Abstract: A method for forming a single damascene and/or dual damascene, contact and interconnect structure, comprising: performing front end processing, depositing copper including a copper barrier, annealing the copper in at least 90% N2 with less than 10% H2, performing planarization, performing in-situ low-H NH3 plasma treatment and low Si—H SiN etch stop layer deposition, and performing remaining back end processing.

Abstract: A method for forming a single damascene and/or dual damascene, contact and interconnect structure, comprising: performing front end processing, depositing copper including a copper barrier, annealing the copper in at least 90% N2 with less than 10% H2, performing planarization, performing in-situ low-H NH3 plasma treatment and low Si—H SiN etch stop layer deposition, and performing remaining back end processing.

Abstract: A technique for use in fabricating an integrated circuit are disclosed. The method generally begins by performing an operation on a wafer using a fabrication tool. Next, volatiles are desorbed from the wafer. The desorbed volatiles are sampled and raw spectral data indicating the content of the desorbed volatiles is generated. The raw spectral data is subjected to a spectroscopic analysis. An operational parameter of the fabrication tool is then modified responsive to the result of the results of the spectroscopic analysis. In one particular aspect of the invention, a controller receives the raw spectral data and processes the raw spectral data to determine the presence of a residual material on the wafer. The controller then controls the process flow operation to reduce the amount of the residual material on the wafer responsive to the results of processing the raw spectral data. Other aspects of the invention include the apparatus implementing the process flow and the controller itself.

Abstract: In another aspect of the present invention, a system for detecting an endpoint in a polishing process is provided. The system comprises a polishing tool, a controllable light source, a sensor, and a controller. The polishing tool is capable of polishing a surface of a semiconductor device, wherein the semiconductor device includes a first layer comprised of a first material and a second layer comprised of a second material. The first layer is positioned above the second layer. The controllable light source is capable of delivering light having one of a plurality of a preselected frequencies to the surface of the semiconductor device. The sensor is capable of detecting the light reflected from the surface of the semiconductor device.

Abstract: The present invention is generally directed to various methods of controlling copper barrier/seed deposition processes, and a system for accomplishing same. In one illustrative embodiment, the method comprises performing at least one process operation to form a barrier metal layer and a copper seed layer above a wafer, sensing at least one parameter of at least one process operation and determining an acceptability metric for the barrier metal layer and the copper seed layer based upon the sensed at least one parameter. In some embodiments, the method further comprises modifying at least one parameter of said at least one process operation to be performed to form a barrier metal layer and a copper seed layer on a subsequently processed wafer based upon said determined acceptability metric. In some embodiments, the method further comprises identifying a wafer as unacceptable if said acceptability metric falls below a preselected level.

Abstract: The present invention is generally directed to a transistor having a gate stack comprised of a metal, and a method of making same. In one illustrative embodiment, the transistor is comprised of a gate stack comprised of a gate insulation layer positioned above a semiconducting substrate, a layer of silicon positioned above the gate insulation layer, a layer of adhesion material positioned above the layer of silicon, a layer of metal positioned above the layer of adhesion material, and a plurality of source/drain regions formed in the substrate adjacent the gate stack.

Abstract: A method for forming a conductive interconnect comprises forming a process layer over a structure layer and forming a mask over the process layer, the mask having an etch profile therein. An anisotropic etching process is performed to erode the mask and to form an etched region in the process layer, the etched region having a profile correlating to the etch profile. A conductive material is formed in the etched region in the process layer and any excess conductive material is removed from above an upper surface of the process layer.

Abstract: A test structure useful in controlling a polishing process of a semiconductor device is provided. The test structure is comprised of a structure layer, a first process layer, and interconnects. The first process layer is positioned above the structure layer and has a plurality of openings formed therein and extending at least partially therethrough to a preselected depth. At least a portion of the plurality of openings have a tapered region progressively narrowing in a direction from the first process layer toward the structure layer. The openings are spaced a preselected distance X apart. The interconnects are formed in the plurality of openings including the tapered region. Thus, as the process layer and interconnects are removed by the polishing process, the distance X increases, indicating the depth of the polishing process.

Abstract: A method for forming a semiconductor having improved copper interconnects is provided. The method comprises forming a first dielectric layer above a first structure layer. Thereafter, a first opening is formed in the first dielectric layer, and a first copper layer is formed above the first dielectric layer and in the first opening. A portion of the first copper layer outside of the opening is removed. A surface portion of the first copper layer is also removed from within the opening, and a second layer of copper is formed above the first layer of copper, replacing the removed surface portion.

Abstract: A method of forming conductive contacts or an integrated circuit device is disclosed herein. In one embodiment, the method comprises forming a transistor above a semiconducting substrate, and forming a first layer comprised of an orthosilicate glass material above the transistor and the substrate. The method further comprises forming a second layer comprised of an insulating material above the first layer, and performing at least one etching process to define an opening in the second layer for a conductive contact to be formed therein, wherein the first layer comprised of an orthosilicate glass material acts as an etch stop layer during the etching of the opening in the second layer.

Abstract: Methods of removing gaseous phase contaminants from a processing chamber, such as a PVD chamber, are provided. In one aspect, a method of removing gaseous phase water from a processing chamber is provided that includes placing a heated substrate that has a titanium film in the processing chamber to dissociate a first portion of the gaseous phase water into hydrogen and oxygen and capture some of the oxygen in, the titanium film. The dissociated hydrogen and uncaptured oxygen are pumped from the processing chamber and the substrate is removed from the processing chamber. Pump down times and test wafer consumption may be reduced.

