Abstract: A method of forming an integrated circuit includes providing a buffer layer comprising a dielectric material above a layer of conductive material and providing a layer of mask material above the buffer layer. The mask material comprises amorphous carbon. The method also includes removing a portion of the buffer layer and the layer of mask material to form a mask. A feature is formed in the layer of conductive material according to the mask.

Abstract: A double gate metal-oxide semiconductor field-effect transistor (MOSFET) includes a fin, a first gate and a second gate. The first gate is formed on top of the fin. The second gate surrounds the fin and the first gate. In another implementation, a triple gate MOSFET includes a fin, a first gate, a second gate, and a third gate. The first gate is formed on top of the fin. The second gate is formed adjacent the fin. The third gate is formed adjacent the fin and opposite the second gate.

Abstract: A double gate metal-oxide semiconductor field-effect transistor (MOSFET) includes a fin, a first gate and a second gate. The first gate is formed on top of the fin. The second gate surrounds the fin and the first gate. In another implementation, a triple gate MOSFET includes a fin, a first gate, a second gate, and a third gate. The first gate is formed on top of the fin. The second gate is formed adjacent the fin. The third gate is formed adjacent the fin and opposite the second gate.

Abstract: A method of forming an integrated circuit includes providing a buffer layer comprising a dielectric material above a layer of conductive material and providing a layer of mask material above the buffer layer. The mask material comprises amorphous carbon. The method also includes removing a portion of the buffer layer and the layer of mask material to form a mask. A feature is formed in the layer of conductive material according to the mask.

Abstract: Methods are provided for forming contacts for a semiconductor device. The methods may include depositing various materials, such as polysilicon, nitride, oxide, and/or carbon materials, over the semiconductor device. The methods may also include forming a contact hole and filling the contact hole to form the contact for the semiconductor device.

Abstract: A method of fabricating a semiconductor device using lithography. The method can include providing a wafer assembly having a layer to be processed disposed under a photo resist layer and illuminating the wafer assembly with an exposure dose transmitted through a birefringent material disposed between a final optical element of an imaging subsystem used to transmit the exposure dose and the photo resist layer. Also disclosed is a wafer assembly from which at least one semiconductor device can be fabricated. The wafer assembly can include a layer to be processed, a photo resist layer disposed over the layer to be processed and a contrast enhancing, birefringent top anti-reflecting coating (TARC).

Abstract: A process for fabricating a semiconductor device, including applying an immersion lithography medium to a surface of a semiconductor wafer; exposing a material on the surface of the semiconductor wafer to electromagnetic radiation having a selected wavelength; and applying supercritical carbon dioxide to the semiconductor wafer to remove the immersion lithography medium from the surface of the semiconductor wafer. In one embodiment, the process includes recovery of the immersion lithography medium.

Abstract: A method of selecting a plurality of lithography process parameters for patterning a layout on a wafer includes simulating how the layout will print on the wafer for a plurality of resolution enhancement techniques (RETs), where each RET corresponds to a plurality of lithography process parameters. For each RET, the edges of structures within the simulated layout can be classified based on manufacturability. RETs that provide optimal manufacturability can be selected. In this manner, the simulation tool can be used to determine the optimal combination of scanner setup and reticle type for minimizing the variation in wafer critical dimension (CD).

Abstract: A method includes specifying a plurality of optical proximity correction metrology sites on a wafer. Metrology data is collected from at least a subset of the metrology sites. Data values are predicted for the subset of the metrology sites using an optical proximity correction design model. The collected metrology data is compared to the predicted data values to generate an optical proximity correction metric. A problem condition associated with the optical proximity correction design model is identified based on the optical proximity correction metric.

Abstract: A method includes generating a layout for an integrated circuit device in accordance with a plurality of layout design rules. A plurality of metrology sites on the layout associated with at least one subset of the layout design rules is identified. A metrology tag associated with each of the metrology sites is generated. At least one metrology recipe for determining a characteristic of the integrated circuit device is generated based on the metrology tags. Metrology data is collected using the at least one metrology recipe. A selected layout design rule in the at least one subset is modified based on the metrology data.

