Abstract: A method for depositing dielectric material into gaps between wiring lines in the formation of a semiconductor device includes the formation of a cap layer and the formation of gaps into which high density plasma chemical vapor deposition (HDPCVD) dielectric material is deposited. First and second antireflective coatings may be formed on the wiring line layer, the first and second antireflective coatings being made from different materials. Both antireflective coatings and the wiring line layer are etched through to form wiring lines separated by gaps. The gaps between wiring lines may be filled using high density plasma chemical vapor deposition.

Abstract: A dielectric layer overlying a substrate is prepared. A damascene opening is etched into the dielectric layer. The damascene opening is filled with copper or copper alloy. A surface of the copper or copper alloy is treated with hydrogen-containing plasma such as H2 or NH3 plasma. The treated surface of the copper or copper alloy then reacts with trimethylsilane or tertramethylsilane under plasma enhanced chemical vapor deposition (PECVD) conditions. Subsequently, by PECVD, a silicon carbide layer is in-situ deposited on the copper or copper alloy.

Abstract: A method for making a damascene interconnect structure with a bi-layer capping film is provided. The damascene interconnect structure comprises a semiconductor layer and a dielectric layer disposed on the semiconductor layer. The dielectric layer has a main surface and at least one damascened recess provided on the main surface. A copper wire is embedded in the damascened recess. The copper wire has a chemical mechanical polished upper surface, which is substantially co-planar with the main surface of the dielectric layer. After polishing the upper surface of the copper wire, the upper surface is pre-treated and reduced in a conductive plasma environment at a temperature of below 300° C. A bi-layer capping film is thereafter disposed on the upper surface of the copper wire. The bi-layer capping film consists of a lower HDPCVD silicon nitride layer and an upper doped silicon carbide layer.

Abstract: The present invention provides a method for forming low dielectric constant inter-metal dielectric layer. The method includes providing a semiconductor substrate and forming a first dielectric layer on the semiconductor substrate. Conductor structures are formed in the first dielectric layer. The partial first dielectric layer is removed by using the conductor structures as etching mask. A second dielectric layer is formed between the conductor structures, which has a dielectric constant smaller than the first dielectric layer. The second dielectric layer also alternatively has air voids contained therein to reduce dielectric constant.

Abstract: A damascene interconnect structure with a bi-layer capping film is provided. The damascene interconnect structure comprises a semiconductor layer and a dielectric layer disposed on the semiconductor layer. The dielectric layer has a main surface and at least one damascened recess provided on the main surface. A copper wire is embedded in the damascened recess. The copper wire has a chemical mechanical polished upper surface, which is substantially co-planar with the main surface of the dielectric layer. After polishing the upper surface of the copper wire, the upper surface is pre-treated and reduced in a conductive plasma environment at a temperature of below 300° C. A bi-layer capping film is thereafter disposed on the upper surface of the copper wire. The bi-layer capping film consists of a lower HDPCVD silicon nitride layer and an upper doped silicon carbide layer.

Abstract: A method for removing a dielectric layer formed upon a semiconductor substrate is disclosed. In an exemplary embodiment of the invention, the method includes subjecting the dielectric layer to a dry etch process and subjecting an adhesion promoter layer underneath the dielectric layer to a wet etch process.

Abstract: A method for depositing dielectric material into gaps between wiring lines in the formation of a semiconductor device includes the formation of a cap layer and the formation of gaps into which high density plasma chemical vapor deposition (HDPCVD) dielectric material is deposited. First and second antireflective coatings may be formed on the wiring line layer, the first and second antireflective coatings being made from different materials. Both antireflective coatings and the wiring line layer are etched through to form wiring lines separated by gaps. The gaps between wiring lines may be filled using high density plasma chemical vapor deposition.

Abstract: A method for forming dielectric layers is described. Wiring lines are formed on a provided semiconductor substrate. Spacers are formed on the sidewalls of the wiring lines. A liner layer is formed on the wiring lines and on the spacers by a first HDPCVD step, such as unbiased, unclamped HDPCVD. A dielectric layer is formed on the liner layer to cover the wiring lines and to fill gaps between the wiring lines by a second HDPCVD step.

Abstract: A method for making a damascene interconnect structure with a bi-layer capping film is provided. The damascene interconnect structure comprises a semiconductor layer and a dielectric layer disposed on the semiconductor layer. The dielectric layer has a main surface and at least one damascened recess provided on the main surface. A copper wire is embedded in the damascened recess. The copper wire has a chemical mechanical polished upper surface, which is substantially co-planar with the main surface of the dielectric layer. After polishing the upper surface of the copper wire, the upper surface is pre-treated and reduced in a conductive plasma environment at a temperature of below 300° C. A bi-layer capping film is thereafter disposed on the upper surface of the copper wire. The bi-layer capping film consists of a lower HDPCVD silicon nitride layer and an upper doped silicon carbide layer.

Abstract: A damascene interconnect structure with a bi-layer capping film is provided. The damascene interconnect structure comprises a semiconductor layer and a dielectric layer disposed on the semiconductor layer. The dielectric layer has a main surface and at least one damascened recess provided on the main surface. A copper wire is embedded in the damascened recess. The copper wire has a chemical mechanical polished upper surface, which is substantially co-planar with the main surface of the dielectric layer. After polishing the upper surface of the copper wire, the upper surface is pre-treated and reduced in a conductive plasma environment at a temperature of below 300 ° C. A bi-layer capping film is thereafter disposed on the upper surface of the copper wire. The bi-layer capping film consists of a lower HDPCVD silicon nitride layer and an upper doped silicon carbide layer.