Abstract: A dielectric material is provided having air gaps purposely formed within the dielectric. The dielectric is deposited, and air gaps formed, between respective interconnect lines. The geometries between interconnect lines is purposely controlled to achieve a large aspect ratio necessary to produce air gaps during CVD of the dielectric. Air gaps exist between interconnects to reduce the line-to-line capacitance, and thereby reduce the propagation delay associated with closely spaced interconnects.

Abstract: An isolation technique is provided for improving the overall planarity of isolation regions relative to adjacent active area silicon mesas. The isolation process results in a trench formed in field regions immediately adjacent the active regions. The trench, however, does not extend entirely across the field region. By preventing large area trenches, substantial dielectric fill material and the problems of subsequent planarization of that fill material is avoided. Accordingly, the present isolation technique does not require conventional fill dielectric normally associated with a shallow trench process. While it achieves the advantages of forming silicon mesas, the present process avoids having to rework dielectric surfaces in large area field regions using conventional sacrificial etchback, block masking and chemical-mechanical polishing. The improved isolation technique hereof utilizes trenches of minimal width etched into the silicon substrate at the periphery of field regions, leaving a field mesa.

Abstract: A method for forming a multilevel interconnect structure having a globally planarized upper surface. Dielectrics are deposited upon a semiconductor to minimize pre-existing disparities in topographical height and to create an upper surface topography having a polish rate greater than that of lower regions. Subsequent chemical mechanical polishing produces a substantially planar surface.

Abstract: An isolation technique is provided for improving the overall planarity of isolation regions relative to adjacent active area silicon mesas. The isolation process results in a trench formed in field regions immediately adjacent the active regions. The trench, however, does not extend entirely across the field region. By preventing large area trenches, substantial dielectric fill material and the problems of subsequent planarization of that fill material is avoided. Accordingly, the present isolation technique does not require conventional fill dielectric normally associated with a shallow trench process. While it achieves the advantages of forming silicon mesas, the present process avoids having to rework dielectric surfaces in large area field regions using conventional sacrificial etchback, block masking and chemical-mechanical polishing. The improved isolation technique hereof utilizes trenches of minimal width etched into the silicon substrate at the periphery of field regions, leaving a field mesa.

Abstract: A process for forming a silicide layer using a metal layer formed by collimated deposition is provided. The collimated metal layer may, for example, be formed by sputtering metal particles and filtering the metal particles prior to forming the metal layer. By depositing metal in this manner, the resistance of the resultant metal silicide layer can be reduced as compared to metal silicide layers formed using conventional techniques. Lower silicidation reaction temperatures may also be employed.

Abstract: Methods of fabricating ohmic contacts and adhesion layers therefore are provided. In one aspect, a method of fabricating an ohmic contact in an opening of an insulating layer is provided. Tetra-dimethyl-amino-titanium vapor is decomposed in the presence of the opening to deposit TiCN in the opening at a rate of about 9.4 to 10.6 Å/second and a thickness of less than about 105 Å. The deposited TiCN is exposed to a plasma ambient containing nitrogen and hydrogen to remove carbon and oxygen from the deposited TiCN. A conducting material is deposited on the TiCN. Controlled TiCN thickness, and subsequent plasma treatment dissociate most of the carbon and oxygen incorporated into the TiCN layer during deposition. The potential for undesirably high contact resistance due to oxygen and carbon-based insulating structures within the adhesion layer is reduced.

Abstract: A reduced permittivity interlevel dielectric in a semiconductor device arranged between two levels of interconnect. The dielectric comprises a first dielectric layer preferably from a silane source deposited on a first level interconnect to form air gaps at midpoints between adjacent first interconnect structures, a second dielectric containing air gap trenches at spaced intervals across the second dielectric, and a third dielectric formed upon said second dielectric. A second interconnect level is formed on the third dielectric.

Abstract: It has been observed that Si introduced into an Al metal line of an Al, Ti, and Si-containing layer stack of an integrated circuit, at concentrations uniformly less than the solid solubility of Si in Al, results in a reduction in Al metal line voiding. Such voiding is a stress induced phenomenon and the introduction of Si appears to reduce stresses in the Al metal lines. By controlling Ti deposition conditions to achieve desired thickness and grain-size characteristics of the Ti underlayer, a self-regulating filter for introduction of Si into the Al metal layer is provided. Si is introduced into the Al metal layer by migration through a suitably deposited Ti layer, rather than during Al layer deposition.

Abstract: A method of making a semiconductor device to reduce or prevent defects caused by the ejection of deposited material. The method includes a first layer of material deposited over a substrate in the presence of a gaseous ambient. A portion of the gaseous ambient is trapped by the first layer. This entrapped portion could cause defects during subsequent elevated temperature processing as the gas attempts to escape from the first layer. To prevent or reduce this problem, after depositing the first layer and before depositing a second layer over the first layer, the first layer is heated to remove at least a portion of the gaseous ambient trapped in the layer. For best results, the first layer is heated to a temperature at least as high as the highest temperature of later processing steps and at a pressure of no more than 1 torr. This method is particularly useful for layers formed by physical vapor deposition.