Abstract: Metal filling processes for semiconductor devices and methods of fabricating semiconductor devices. One method includes, for instance: obtaining a wafer with at least one contact opening; depositing a metal alloy into at least a portion of the at least one contact opening; separating the metal alloy into a first metal layer and a second metal layer; depositing a barrier stack over the wafer; forming at least one trench opening; forming at least one via opening; and depositing at least one metal material into the trench openings and via openings. An intermediate semiconductor device is also disclosed.

Abstract: Integrated circuits and methods for fabricating integrated circuits are provided. In one example, a method for fabricating an integrated circuit includes depositing an organic dielectric material overlying a semiconductor substrate for forming an organic interlayer dielectric (OILD) layer. An opening is formed in the OILD layer and a conductive metal fill is deposited in the opening for forming a metal line and/or a via.

Abstract: Methods are provided for fabricating an interlayer structure useful in, for instance, providing BEOL interconnect for circuit structures. The method includes, for instance, providing an interlayer structure, including: providing an uncured insulating layer above a substrate structure; forming an energy removal film over the uncured insulated layer; forming at least one opening through the energy removal film and extending at least partially into the uncured insulating layer; and applying energy to cure the uncured insulating layer, establishing a cured insulating layer, and decomposing in part the energy removal film, establishing a reduced thickness, energy removal film over the cured insulating layer, the interlayer structure including the cured insulating layer, and the applying energy decreasing an aspect ratio(s) of the one opening(s). In one implementation, the uncured insulating layer includes porogens which also decompose partially during applying energy to further improve the aspect ratio(s).

Abstract: Methods are provided for fabricating an interlayer structure useful in, for instance, providing BEOL interconnect for circuit structures. The method includes, for instance, providing an interlayer structure, including: providing an uncured insulating layer above a substrate structure; forming an energy removal film over the uncured insulated layer; forming at least one opening through the energy removal film and extending at least partially into the uncured insulating layer; and applying energy to cure the uncured insulating layer, establishing a cured insulating layer, and decomposing in part the energy removal film, establishing a reduced thickness, energy removal film over the cured insulating layer, the interlayer structure including the cured insulating layer, and the applying energy decreasing an aspect ratio(s) of the one opening(s). In one implementation, the uncured insulating layer includes porogens which also decompose partially during applying energy to further improve the aspect ratio(s).

Abstract: A method of forming a device is disclosed. The method includes providing a substrate prepared with a dielectric layer having first and second regions. The first region comprises wide features and the second region comprises narrow features. A depth delta exists between bottoms of the wide and narrow features. A non-conformal layer is formed on the substrate and it lines the wide and narrow trenches in the first and second regions. The non-conformal layer is removed. Removing the non-conformal layer reduces the depth delta between the bottoms of the wide and narrow features in the first and second region.

Abstract: A method of manufacturing an integrated circuit system includes: providing a etch stop layer; forming a layer stack over the etch stop layer with the layer stack having an anti-reflective coating layer over a low temperature oxide layer; forming a photoresist layer over the anti-reflective coating layer; forming a first resist line and a second resist line from the photoresist layer with the first resist line and the second resist line separated by a through line pitch on the anti-reflective coating layer; etching the anti-reflective coating layer using a low-pressure polymer burst with a non-oxidizing gas mixture to remove a portion of the anti-reflective coating layer; and forming a first polymer layer over the first resist line.

Abstract: A method of manufacturing an integrated circuit system includes: providing a etch stop layer; forming a layer stack over the etch stop layer with the layer stack having an anti-reflective coating layer over a low temperature oxide layer; forming a photoresist layer over the anti-reflective coating layer; forming a first resist line and a second resist line from the photoresist layer with the first resist line and the second resist line separated by a through line pitch on the anti-reflective coating layer; etching the anti-reflective coating layer using a low-pressure polymer burst with a non-oxidizing gas mixture to remove a portion of the anti-reflective coating layer; and forming a first polymer layer over the first resist line.

