Abstract: A circuit isolation technique that uses implanted ions in embedded portions of a wafer substrate to lower the resistance of the substrate under circuits formed on the wafer or portions of circuits formed on the wafer to prevent the flow of injected currents across the substrate. The embedded ions provide low resistance regions that allow injected currents from a circuit to flow directly to a ground potential in the same circuit rather than flowing across the substrate to other circuits. High energy implantation processes on the order of 1 MeV to 3 MeVs can be used to implant the ions in embedded regions. Multiple energy levels can be used to provide thick embedded layers either prior to or after application of an epitaxial layer. Various masking materials can be used to mask the isolation regions during the implantation process, including hard masking materials such as silicon dioxide or silicon nitride, poly-silicon or an amorphous silicon layer, and a photoresist layer.

Abstract: A method for composing a dielectric layer within an interconnect structure of a multilayer semiconductor device is disclosed. A layer of silica precursor material is first deposited on a silicon substrate. Without affecting its structure and porosity, the layer of silica precursor material is then dried; and the layer of silica precursor material becomes porous silica film. Subsequently, a protective layer, such as parylene, is deposited on top of the dried porous silica film. The thickness of the protective layer should be greater than the peak-valley planarization requirements of the silicon substrate surface. As a result, a composite porous silica film, which services as a dielectric layer within an interconnect structure, is formed. This composite porous silica film has a relatively low dielectric constant and is able to withstand damage from a standard CMP procedure.

Abstract: A method of determining temperature of a semiconductor wafer during wafer fabrication includes the step of providing a response circuit on the semiconductor wafer. The method also includes the step of transmitting an interrogation signal with a signal transceiver so as to excite the response circuit. The method further includes the step of receiving a response signal which was generated by the response circuit as a result of excitation thereof. In addition, the method includes the step of determining temperature of the semiconductor wafer based on the response signal. Moreover, the method includes the step of fabricating a circuit layer on the semiconductor wafer. Both the transmitting step tri and the receiving step are performed contemporaneously with the fabricating step. An apparatus for determining temperature of a semiconductor wafer during wafer fabrication is also disclosed.

Abstract: A method for composing a dielectric layer within an interconnect structure of a multilayer semiconductor device is disclosed. A layer of silica precursor material is first deposited on a silicon substrate. Without affecting its structure and porosity, the layer of silica precursor material is then dried; and the layer of silica precursor material becomes porous silica film. Subsequently, a protective layer, such as parylene, is deposited on top of the dried porous silica film. The thickness of the protective layer should be greater than the peak-valley planarization requirements of the silicon substrate surface. As a result, a composite porous silica film, which services as a dielectric layer within an interconnect structure, is formed. This composite porous silica film has a relatively low dielectric constant and is able to withstand damage from a standard CMP procedure.

Abstract: A circuit isolation technique that uses implanted ions in embedded portions of a wafer substrate to lower the resistance of the substrate under circuits formed on the wafer or portions of circuits formed on the wafer to prevent the flow of injected currents across the substrate. The embedded ions provide low resistance regions that allow injected currents from a circuit to flow directly to a ground potential in the same circuit rather than flowing across the substrate to other circuits. High energy implantation processes on the order of 1 MeV to 3 MeVs can be used to implant the ions in embedded regions. Multiple energy levels can be used to provide thick embedded layers either prior to or after application of an epitaxial layer. Various masking materials can be used to mask the isolation regions during the implantation process, including hard masking materials such as silicon dioxide or silicon nitride, poly-silicon or an amorphous silicon layer, and a photoresist layer.

Abstract: A low dielectric material is applied, as by spinning on, over the passivation layer of a semiconductor chip to fill the gaps which may exist between the top layer metal lines, and thereby minimize the possibility of cross talk which might otherwise be present between those lines.

Abstract: A low dielectric material is applied, as by spinning on, over the passivation layer of a semiconductor chip to fill the gaps which may exist between the top layer metal lines, and thereby minimize the possibility of cross talk which might otherwise be present between those lines.

Abstract: A low dielectric material is applied, as by spinning on, over the passivation layer of a semiconductor chip to fill the gaps which may exist between the top layer metal lines, and thereby minimize the possibility of cross talk which might otherwise be present between those lines.

Abstract: A low dielectric material is applied, as by spinning on, over the passivation layer of a semiconductor chip to fill the gaps which may exist between the top layer metal lines, and thereby minimize the possibility of cross talk which might otherwise be present between those lines.

Abstract: A low dielectric material is applied, as by spinning on, over the passivation layer of a semiconductor chip to fill the gaps which may exist between the top layer metal lines, and thereby minimize the possibility of cross talk which might otherwise be present between those lines.

Abstract: An improved dual gate oxide process for dual-gated devices using oxygen ion implantation to vary the thickness of gate oxide layers. The desired layers are identified by photoresist layer patterning prior to an ion implantation. A subsequent heat treatment oxidizes the implanted region.

Abstract: A method of planarizing a semiconductor wafer having a polishing endpoint layer that includes a ligand is disclosed. One step of the method includes polishing a first side of the wafer in order to remove the ligand from the wafer. Another step of the method includes determining that a chelating agent has bound the ligand due to the polishing step removing the ligand of the polishing endpoint layer. The method also includes the step of terminating the polishing step in response to determining that the chelating agent has bound the ligand. A polishing system is also disclosed which detects a polishing endpoint based upon a chelating agent binding a ligand of a polishing endpoint layer of a semiconductor device.

