improves integrated circuit metal polishing and increases conductivity following polish. A method of fabricating a metal layer in an integrated circuit is described which comprises the steps of depositing a layer of metal alloy which contains alloy dopant precipitates, and performing a first anneal of the integrated circuit to drive the alloy dopants into solid solution. The metal is quenched to prevent the alloy dopants from coming out of solution prior to removing excess metal alloy with a polish process. To improve conductivity after polishing, the dopants are allowed to come out of solution. The metal alloy is described as aluminum with alloy dopants of silicon and copper where the first anneal is performed at 400 to 500° C. This process is particularly applicable to fabrication of interconnects formed using a dual damascene process. The integrated circuit is described as any circuit, but can be a memory device such as a DRAM.

Abstract: Disclosed is a method for manufacturing an interconnect structure situated on a semiconductor wafer having a substrate assembly thereon. The interconnect structure is formed in a recess such as a trench, a hole, a via, or a combination of a trench and a hole or via within a dielectric material situated on the substrate assembly of the semiconductor wafer. At least one barrier layer is deposited within the recess. A seed layer helping to promote nucleation, deposition, and growth of a material that will be used to fill up the recess is then deposited on the barrier layer. An electrically conductive layer is then formed upon the seed layer. An energy absorbing layer will then be formed upon the conductor layer, where the energy absorbing layer has a greater thermal absorption capacity than that of the electrically conductive layer.

Abstract: Disclosed is a method for manufacturing an interconnect structure situated on a semiconductor wafer having a substrate assembly thereon. The interconnect structure is formed in a recess such as a trench, a hole, a via, or a combination of a trench and a hole or via within a dielectric material situated on the substrate assembly of the semiconductor wafer. At least one barrier layer is deposited within the recess. A seed layer helping to promote nucleation, deposition, and growth of a material that will be used to fill up the recess is then deposited on the barrier layer. An electrically conductive layer is then formed upon the seed layer. An energy absorbing layer will then be formed upon the conductor layer, where the energy absorbing layer has a greater thermal absorption capacity than that of the electrically conductive layer.

Abstract: In one aspect, the invention includes a processing method, comprising: a) providing a substrate having a high aspect ratio opening therein; b) forming a metal-comprising layer over the opening; c) providing a first pressure against the metal-comprising layer; and d) ramping the pressure that is against the metal-comprising layer to a second pressure at a rate of from about 1 atmosphere per second about 100 atmospheres per second.

Abstract: A contact interface having a substantially annular silicide ring along sides of a depression formed in an active surface of the semiconductor substrate, wherein the depression is formed by an etching process to form a contact opening through a dielectric layer. The contact interface is formed by depositing a layer of conductive material, such as titanium, with a high bias power IMP deposition. The conductive material is turned to a silicide by an annealing process, thereby forming the contact interface.

Abstract: Semiconductor processing methods of forming integrated circuitry, and in particular, methods of forming such circuitry utilizing dual damascene technology, and resultant integrated circuitry constructions are described. In one embodiment, a substrate is provided having a circuit device. At least three layers are formed over the substrate and through which electrical connection is to be made with the circuit device. The three layers comprise first and second layers having an etch stop layer interposed therebetween. A contact opening is formed through the three layers and a patterned masking layer is formed over the three layers to define a conductive line pattern. Material of an uppermost of the first and second layers is selectively removed relative to the etch stop layer and defines a trough joined with the contact opening. Conductive material is subsequently formed within the trough and contact opening.

Abstract: A contact interface having a substantially annular silicide ring along sides of a depression formed in an active surface of the semiconductor substrate, wherein the depression is formed by an etching process to form a contact opening through a dielectric layer. The contact interface is formed by depositing a layer of conductive material, such as titanium, with a high bias power IMP deposition. The conductive material is turned to a silicide by an annealing process, thereby forming the contact interface.