Abstract: A method includes providing an initial IC device design, which design has a desired set of electrical characteristics. A layout representation corresponding to the initial device design is generated. A simulation tool is used to determine whether the layout representation corresponds to an IC device design having the desired electrical characteristics. In addition, the variation between structures within IC device designed due to process variations is evaluated using the simulation tool. This variation can be used to determine whether the design is optimized.

Abstract: A method of forming an integrated circuit includes providing a buffer layer comprising a dielectric material above a layer of conductive material and providing a layer of mask material above the buffer layer. The mask material comprises amorphous carbon. The method also includes removing a portion of the buffer layer and the layer of mask material to form a mask. A feature is formed in the layer of conductive material according to the mask.

Abstract: A semiconductor device may include a substrate and an insulating layer formed on the substrate. A fin may be formed on the insulating layer. The fin may include a side surface and a top surface, and the side surface may have a <100> orientation. A first gate may be formed on the insulating layer proximate to the side surface of the fin.

Abstract: A method of forming a plurality of contact holes of varying pitch and density in a contact layer of an integrated circuit device is provided. The plurality of contact holes can include a plurality of regularly spaced contact holes having a first pitch along a first direction and a plurality of semi-isolated contact holes having a second pitch along a second direction. A double-dipole illumination source can transmit light energy through a mask having a pattern corresponding to a desired contact hole pattern. The double-dipole illumination source can include a first dipole aperture, which is oriented and optimized for patterning the regularly spaced contact holes, and a second dipole aperture, which is oriented substantially orthogonal to the first dipole aperture and optimized for patterning the plurality of semi-isolated contact holes. The contact layer can be etched using the patterned photoresist layer.

Abstract: A method of manufacturing a semiconductor device includes forming a gate electrode over a substrate, implanting dopants into the substrate and activating the dopants using laser thermal annealing. During annealing, the laser and substrate are moved relative to one another, and the movement of the laser and the substrate relative to one another does not pause between and during activating one portion of the source/drain regions and activating another portion of the source/drain regions. Each pulse from the laser can respectively irradiate different portions of the source/drain regions, and a spot area of the laser is less than 50 millimeter2.

Abstract: A method of producing a layout representation corresponding to an integrated circuit (IC) device design can include generating an initial layout representation in accordance with a predetermined set of design rules and simulating how structures within the initial layout representation will pattern on a wafer. Based on the simulation, portions of the layout representation, which include structures demonstrating poor manufacturability and/or portions of the layout representation in which extra manufacturability margin is present, can be identified. Portions of the layout representation including structures demonstrating poor manufacturability and/or in which extra manufacturability margin is present can be modified to optimize the layout representation.

Abstract: A method of reflective lithography includes directing an asymmetric radiation (light) beam onto a reticle of a reflective lithography system. The asymmetry in the shape of the radiation beam may be used to compensate for a non-zero (non-normal) angle of incidence of the incident radiation. The radiation source shape may be configured to produce a substantially-symmetric output from the reticle. The shape of the radiation source may be configurable by any of a variety of suitable methods, for example by use of a configurable reflective device such as a fly's eye mirror, or by use of one or more suitable mirrors, lenses, and/or slits.

Abstract: A method of selecting a plurality of lithography process parameters for patterning a layout on a wafer includes simulating how the layout will print on the wafer for a plurality of resolution enhancement techniques (RETs), where each RET corresponds to a plurality of lithography process parameters. For each RET, the edges of structures within the simulated layout can be classified based on manufacturability. RETs that provide optimal manufacturability can be selected. In this manner, the simulation tool can be used to determine the optimal combination of scanner setup and reticle type for minimizing the variation in wafer critical dimension (CD).

Abstract: The present invention enables the production of improved high-reliability, high-density semiconductor devices. The present invention provides the high-density semiconductor devices by decreasing the size of semiconductor device structures, such as gate channel lengths. Short-channel effects are prevented by the use of highly localized halo implant regions formed in the device channel. Highly localized halo implant regions are formed by a tilt pre-amorphization implant and a laser thermal anneal of the halo implant region.

Abstract: A method of producing design rules including generating a plurality of parametrically varying geometric layouts and simulating how each geometric layout will pattern on a wafer. Edges of structures within the simulated geometric layouts can be classified based on manufacturability and design rules can be created to disallow layouts demonstrating poor manufacturability.