Abstract: A vertically oriented metal circuit element is electrically connected and isolated between vertically separated conductors of interconnect layers in an integrated circuit. The methodology involves connecting a lower end of the metal element to the lower interconnect layer at the lower end of an opening in an inter-layer dielectric, preferably by simultaneously forming the metal element and connecting it to the conductor by vapor deposition. An upper end of the metal element initially extends above an upper surface of the inter-layer dielectric, and chemical mechanical polishing is employed to reduce the upper end to a level flush with the upper surface of the inter-layer dielectric. The flush upper end of the metal element allows it to be precisely spaced and covered with dielectric material to obtain predictable and reliable electrical isolation characteristics.

Abstract: An improved dual gate oxide process for dual-gated devices using oxygen ion implantation to vary the thickness of gate oxide layers. The desired layers are identified by photoresist layer patterning prior to an ion implantation. A subsequent heat treatment oxidizes the implanted region.

Abstract: A method and apparatus for forming a dielectric layer. A dielectric precursor solution is deposited onto a surface of a substrate. The substrate is spun to spread the dielectric precursor solution over the surface of the substrate. A catalyst is introduced through a filter, wherein the filter causes a substantially homogenous distribution of the catalyst within the substrate, wherein a dielectric layer forms containing pores and wherein a solvent is contained in the pores. The solution is dried to form the dielectric layer using a carrier gas after introducing the catalyst, wherein the carrier gas places a positive pressure within the pores while removing the solvent to form a low-k dielectric layer.

Abstract: An apparatus for determining temperature of a semiconductor wafer during wafer fabrication is disclosed. The semiconductor wafer has a response circuit. The apparatus includes a signal transceiver for (i) transmitting an interrogation signal which excites the response circuit, and (ii) receiving a response signal generated by the response circuit. The apparatus also includes a processing unit electrically coupled to the signal transceiver. The apparatus also includes a memory device electrically coupled to the processing unit. The memory device has stored therein a plurality of instructions which, when executed by the processing unit, causes the processing unit to (a) operate the signal transceiver to (i) transmit the interrogation signal so as to excite the response circuit during fabrication of the semiconductor wafer, and (ii) measure the response signal generated by the response circuit, and (b) determine temperature of the semiconductor wafer based on the response signal of the response circuit.

Abstract: A method of forming a semiconductor device on a substrate comprising the steps of: forming a first recess in the substrate; depositing an insulator in the first recess so that an isolation region is formed when the first recess is filled with the insulator; forming a second recess in a predetermined area of the substrate; forming a recess insulation layer on the surface of the second recess; depositing a conductive material on the recess insulation layer and in the second recess so that a gate region is formed when the second recess is filled with the conductive material; removing a sufficient amount of the insulator and the conductive material so that the top surfaces of the insulator, the conductive material and the substrate are substantially at the same level.

Abstract: A circuit isolation technique that uses implanted ions in embedded portions of a wafer substrate to lower the resistance of the substrate under circuits formed on the wafer or portions of circuits formed on the wafer to prevent the flow of injected currents across the substrate. The embedded ions provide low resistance regions that allow injected currents from a circuit to flow directly to a ground potential in the same circuit rather than flowing across the substrate to other circuits. High energy implantation processes on the order of 1 MeV to 3 MeVs can be used to implant the ions in embedded regions. Multiple energy levels can be used to provide thick embedded layers either prior to or after application of an epitaxial layer. Various masking materials can be used to mask the isolation regions during the implantation process, including hard masking materials such as silicon dioxide or silicon nitride, poly-silicon or an amorphous silicon layer, and a photoresist layer.

Abstract: A circuit isolation technique that uses implanted ions in embedded portions of a wafer substrate to lower the resistance of the substrate under circuits formed on the wafer or portions of circuits formed on the wafer to prevent the flow of injected currents across the substrate. The embedded ions provide low resistance regions that allow injected currents from a circuit to flow directly to a ground potential in the same circuit rather than flowing across the substrate to other circuits. High energy implantation processes on the order of 1 MeV to 3 MeVs can be used to implant the ions in embedded regions. Multiple energy levels can be used to provide thick embedded layers either prior to or after application of an epitaxial layer. Various masking materials can be used to mask the isolation regions during the implantation process, including hard masking materials such as silicon dioxide or silicon nitride, poly-silicon or an amorphous silicon layer, and a photoresist layer.

Abstract: A method and apparatus for forming a dielectric layer. A dielectric precursor solution is deposited onto a surface of a substrate. The substrate is spun to spread the dielectric precursor solution over the surface of the substrate. A catalyst is introduced through a filter, wherein the filter causes a substantially homogenous distribution of the catalyst within the substrate, wherein a dielectric layer forms containing pores and wherein a solvent is contained in the pores. The solution is dried to form the dielectric layer using a carrier gas after introducing the catalyst, wherein the carrier gas places a positive pressure within the pores while removing the solvent to form a low-k dielectric layer.