Abstract: A disclosed method produces an image of one or more fabricated features by iteratively producing a cross-section of the features. The method includes milling a surface proximate to the one or more fabricated features where the surface being milled is substantially parallel to a layer in which the feature is located. At each milling step, top-down imaging of the one or more fabricated features produces a plurality of cross-sectional images. Each of the plurality of cross-sectional images is reconstructed into a representation of the fabricated feature.

Abstract: A method for etching a trench to a trench depth in a dielectric layer over a substrate is provided. An ARC is applied over the dielectric layer. A photoresist mask is formed on the ARC, where the photoresist mask has a thickness. The ARC is etched through. A trench is etched into the dielectric layer with a dielectric to photoresist etch selectivity between 1:1 and 2:1.

Abstract: A method for etching a trench to a trench depth in a dielectric layer over a substrate is provided. An ARC is applied over the dielectric layer. A photoresist mask is formed on the ARC, where the photoresist mask has a thickness. The ARC is etched through. A trench is etched into the dielectric layer with a dielectric to photoresist etch selectivity between 1:1 and 2:1.

Abstract: A method for etching a trench to a trench depth in a dielectric layer over a substrate is provided. An ARC is applied over the dielectric layer. A photoresist mask is formed on the ARC, where the photoresist mask has a thickness. The ARC is etched through. A trench is etched into the dielectric layer with a dielectric to photoresist etch selectivity between 1:1 and 2:1.

Abstract: A semiconductor manufacturing process wherein an organic anti-reflective coating (ARC) is plasma etched with selectivity to an underlying dielectric layer and/or overlying photoresist. The etchant gas is fluorine-free and includes a carbon-containing gas such as CO gas, a nitrogen-containing gas such as N2, an optional oxygen-containing gas such as O2, and an optional inert carrier gas such as Ar. The etch rate of the ARC can be at least 10 times higher than that of the underlying layer. Using a combination of CO and O2 with N2 and a carrier gas such as Ar, it is possible to obtain dielectric:ARC selectivity of at least 10. The process is useful for etching contact or via openings in damascene and self-aligned contact or trench structures.

Abstract: Methods for etching a trench into a dielectric layer are provided. One exemplary method controls an ion-to-neutral flux ratio during etching so as to achieve a neutral limited regime in an ion assisted etch mechanism where the neutral limited regime causes bottom rounding. The method includes modulating physical sputtering causing microtrenching to offset the bottom rounding so as to produce a substantially flat bottom trench profile. Some notable advantages of the discussed methods of etching a trench into a dielectric layer includes the ability to eliminate the intermediate etch stop layer. Elimination of the etch stop layer will decrease fabrication cost and process time. Additionally, the elimination of the intermediate stop layer will improve device performance.

Abstract: A semiconductor manufacturing process wherein an organic anti-reflective coating (ARC) is plasma etched with selectivity to an underlying dielectric layer and/or overlying photoresist. The etchant gas is fluorine-free and includes a carbon-containing gas such as CO gas, a nitrogen-containing gas such as N2, an optional oxygen-containing gas such as O2, and an optional inert carrier gas such as Ar. The etch rate of the ARC can be at least 10 times higher than that of the underlying layer. Using a combination of CO and O2 with N2 and a carrier gas such as Ar, it is possible to obtain dielectric:ARC selectivity of at least 10. The process is useful for etching contact or via openings in damascene and self-aligned contact or trench structures.