Abstract: A thermal processing method is described which improves integrated circuit metal polishing and increases conductivity following polish. A method of fabricating a metal layer in an integrated circuit is described which comprises the steps of depositing a layer of metal alloy which contains alloy dopant precipitates, and performing a first anneal of the integrated circuit to drive the alloy dopants into solid solution. The metal is quenched to prevent the alloy dopants from coming out of solution prior to removing excess metal alloy with a polish process. To improve conductivity after polishing, the dopants are allowed to come out of solution. The metal alloy is described as aluminum with alloy dopants of silicon and copper where the first anneal is performed at 400 to 500° C. This process is particularly applicable to fabrication of interconnects formed using a dual damascene process. The integrated circuit is described as any circuit, but can be a memory device such as a DRAM.

Abstract: A void is defined between adjacent wiring lines to minimize RC coupling. The void has a low dielectric value approaching 1.0. For one approach, hollow silicon define the void. The spheres are fabricated to a known inner diameter, wall thickness and outer diameter. The spheres are ridgid enough to withstand the mechanical processes occurring during semiconductor fabrication. The spheres withstand elevated temperature up to a prescribed temperature range. At or above a desired temperature, the sphere walls disintegrate leaving the void in place. For an alternative approach, adjacent wiring lines are “T-topped” (i.e., viewed cross-sectionally). Dielectric fill deposited in the spacing between lines. As the dielectric material accumulates on the line and substrate walls, the T-tops grow toward each other. Eventually, the T-tops meet sealing off and internal void.

Abstract: An integrated circuit alloy is described which reduces the alloy melting temperature for improved coverage of high aspect ratio features with a reduced deposition pressure. The alloy is used to fabricate metal contacts and interconnects in integrated circuits, such as memory devices. The contacts and interconnects can be high aspect ratio features formed using a dual damascene process. An aluminum interconnect alloy is described for use in an integrated circuit which includes Al, Cu, Si. Ge and Mg can also be provided in the alloy. The composition of Si+Ge+Mg provides a melting temperature of the aluminum interconnect alloy which is between 500 and 550° C.

Abstract: In one aspect, the invention includes a processing method, comprising: a) providing a substrate having a high aspect ratio opening therein; b) forming a metal-comprising layer over the opening; c) providing a first pressure against the metal-comprising layer; and d) ramping the pressure that is against the metal-comprising layer to a second pressure at a rate of from about 1 atmosphere per second about 100 atmospheres per second.

Abstract: A method and substrate structure for fabricating highly conductive components on microelectronic devices. In one embodiment in accordance with the principles of the present invention, a first dielectric layer is formed over a base layer of a substrate, a second dielectric layer is deposited onto the first dielectric layer, and a third dielectric layer is deposited onto the second dielectric layer. The first, second and third dielectric layers define a dielectric stratum in which the first and second dielectric layers may be selectively etchable from one another so that the second dielectric layer etches at a faster rate than the first layer in the presence of a selective etchant. After the dielectric layers are deposited onto the substrate, a void is etched through the second and third dielectric layers.

Abstract: Disclosed is a method of forming a PVD deposition chamber which is modified with an electrical circuit that allows a voltage bias to be applied to any one or more of a target, an in-process integrated circuit wafer, and collimator. The collimator can also be isolated from the electrical circuit. This configuration allows a preclean of the in-process integrated circuit wafer in situ in the PVD deposition chamber by ion sputtering and a subsequent sputter deposition through the collimator. A method is also disclosed wherein an in-process integrated circuit wafer is first precleaned in the PVD deposition chamber by applying a negative voltage bias to the in-process integrated circuit wafer. A film of conducting material is then sputter deposited on the surface of the in-process integrated circuit wafer by applying a negative voltage bias to the target. The collimator is electrically isolated during this process or is set at a higher potential than the in-process integrated circuit wafer.

Abstract: The present invention relates to high aspect-ratio electrical connections, wiring trenches, and methods of forming the same in semiconductor devices. In particular, the present invention relates to formation of contacts with refractory metal and/or refractory metal nitride liners that assist in filling of the contacts. Additionally disclosed is the combination of shallow junction fabrication and high aspect-ratio contact formation to form contacts between a shallow junction and microcircuitry wiring. More particularly, the present invention relates to aluminum filled contacts that fill contact corridors, trenches, or vias in semiconductor devices that are initially lined with a titanium layer and at least one other layer. Preferred other layers include CVD, PVD, or reacted TiN, Co, Ge, and Si.