Abstract: A method of chemical-mechanical polishing for forming a shallow trench isolation is disclosed. A substrate having a number of active regions, including a number of relatively large active regions and a number of relatively small active regions, is provided. The method comprises the following steps. A silicon nitride layer on the substrate is first formed. A number of shallow trenches are formed between the active regions. An oxide layer is formed over the substrate, so that the shallow trenches are filled with the oxide layer. A partial reverse active mask is formed on the oxide layer. The partial reverse active mask has an opening at a central part of each relatively large active region. The opening exposes a portion of the oxide layer. The opening has at least a dummy pattern. The oxide layer on the central part of each large active region is removed to expose the silicon nitride layer. The partial reverse active mask is removed. The oxide layer is planarized to expose the silicon nitride layer.

Abstract: An improved dual damascene structure is provided for use in the wiring-line structures of multi-level interconnects in integrated circuit. In this dual damascene structure, low-K (low dielectric constant) dielectric materials are used to form both the di-electric layers and the etch-stop layers between the metal interconnects in the IC device. With this feature, the dual damascene structure can prevent high parasite capacitance to occur therein that would otherwise cause large RC delay to the signals being transmitted through the metal interconnects and thus degrade the performance of the IC device. With the dual damascene structure, such parasite capacitance can be reduced, thus assuring the performance of the IC device.

Abstract: An air gap structure and formation method for substantially reducing the undesired capacitance between adjacent interconnects, metal lines or other features in an integrated circuit device is disclosed. The air gap extends above, and may also additionally extend below, the interconnects desired to be isolated thus minimizing fringing fields between the lines. The integrated air gap structure and formation method can be utilized in conjunction with either damascene or conventional integrated circuit metallization schemes. Also, multiple levels of the integrated air gap structure can be fabricated to accommodate multiple metal levels while always ensuring that physical dielectric layer support is provided to the device structure underlying the interconnects.

Abstract: A cluster tool and a number of different processes for making a cobalt-silicide material are disclosed. Combinations of alloyed layers of Co—Ti—along with layers of Co—are arranged and heat treated so as to effectuate a silicide reaction. The resulting structures have extremely low resistance, and show little line width dependence, thus making them particularly attractive for use in semiconductor processing. A cluster tool is configured with appropriate sputter targets/heat assemblies to implement many of the needed operations for the silicide reactions, thus resulting in higher savings, productivity, etc.

Abstract: A semiconductor device that includes cobalt-silicide based contacts is disclosed, as well as a process for making the same. Combinations of alloyed layers of Co—Ti—along with layers of Co—are arranged and heat treated so as to effectuate a silicide reaction on a silicon substrate. The resulting structures have extremely low resistance, and show little line width dependence, thus making them particularly attractive for use in semiconductor devices and processes.

Abstract: A semiconductor device that includes cobalt-silicide based contacts is disclosed, as well as a process for making the same. Combinations of alloyed layers of Co—Ti—along with layers of Co—are arranged and heat treated so as to effectuate a silicide reaction on a silicon substrate. The resulting structures have extremely low resistance, and show little line width dependence, thus making them particularly attractive for use in semiconductor devices and processes.

Abstract: A semiconductor substrate is provided, and at least one first mask is formed above the semiconductor substrate. The first mask has a plurality of thicknesses and blocks at least one semi-insulating region. A second mask is thereafter formed on a surface of the semiconductor substrate. The second mask covers the semi-insulating region. The semi-insulating region is implanted with a high energy beam of particles by utilizing the second mask and the first mask as particle hindering masks. Finally, the second mask is removed.

Abstract: An air gap structure and formation method for substantially reducing the undesired capacitance between adjacent interconnects, metal lines or other features in an integrated circuit device is disclosed. The air gap extends above, and may also additionally extend below, the interconnects desired to be isolated thus minimizing fringing fields between the lines. The integrated air gap structure and formation method can be utilized in conjunction with either damascene or conventional integrated circuit metallization schemes. Also, multiple levels of the integrated air gap structure can be fabricated to accommodate multiple metal levels while always ensuring that physical dielectric layer support is provided to the device structure underlying the interconnects.

Abstract: A semiconductor substrate is provided, and at least one first mask is formed above the semiconductor substrate. The first mask has a plurality of thicknesses and blocks at least one semi-insulating region. A second mask is thereafter formed on a surface of the semiconductor substrate. The second mask covers the semi-insulating region. The semi-insulating region is implanted with a high energy beam of particles by utilizing the second mask and the first mask as particle hindering masks. Finally, the second mask is removed.

Abstract: A semiconductor substrate is provided, and at least one first mask is formed above the semiconductor substrate. The first mask blocks at least one semi-insulating region. A second mask is thereafter formed on a surface of the semiconductor substrate. The second mask covers the semi-insulating region. The semi-insulating region is implanted with a high energy beam of particles by utilizing the second mask and the first mask as particle hindering masks. Finally, the second mask is removed.

