Abstract: A method for mitigating line-edge roughness on a semiconductor device. The method includes line-edge roughness mitigation techniques in accordance with embodiments of the present invention. The techniques include: reducing the SiON film thickness below a conventional thickness; increasing the photoresist thickness above a conventional thickness; etching the SiON film with an etch bias power less than a conventional wattage amount with an overetch percentage less than a conventional overetch percentage; removing the SiON film layer immediately after completion of the amorphous carbon film layer etching; and lowering the lower electrode temperature below a conventional temperature.

Abstract: A method for mitigating line-edge roughness on a semiconductor device. The method includes line-edge roughness mitigation techniques in accordance with embodiments of the present invention.

Abstract: A method for mitigating line-edge roughness on a semiconductor device. The method includes line-edge roughness mitigation techniques in accordance with embodiments of the present invention. The techniques include: reducing the SiON film thickness below a conventional thickness; increasing the photoresist thickness above a conventional thickness; etching the SiON film with an etch bias power less than a conventional wattage amount with an overetch percentage less than a conventional overetch percentage; removing the SiON film layer immediately after completion of the amorphous carbon film layer etching; and lowering the lower electrode temperature below a conventional temperature.

Abstract: A method for mitigating line-edge roughness on a semiconductor device. The method includes line-edge roughness mitigation techniques in accordance with embodiments of the present invention.

Abstract: The present invention discloses a system and method for designing grating structures for use in situ scatterometry during the photolithography process to detect a photoresist defect (e.g., photoresist erosion, pattern collapse or pattern bending). In one embodiment, a grating structure may be designed with a pitch or critical dimensional smaller than the one used for the semiconductor device. The pitch and the critical dimension of the grating structure may be varied. In another embodiment, the present invention provides for a feedback mechanism between the in situ scatterometry process and the photolithography process to provide an early warning of the existence of a photoresist defect. If a defect is detected on the wafer, the wafer may be sent to be re-worked or re-patterned, thereby avoiding scrapping the entire wafer.

Abstract: Systems and methods are disclosed for testing semiconductors at the wafer level, specifically, systems and methods are disclosed that quantify line-edge roughness in terms of electrical properties and the impact of the line-edge roughness on device reliability and performance. A voltage ramp dielectric breakdown (VRDB) test is used to measure the breakdown voltage of the inter-digitated fingers of a semiconductor device. The distribution of breakdown voltage is used to measure the median breakdown voltage and the outliers which fan the extrinsic tail. Thereby, VRDB is used to quantify the impact LER will have on device reliability and performance. The systems and methods also provide a feedback tool to the fabrication process to control line edge roughness to a desired specification.

Abstract: The disclosure provides methods to mitigate and/or eliminate problems associated with removal of carbon-based resists from organic low k dielectrics. The methods include forming an organic low k dielectric layer over a semiconductor substrate, forming a capping layer over the organic low k dielectric layer, forming a silicon-containing resist over the capping layer, patterning the silicon-containing resist layer to expose portions of the capping layer and to form a patterned silicon oxide layer, removing the organic low k dielectric layer to form one or more openings, and removing the patterned silicon oxide layer. The silicon-containing resist facilitates efficient patterning of the organic low k-dielectric layers, and thereby increases the performance and cost-effectiveness of semiconductor devices fabricated using organic low k dielectrics.

Abstract: Methods for eliminating and/or mitigating bridging and/or leakage caused by the contamination of a dielectric layer with fragments and/or residues of a conductive material are disclosed. The methods involve exposing a semiconductor substrate with a dielectric layer contaminated with fragments and/or residues of conductive materials to one or more conductor and/or dielectric etches. The disclosure by eliminating and/or mitigating metal bridging and/or leakage can provide one or more of the following advantages: high device reliability, decreased manufacturing cost, more efficient metallization, and increased performance.

Abstract: In one embodiment, the present invention relates to a method for increasing the ignition reliability of a plasma in a plasma reactor, the method comprising: supplying a source gas to the plasma reactor, the source gas comprising: (a) at least one reactive compound; and (b) at least one ignition gas, wherein the at least one ignition gas increases the ignitability of the source gas as compared to the ignitability of the source gas lacking the at least one ignition gas.

Abstract: Systems and methods are described that facilitate verifying that bottom apertures in tapered vias are open and free of obstruction. Scatterometry can be employed to monitor tapered via formation during and/or after a dry etch process on a photoresist bilayer. Information regarding critical dimensions at the bottoms of tapered vias can be analyzed to assess whether bottom apertures exhibit a minimum acceptable diameter that is equal to or greater than a predetermined threshold tolerance. Via apertures with dimensions below the threshold tolerance and/or regions of a wafer evincing unacceptable frequent occurrences of faulty via apertures are considered occluded, or suspect, and a corrective re-etch can be performed thereon.