Abstract: A process for forming fusible links in an integrated circuit in which the fusible links are formed in the final metallization layer simultaneously with bonding pads. The process can be applied in the fabrication of integrated circuits that employ copper metallization and low k dielectric materials. After patterning the final metal (aluminum) layer to form the fusible links and the bonding pads, a dielectric etch stop layer is formed over the final metal layer before a passivation layer is deposited. The passivation layer is removed in areas over the fusible links and the bonding pads. The dielectric etch stop layer is removed either from above the bonding pads only, or from above both the bonding pads and the fusible links.

Abstract: A process for forming fusible links in an integrated circuit in which the fusible links are formed in the final metallization layer simultaneously with bonding pads. The process can be applied in the fabrication of integrated circuits that employ copper metallization and low k dielectric materials. After patterning the final metal (aluminum) layer to form the fusible links and the bonding pads, a dielectric etch stop layer is formed over the final metal layer before a passivation layer is deposited. The passivation layer is removed in areas over the fusible links and the bonding pads. The dielectric etch stop layer is removed either from above the bonding pads only, or from above both the bonding pads and the fusible links.

Abstract: A method for forming a planarized dielectric layer upon a semiconductor wafer is disclosed. In an exemplary embodiment of the invention, the method includes applying an adhesion promoter to the wafer, thereby forming an adhesion promoter layer. A dielectric material is applied in a spin-on fashion upon the adhesion promoter layer at a relative humidity of less than 40% and for a thickness setting duration of less than 30 seconds. Then, the dielectric material is dried by baking without additional spinning of the semiconductor wafer.

Abstract: A method for forming a damascene opening in a polymer-based dielectric layer is introduced. The method includes providing a substrate, which has also a conductive structure layer and a polymer-based dielectric layer formed thereon already. The polymer-based dielectric layer is uniformly hardened by a thermal treatment. A mask layer is formed on the polymer-based dielectric layer. The mask layer and the polymer-based dielectric layer are patterned to form an opening. The opening exposes a surface of the polymer-based dielectric layer. The exposed surface of the polymer-based dielectric layer is further hardened by a local hardening process. The local hardening process includes using an irradiation source of a high energy light beam, electron beam or ion beam to proceed the local hardening. The irradiation source can be incident onto the substrate by vertical angle or inclining angle. The substrate can also be rotated.

Abstract: A method for forming dielectric layers is described. Wiring lines are formed on a provided semiconductor substrate. Spacers are formed on the sidewalls of the wiring lines. A liner layer is formed on the wiring lines and on the spacers by a first HDPCVD step, such as unbiased, unclamped HDPCVD. A dielectric layer is formed on the liner layer to cover the wiring lines and to fill gaps between the wiring lines by a second HDPCVD step.

Abstract: The present invention provides a method for forming low dielectric constant inter-metal dielectric layer. The method comprises providing a semiconductor structure and forming a first dielectric layer on the semiconductor structure. Conductor structures are formed in the first dielectric layer. The partial first dielectric layer is removed by using the conductor structures as etching mask. A second dielectric layer is formed between the conductor structures, which has a dielectric constant smaller than the first dielectric layer. The second dielectric layer also alternatively has air voids contained therein to reduce dielectric constants.

Abstract: The present invention provides a method for forming low dielectric constant inter-metal dielectric layer. The method comprises providing a semiconductor substrate and forming a first dielectric layer on the semiconductor substrate. Conductor structures are formed in the first dielectric layer. The partial first dielectric layer is removed by using the conductor structures as etch mask. A second dielectric layer is formed between the conductor structure, which has a dielectric constant smaller than the first dielectric layer. The semiconductor structure comprises a substrate, a first dielectric layer on the substrate, multitude of conductor structures in the first dielectric layer, and multitude of second dielectric structures in the first dielectric layer and between the conductor structures.

Abstract: A method for forming dielectric layers is described. Wiring lines are formed on a provided semiconductor substrate. Spacers are formed on the sidewalls of the wiring lines. A liner layer is formed on the wiring lines and on the spacers by a first HDPCVD step, such as unbiased, unclamped HDPCVD. A dielectric layer is formed on the liner layer to cover the wiring lines and to fill gaps between the wiring lines by a second HDPCVD step.

Abstract: A method for removing a dielectric layer formed upon a semiconductor substrate is disclosed. In an exemplary embodiment of the invention, the method includes subjecting the dielectric layer to a dry etch process and subjecting an adhesion promoter layer underneath the dielectric layer to a wet etch process.

Abstract: A method for forming a planarized dielectric layer upon a semiconductor wafer is disclosed. In an exemplary embodiment of the invention, the method includes applying an adhesion promoter to the wafer, thereby forming an adhesion promoter layer. A dielectric material is applied in a spin-on fashion upon the adhesion promoter layer at a relative humidity of less than 40% and for a thickness setting duration of less than 30 seconds. Then, the dielectric material is dried by baking without additional spinning of the semiconductor wafer.