Abstract: A method of forming a device is disclosed. The method includes providing a substrate prepared with a dielectric layer having first and second regions. The first region comprises wide features and the second region comprises narrow features. A depth delta exists between bottoms of the wide and narrow features. A non-conformal layer is formed on the substrate and it lines the wide and narrow trenches in the first and second regions. The non-conformal layer is removed. Removing the non-conformal layer reduces the depth delta between the bottoms of the wide and narrow features in the first and second region.

Abstract: A method for semiconductor fabrication includes etching a via and a trench in a dielectric material to yield an etched surface. The dielectric material may have an ultra-low K value (e.g., a K-value of less than or equal to 2.4). The etched surface is then processed with a gas-phase silylation process to yield a silylated surface. The silylated surface is processed with a plasma treatment process to yield a plasma treated surface. The plasma treated surface, in turn, is processed with a dilute hydrofluoric acid before a conductive metal is deposited in the via and the trench. Inclusion of the plasma treatment process reduces hollow metal defects caused by the silylation process and increases reliability of metal interconnects and improves barrier metallization.

Abstract: A method for semiconductor fabrication using a trench first metal hard mask (TFMHM) process for damascene structures includes forming a secondary metal hard mask layer above a first metal hard mask layer after trench opening for the via (and trench) etching. The secondary metal hard mask layer is formed of metal material substantially resistant to the etching process which enables via etching to self-align (using an edge of the secondary metal mask layer). In one embodiment, the secondary metal mask layer is formed using an electroless deposition process, and may include nickel (Ni), cobalt (Co), gold, (Au), palladium (Pd), cadmium (Cd) silver (Ag), ruthenium (Ru), and alloys and/or combinations thereof. Because the first metal hard mask is usually formed of TiN, the trench and via etching process removes a significant amount of the TiN layer. Utilization of the secondary metal hard mask to protect the first metal hard mask layer further enables a reduction in the thickness of the first metal hard mask layer.

Abstract: Methods of forming integrated circuit devices include forming an integrated circuit substrate having an electrically insulating layer thereon and forming a mask layer pattern having at least first and second openings of different size therein, on the electrically insulating layer. First and second portions of the electrically insulating layer extending opposite the first and second openings, respectively, are simultaneously etched at first and second different etch rates. This etching yields a first trench extending adjacent the first opening that is deeper than a second trench extending adjacent the second opening. Then, the bottoms of the first and second trenches are simultaneously etched to substantially the same depths using an etching process that compensates for the first and second different etch rates.

Abstract: A method of minimizing undercut of a hard mask in an integrated circuit (IC) structure including steps of providing an IC structure having a substrate, a interlayer dielectric layer, and a hard mask, forming a via in said IC structure, and depositing an organic planarizing layer (OPL) over the IC structure such that it fills the vias formed therein. The method also includes steps of forming a masking structure layer over the OPL, forming an opening in the masking structure that has a critical dimension (CD) smaller than an opening design dimension, anisotropic etching the OPL such that sidewall of the via remains covered with the OPL while forming a trench, and removing any remaining OPL on the sidewalls and trench, wherein the undercut of the sidewalls with respect to the hard mask is minimized by the covering of OPL during the anisotropic etching process.

Abstract: Methods of forming integrated circuit devices include forming an integrated circuit substrate having an electrically insulating layer thereon and forming a mask layer pattern having at least first and second openings of different size therein, on the electrically insulating layer. First and second portions of the electrically insulating layer extending opposite the first and second openings, respectively, are simultaneously etched at first and second different etch rates. This etching yields a first trench extending adjacent the first opening that is deeper than a second trench extending adjacent the second opening. Then, the bottoms of the first and second trenches are simultaneously etched to substantially the same depths using an etching process that compensates for the first and second different etch rates.

Abstract: The invention is an entirely new application of domain characterization generated by Voronoi tessellation, which is very close to realistic geology and computation of gravity response of such domain, which has three dimensional fractal basin structure, and is favorable for oil exploration. In this work the interfaces or tessellating domains are represented by a set of parameters, which are referred as Voronoi centers. These parameters can be perturbed by any amount without getting into representational problems as faced by the conventional techniques. To accomplish such representation Voronoi tessellation is used, which in two dimensional space consists of enclosing every Voronoi center by a Voronoi polygon such that the common edge of adjacent polygons is perpendicular bisector to the line joining the Voronoi centers on both the sides of that edge.