Abstract: Methods of making a semiconductor structure are disclosed. A refractory metal layer containing W, TiW, Ta, or TaN and semiconductor layer are formed on a substrate that contains copper in, for example, a via therein. A portion of the refractory metal layer and semiconductor layer is removed by etching using a fluorine-containing compound. By using W, TiW, Ta, or TaN as the refractory metal layer material and employing fluorine-based etching, the copper portion in the substrate is not substantially etched, thus preventing corrosion of the copper portion.

Abstract: A method of forming an interlevel dielectric (ILD) layer forms a polymer sacrificial ILD on a substrate. After metallization structures are formed in the polymer sacrificial ILD layer, a low power etch back is performed on the sacrificial ILD layer. Dielectric material is non-conformally deposited as an ILD layer over the substrate and the metallization structures, forming air gaps between some of the metallization structures.

Abstract: The present invention uses in situ scatterometry to determine if a defect (e.g., photoresist erosion, photoresist bending and pattern collapse) is present on a wafer. In one embodiment, in situ scatterometry is used to detect a pattern integrity defect associated with the layer of photoresist. In situ scatterometry produces diffraction data associated with the thickness of the photoresist patterned mask. This data is compared to a model of diffraction data associated with a suitable photoresist thickness. If the measured diffraction data is within an acceptable range, the next step of the photolithography process is carried out. However, if the measured thickness is outside of the suitable range, a defect is detected, and the wafer may be sent for re-working or re-patterned prior to main etch, thereby preventing unnecessary wafer scrap.

Abstract: In one embodiment, a semiconductor device processing method, comprising the steps of: (a) using a patterned photoresist to form a structure having at least one edge; (b) prior to removal of the photoresist, forming a conforming layer from an organic compound and patterning the conforming layer to form at least one sidewall spacer which are self-aligned to the at least one edge; (c) performing a processing operation which is at least partially localized by the at least one sidewall spacer; and (d) removing the at least one sidewall spacer and the photoresist, wherein the conforming layer is formed via deposition of at least one organic compound selected from C1 to C8 alkanes C2 to C8 alkenes, C3 to C8 cyclo-alkenes, C4 to C8 cyclo-alkenes, C1 to C8 fluoro-alkanes, C2 to C8 fluoro-alkenes, C3 to C8 cyclofluoro-alkanes, C4 to C8 cyclofluoro-alkenes, or mixtures thereof.

Abstract: A method for forming a metal interconnect comprises exposing a dielectric layer to an etch chemistry containing nitrogen-containing compound such as NH3, NF3 or N2O. The nitrogen-containing compound provides selectivity and/or profile control comparable to that provided by N2, while avoiding poisoning of photoresist by embedded N2.

Abstract: An integrated circuit fabrication process is disclosed herein. The process includes exposing a photoresist layer to a plasma, and transforming the top surface and the side surfaces of the photoresist layer to form a hardened surface. The process further includes etching the substrate in accordance with the transformed feature, wherein an etch stability of the feature is increased by the hardened surface. The photoresist layer is provided at a thickness less than 0.25 &mgr;m, for use in deep ultraviolet lithography, or for use in extreme ultraviolet lithography.

Abstract: One aspect of the present invention relates to a system and method for mitigating LER as it may occur on short wavelength photoresists. The method involves forming a short wavelength photoresist over a substrate having at least one dielectric layer formed thereon, exposing the photoresist to a plasma selective to the photoresist to strengthen the photoresist without substantially etching the at least one dielectric layer, the plasma comprising hydrogen, helium and argon, and etching the dielectric layer through openings of the strengthened photoresist with an etchant selective to the at least one dielectric layer, whereby the treated photoresist is substantially resistant to etching effects of the etchant. The system includes a photoresist monitor system for monitoring the plasma treatment to determine whether the photoresist has been strengthened and for adjusting parameters associated with the plasma treatment and for providing feedback to the plasma treatment system.

Abstract: A process for forming sub-lithographic features in an integrated circuit is disclosed herein. The process includes modifying a photoresist layer after patterning and development but before it is utilized to pattern the underlying layers. The modified photoresist layer has different etch rates in the vertical and horizontal directions. The modified photoresist layer is trimmed with a plasma etch. A feature included in the trimmed photoresist layer has a sub-lithographic lateral dimension.

Abstract: An attenuated phase shift mask utilizes a multilayer which has been locally modified. Heat treatment or e-beam treatment can locally modify the multilayer to provide different reflective characteristics. The attenuated phase shift mask can be utilized in EUV applications.

Abstract: A method for forming a metal interconnect structure in a semiconductor device with the elimination of via poisoning during trench mask formation employs a CVD organic BARC that isolates the low k dielectric film. The CVD organic BARC is deposited over the low k dielectric film and in the via hole. Once the trench mask has been formed on the CVD organic BARC, the CVD organic BARC may be removed in the same process as the photoresist of the trench mask layer. A properly formed trench will have been created since the via poisoning and resist scumming were substantially eliminated by the presence of the CVD organic BARC.