Abstract: Embodiments are disclosed that reduce gouging during multi-patterning processes using thermal decomposition materials. For one embodiment, gouging is reduced or suppressed by using thermal decomposition materials as cores during multiple patterning processes. For one embodiment, gouging is reduced or suppressed by using thermal decomposition materials as a gap fill material during multiple patterning processes. By using thermal decomposition material, gouging of an underlying layer, such as a hard mask layer, can be reduced or suppressed for patterned structures being formed using the self-aligned multi-patterning processes because more destructive etch processes, such as plasma etch processes, are not required to remove the thermal decomposition materials.

Abstract: A process is provided in which a patterned layer, an intervening layer and a first layer to be etched according to the pattern of the patterned layer are formed. The intervening layer may be a thermal decomposition layer that may be removed by a heat based removal process. After etching the first layer, the use of a heat based removal process may allow the intervening layer to be removed from the substrate without altering the first layer. In one embodiment, the first layer may be a memorization layer and the process may be a multiple patterning process.

Abstract: Embodiments are disclosed that improve etch uniformity during multi-patterning processes for the manufacture of microelectronic workpieces by reshaping spacers using thermal decomposition materials as a protective layer. Because the thermal decomposition material can be removed through thermal treatment processes without requiring etch processes, spacers can be reshaped with no spacer profile change or damage while suppressing undesired gouging differences in underlying layers and related degradation in etch uniformity.

Abstract: A process is provided in which low-k layers are protected from damage caused by exposure to atmospheric conditions by providing protection through the use of thermal decomposition materials. In one embodiment, the low-k layers may be low-k dielectric layers utilized in BEOL process steps. The thermal decomposition materials may be utilized to coat exposed regions of the low-k layers so that the low-k layers are not exposed to atmospheric conditions. In an exemplary embodiment, the low-k layers may be protected by plugging openings in the low-k layer with the thermal decomposition material. In another exemplary embodiment, trench and via openings in the low-k layer are plugged with the thermal decomposition material. The thermal decomposition materials may be removed by a heat based thermal anneal process step that does not damage the low-k layers.

Abstract: A process is provided in which low-k layers are protected from damage by the use of thermal decomposition materials. In one embodiment, the low-k layers may be low-k dielectric layers utilized in BEOL process steps. The thermal decomposition materials may be utilized to replace organic layers that typically require ashing processes to remove. By removing the need for certain ashing steps, the exposure of the low-k dielectric layer to ashing processes may be lessened. In another embodiment, the low-k layers may be protected by plugging openings in the low-k layer with the thermal decomposition material before a subsequent process step that may damage the low-k layer is performed. The thermal decomposition materials may be removed by a thermal anneal process step that does not damage the low-k layers.

Abstract: Self-aligned interconnect patterning for back-end-of-line (BEOL) structures is described. A method of fabricating an interconnect structure for an integrated circuit includes depositing a first metal layer on an initial interconnect structure, forming a patterned spacer layer containing recessed features on the first metal layer, and etching a self-aligned via in the first metal layer and into the initial interconnect structure using a recessed feature in the patterned spacer layer as a mask. The method further includes filling the via in the first metal layer and the recessed features in the patterned spacer layer with a second metal layer, removing the patterned spacer layer, and etching a recessed feature in the first metal layer using the second metal layer as a mask.

Abstract: A method of processing materials on a semiconductor workpiece using an integrated sequence of processing steps executed on a common manufacturing platform hosting a plurality of processing modules including one or more film-forming modules, one or more etching modules, and one or more transfer modules is provided. A workpiece having an upper planar surface is received into the common manufacturing platform. The method further includes conformally applying a thin film over the feature pattern using one of the film-forming modules, removing the thin film from upper surfaces of the feature pattern using one of the etching modules to leave behind the thin film in the recessed feature, and removing the fill material from the upper planar surface of the workpiece. The integrated sequence of processing steps is executed in a controlled environment within the common manufacturing platform and without leaving the controlled environment.

Abstract: Embodiments of the invention provide a wrap-around contact integration scheme that includes sidewall protection during contact formation. According to one embodiment, a substrate processing method includes providing a substrate containing raised contacts in a first dielectric film and a second dielectric film above the first dielectric film, depositing a metal-containing film on the second dielectric film, and forming a patterned metal-containing film by etching mask openings in the metal-containing film. The method further includes anisotropically etching recessed features in the second dielectric film above the raised contacts using the patterned metal-containing film as a mask, where the anisotropically etching forms a metal-containing sidewall protection film by redeposition of a portion of the patterned metal-containing film on sidewalls of the recessed features.

Abstract: Methods for integration of conformal barrier layers and Ru metal liners with Cu metallization in semiconductor manufacturing are described in several embodiments. According to one embodiment, the method includes providing a substrate containing a recessed feature, depositing a barrier layer in the recessed feature, depositing a Ru metal liner on the barrier layer, and exposing the substrate to an oxidation source gas to oxidize the barrier layer through the Ru metal liner. The method further includes filling the recessed feature with CuMn metal using an ionized physical vapor deposition (IPVD) process, heat-treating the substrate to diffuse Mn from the CuMn metal to the oxidized barrier layer, and reacting the diffused Mn with the oxidized barrier layer to form a Mn-containing diffusion barrier.