Abstract: A semiconductor device that includes cobalt-silicide based contacts is disclosed, as well as a process for making the same. Combinations of alloyed layers of Co—Ti— along with layers of Co— are arranged and heat treated so as to effectuate a silicide reaction on a silicon substrate. The resulting structures have extremely low resistance, and show little line width dependence, thus making them particularly attractive for use in semiconductor devices and processes.

Abstract: The present invention disclosed a method for manufacturing a semiconductor device on a semiconductor substrate, the method comprising the steps of: forming a gate dielectric layer on the semiconductor substrate. A gate is formed on the gate dielectric layer. A first ion implantation is performed to form extended source and drain shallow junctions in the semiconductor substrate. Spacer are formed on the side wall of the gate with liner between the gate and the spacers. The source and drain region is formed by performing a second ion implantation. A thermal annealing is used to eliminate the implantation defect and active the dopants. A surface treatment is used to form selective polycrystalline silicon on the gate and the source and drain region, thereby forming raised source and drain. A Cobalt layer is formed on the selective polycrystalline silicon.

Abstract: A method of chemical-mechanical polishing for forming a shallow trench isolation is disclosed. A substrate having a number of active regions, including a number of relatively large active regions and a number of relative small active regions, is provided. The method comprises the following steps. A silicon nitride layer on the substrate is formed. A number of shallow trenches are formed between the active regions one or more of which may constitute an alignment mark. An oxide layer is formed over the substrate, so that the shallow trenches are filled with the oxide layer. A partial reverse active mask is formed on the oxide layer. The partial reverse active mask exposes a portion of the oxide layer over the large active area and over the alignment mark. The oxide layer of each large active region and the alignment mark is removed. The partial reverse active mask is removed. The oxide layer is planarized.

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 of chemical-mechanical polishing for forming a shallow trench isolation is disclosed. A substrate having a number of active regions, including a number of relative large active regions and a number of relative small active regions, is provided. The method comprises the following steps. A silicon nitride layer on the substrate is first formed A number of shallow trenches are formed between the active regions An oxide layer is formed over the substrate, so that the shallow trenches are filled with the oxide layer. A partial reverse active mask is formed on the oxide layer. The partial rever active mask has an opening at a central part of each relative large active region. The opening exposes a portion of the oxide layer. The opening has at least a dummy pattern. The oxide layer on the central part of each large active region is removed to expose the silicon nitride layer. The partial reverse active mask is removed The oxide layer is planarized to expose the silicon nitride layer.

Abstract: A method of designing an active region pattern with a shifted dummy pattern, wherein an integrated circuit having an original active region pattern thereon is provided. The original active region pattern is expanded with a first parameter of line width to obtain a first pattern. By subtracting the first pattern, a second pattern is obtained. A dummy pattern which comprises an array of a plurality of elements is provided. By shifting the elements, a shifted dummy pattern is obtained. The second pattern and the shifted dummy pattern are combined, so that an overlapped region thereof is extracted as a combined dummy pattern. The combined dummy pattern is expanded with a second parameter of line width, so that a resultant dummy pattern is obtained. The resultant dummy pattern is added to the first pattern, so that the active region pattern with a shifted dummy pattern is obtained.

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 of chemical-mechanical polishing for forming a shallow trench isolation is disclosed. A substrate having a number of active regions, including a number of relatively large active regions and a number of relative small active regions, is provided. The method comprises the following steps. A silicon nitride layer on the substrate is formed. A number of shallow trenches are formed between the active regions one or more of which may constitute an alignment mark. An oxide layer is formed over the substrate, so that the shallow trenches are filled with the oxide layer. A partial reverse active mask is formed on the oxide layer. The partial reverse active mask exposes a portion of the oxide layer over the large active area and over the alignment mark. The oxide layer of each large active region and the alignment mark is removed. The partial reverse active mask is removed. The oxide layer is planarized.

Abstract: The present invention disclosed a method for manufacturing a semiconductor device on a semiconductor substrate, the method comprising the steps of: forming a gate dielectric layer on the semiconductor substrate. A gate is formed on the gate dielectric layer. A first ion implantation is performed to form extended source and drain shallow junctions in the semiconductor substrate. Spacer are formed on the side wall of the gate with liner between the gate and the spacers. The source and drain region is formed by performing a second ion implantation. A thermal annealing is used to eliminate the implantation defect and active the dopants. A surface treatment is used to form selective polycrystalline silicon on the gate and the source and drain region, thereby forming raised source and drain. A Cobalt layer is formed on the selective polycrystalline silicon.

Abstract: A cluster tool and a number of different processes for making a cobalt-silicide material are disclosed. Combinations of alloyed layers of Co—Ti— along with layers of Co— are arranged and heat treated so as to effectuate a silicide reaction. The resulting structures have extremely low resistance, and show little line width dependence, thus making them particularly attractive for use in semiconductor processing. A cluster tool is configured with appropriate sputter targets/heat assemblies to implement many of the needed operations for the silicide reactions, thus resulting in higher savings, productivity, etc.