Abstract: Carborane may be used as a precursor to form low dielectric constant dielectrics. The carborane material may be modified to enable it to be deposited by chemical vapor deposition.

Abstract: An inter-layer dielectric structure and method of making such structure are disclosed. A composite dielectric layer, initially comprising a porous matrix and a porogen, is formed. Subsequent to other processing treatments, the porogen is decomposed and removed from at least a portion of the porous matrix, leaving voids defined by the porous matrix in areas previously occupied by the porogen. The resultant structure has a desirably low k value as a result of the porosity and materials comprising the porous matrix and porogen. The composite dielectric layer may be used in concert with other dielectric layers of varying porosity, dimensions, and material properties to provide varied mechanical and electrical performance profiles.

Abstract: A method of forming a microelectronic structure and its associated structures is described. In one embodiment, a substrate is provided with a sacrificial layer disposed on a hard mask layer, and a metal layer disposed in a trench of the substrate and on the sacrificial layer. The metal layer is then removed at a first removal rate wherein a dishing is induced on a top surface of the metal layer until the sacrificial layer is exposed, and simultaneously removing the metal layer and the sacrificial layer at a second removal rate without substantially removing the hard mask.

Abstract: A method of forming an air gap intermetal layer dielectric (ILD) to reduce capacitive coupling between electrical conductors in proximity. The method entails forming first and second electrical conductors over a substrate, wherein the electrical conductors are laterally spaced apart by a gap. Then, forming a gap bridging dielectric layer that extends over the first electrical conductor, the gap, and the second electrical conductor. In order to form a bridge from one electrical conductor to the other electrical conductor, the gap bridging dielectric materials should have poor gap filling characteristics. This can be attained by selecting and/or modifying a dielectric material to have a sufficiently high molecular weight and/or surface tension characteristic such that the material does not substantially sink into the gap. An example of such a material is a spin-on-polymer with a surfactant and/or other additives.

Abstract: A computer-implemented method and apparatus is provided for workflow configuration and execution in medical imaging. One method embodiment comprises the steps of creating and storing a workflow template (the workflow template comprising a standard form for entering data and activities), filling out the workflow template with data and a sequence of activities, and executing the sequence of activities according to the workflow template.

Abstract: A method for implementing a bismaleimide (BMI) polymer as a sacrificial material for an integrated circuit air gap dielectric. The method of one embodiment comprises forming a first and second metal interconnect lines on a substrate, wherein at least a portion of the first and second metal interconnect lines extend parallel to one another and wherein a trough is located between the parallel portion of said first and second metal interconnect lines. A layer of bismaleimide is spin coated over the substrate. The layer of bismaleimide is polished with a chemical mechanical polish, wherein the trough remains filled with the bismaleimide. A diffusion layer is formed over the substrate. The substrate is heated to activate a pyrolysis of the bismaleimide. An air gap is formed in the trough in the space vacated by the bismaleimide.

Abstract: The present invention relates to methods and assays for detecting bacteriophage MS2 in a sample.

Abstract: A method for modifying an interlayer dielectric (ILD) is disclosed. In one embodiment, an ILD is formed having metallization therein, which may have a protective layer. The ILD is then exposed to a first solution comprising a F− ion, either aqueous with a co-solvent or an organic-HF in conjunction with an organic solvent in supercritical carbon dioxide. After exposing the ILD to the first solution, the ILD is exposed to a second solution comprising a silane in supercritical carbon dioxide. In another embodiment, the ILD is exposed to the first solution after a damascene process including a chemical mechanical polishing is performed on the ILD. In a further embodiment, the ILD can be polymerized to create an organic polymer network after the ILD has been exposed to the second solution.

Abstract: A thermally decomposable sacrificial material is deposited in a void or opening in a dielectric layer on a semiconductor substrate. The thermally decomposable sacrificial material may be removed without damaging or removing the dielectric layer. The thermally decomposable sacrificial material may be a combination of organic and inorganic materials, such as a hydrocarbon-siloxane polymer hybrid.