Abstract: A substrate processing method is provided for metal filling of recessed features in a substrate. According to one embodiment, the method includes providing a substrate containing horizontally spaced nested and isolated recessed features, filling the nested and isolated recessed features with a blocking material, and performing in any order: a) sequentially first, removing the blocking material from the nested recessed features, and second, filling the nested recessed features with a first metal, and b) sequentially first, removing the blocking material from the isolated recessed features, and second, filling the isolated recessed features with a second metal that is different from the first metal. According to one embodiment, the first metal may include Ru metal and the second metal may include Cu metal. According to one embodiment, a microelectronic device containing metal filled recessed features is provided.

Abstract: Embodiments of the invention describe a method of corner rounding and trimming of nanowires used in semiconductor devices. According to one embodiment, the method includes providing in a process chamber a plurality of nanowires separated from each other by a void, where the plurality of nanowires have a height and at least substantially right angle corners, forming an oxidized surface layer on the plurality of nanowires using an oxidizing microwave plasma, removing the oxidized surface layer to trim the height and round the corners of the plurality of nanowires, and repeating the forming and removing at least once until the plurality of nanowires have a desired trimmed height and rounded corners.

Abstract: Embodiments of the invention provide a wrap-around contact integration scheme that includes sidewall protection during contact formation. According to one embodiment, a substrate processing method includes providing a substrate containing raised contacts in a first dielectric film and a second dielectric film above the first dielectric film, depositing a metal-containing film on the second dielectric film, and forming a patterned metal-containing film by etching mask openings in the metal-containing film. The method further includes anisotropically etching recessed features in the second dielectric film above the raised contacts using the patterned metal-containing film as a mask, where the anisotropically etching forms a metal-containing sidewall protection film by redeposition of a portion of the patterned metal-containing film on sidewalls of the recessed features.

Abstract: Methods for integration of conformal barrier layers and Ru metal liners with Cu metallization in semiconductor manufacturing are described in several embodiments. According to one embodiment, the method includes providing a substrate containing a recessed feature, depositing a barrier layer in the recessed feature, depositing a Ru metal liner on the barrier layer, and exposing the substrate to an oxidation source gas to oxidize the barrier layer through the Ru metal liner. The method further includes filling the recessed feature with CuMn metal using an ionized physical vapor deposition (IPVD) process, heat-treating the substrate to diffuse Mn from the CuMn metal to the oxidized barrier layer, and reacting the diffused Mn with the oxidized barrier layer to form a Mn-containing diffusion barrier.

Abstract: Embodiments of the invention describe a method of corner rounding and trimming of nanowires used in semiconductor devices. According to one embodiment, the method includes providing in a process chamber a plurality of nanowires separated from each other by a void, where the plurality of nanowires have a height and at least substantially right angle corners, forming an oxidized surface layer on the plurality of nanowires using an oxidizing microwave plasma, removing the oxidized surface layer to trim the height and round the corners of the plurality of nanowires, and repeating the forming and removing at least once until the plurality of nanowires have a desired trimmed height and rounded corners.

Abstract: Methods for integration of atomic layer deposition (ALD) of barrier layers and chemical vapor deposition (CVD) of Ru liners for Cu filling of narrow recessed features for semiconductor devices are disclosed in several embodiments. According to one embodiment, the method includes providing a substrate containing a recessed feature, depositing a conformal barrier layer by ALD in the recessed feature, where the barrier layer contains TaN or TaAlN, depositing a conformal Ru liner by CVD on the barrier layer, and filling the recessed feature with Cu metal.

Abstract: A method for forming a manganese-containing film to be formed between an underlayer and a copper film includes reacting a manganese compound gas with a nitrogen-containing reaction gas to form a nitrogen-containing manganese film on the underlayer; and reacting a manganese compound gas with a reducing reaction gas, thermally decomposing a manganese compound gas, or performing a decomposition reaction on a manganese compound gas through irradiation of energy or active species to form a metal manganese film on the nitrogen-containing manganese film.

Abstract: A method for manufacturing a semiconductor device for forming a metal element-containing layer on an insulating layer in which a concave portion is formed, includes: forming an oxide layer including mainly an oxide of the metal element on the insulating layer including the concave portion; and forming a silicate layer including mainly a silicate of the metal element by making the oxide layer into silicate by annealing under a reducing atmosphere.

Abstract: The objective of the present invention is to provide a technique capable of easily forming an alloy layer containing an additive metal on an object to provide a concentration gradient in a thickness direction by sputtering in one treatment vessel. That is, the present invention can form a film with the desired concentration, and includes a first film forming process and a second film forming process that changes at least one of, the pressure in the treatment vessel, and the electric power so they are different from the first film forming process, so that the concentration of the additive metal is different from the concentration of the additive metal of the first alloy film.

Abstract: Methods for integration of atomic layer deposition (ALD) of barrier layers and chemical vapor deposition (CVD) of Ru liners for Cu filling of narrow recessed features for semiconductor devices are disclosed in several embodiments. According to one embodiment, the method includes providing a substrate containing a recessed feature, depositing a conformal barrier layer by ALD in the recessed feature, where the barrier layer contains TaN or TaAlN, depositing a conformal Ru liner by CVD on the barrier layer, and filling the recessed feature with Cu metal.

Abstract: A method for manufacturing a semiconductor device includes: forming an insulating film on a substrate where a first conductive film is formed; forming a recess in the insulating film such that the first conductive film is exposed in a portion of the recess; forming a metal oxide film to cover the insulating film and the first conductive film after forming a recess; performing a hydrogen radical treatment of irradiating the substrate with atomic hydrogen after forming a metal oxide film; and forming a second conductive film in the recess.