Abstract: An economic supply optimization system is provided whereby an optimal machine dismantling configuration of a machine supply is determined to meet a parts demand at a lowest cost. The parts supply is calculated and it is determined what portions of the demand cannot be met from the machine supply and what portions of the demand it is not economically justifiable to meet from the machine supply. A parts supply is then determined from the machine supply. The remaining parts demand is matched to the parts supply to create a list of parts covered by the parts supply and a list of parts not covered by the parts supply, if there are any. The optimal dismantling configuration of the machine supply is calculated for the covered parts list and an optimal harvesting configuration is calculated for the not-covered parts list.

Abstract: An interlayer dielectric may be exposed to a gas cluster ion beam to densify an upper layer of the interlayer dielectric. As a result, the upper layer of the interlayer dielectric may be densified without separate deposition steps and without the need for etch stops that may adversely affect the capacitance of the overall structure.

Abstract: A thin hard mask is formed over a semiconductor substrate. The thin hard mask allows diffusion of a sacrificial material or pore-forming agent therethrough to form an underlying air gap or porous dielectric region. The thin hard mask may be a polymer or an initially porous material that may be later densified. The thin hard mask may be used to prevent etch steps used in forming an unlanded via from reaching layers below the hard mask.

Abstract: A dielectric layer is made porous by treating the dielectric material after metal interconnects are formed in or through that layer. The porosity lowers the dielectric constant of the dielectric material. The dielectric material may be subjected to an electron beam or a sonication bath to create the pores. The structure has smooth sidewalls for metal interconnects extending through the dielectric layer.

Abstract: A semiconductor structure may be covered with a thermally decomposing film. That film may then be covered by a sealing cover. Subsequently, the thermally decomposing material may be decomposed, forming a cavity.

Abstract: Carborane may be used as a precursor to form low dielectric constant dielectrics. The carborane material may be modified to enable it to be deposited by chemical vapor deposition.

Abstract: A method for implementing a bismaleimide (BMI) polymer as a sacrificial material for an integrated circuit air gap dielectric. The method of one embodiment comprises forming a first and second metal interconnect lines on a substrate, wherein at least a portion of the first and second metal interconnect lines extend parallel to one another and wherein a trough is located between the parallel portion of said first and second metal interconnect lines. A layer of bismaleimide is spin coated over the substrate. The layer of bismaleimide is polished with a chemical mechanical polish, wherein the trough remains filled with the bismaleimide. A diffusion layer is formed over the substrate. The substrate is heated to activate a pyrolysis of the bismaleimide. An air gap is formed in the trough in the space vacated by the bismaleimide.

Abstract: An inter-layer dielectric structure and method of making such structure are disclosed. A composite dielectric layer, initially comprising a porous matrix and a porogen, is formed. Subsequent to other processing treatments, the porogen is decomposed and removed from at least a portion of the porous matrix, leaving voids defined by the porous matrix in areas previously occupied by the porogen. The resultant structure has a desirably low k value as a result of the porosity and materials comprising the porous matrix and porogen. The composite dielectric layer may be used in concert with other dielectric layers of varying porosity, dimensions, and material properties to provide varied mechanical and electrical performance profiles.

Abstract: A dielectric layer is made porous by treating the dielectric material after metal interconnects are formed in or through that layer. The porosity lowers the dielectric constant of the dielectric material. The dielectric material may be subjected to an electron beam or a sonication bath to create the pores. The structure has smooth sidewalls for metal interconnects extending through the dielectric layer.

Abstract: A thermally decomposable sacrificial material is deposited in a void or opening in a dielectric layer on a semiconductor substrate. The thermally decomposable sacrificial material may be removed without damaging or removing the dielectric layer. The thermally decomposable sacrificial material may be a combination of organic and inorganic materials, such as a hydrocarbon-siloxane polymer hybrid.

Abstract: A wet etching solution may be utilized to remove insulator material between delicate structures. Surface tension effects of the wet etching solution may tend to collapse or deform delicate features. By applying sonic energy during the wet etch process and/or the removal of the wafer from a wet etching bath, the adverse effects of surface tension may be counteracted.