Abstract: A transistor may include a semiconductor region such as a rectangular doped silicon well. Gate fingers may overlap the silicon well. The gate fingers may be formed from polysilicon and may be spaced apart from each other along the length of the well by a fixed gate-to-gate spacing. The edges of the well may be surrounded by field oxide. Epitaxial regions may be formed in the well to produce compressive or tensile stress in channel regions that lie under the gate fingers. The epitaxial regions may form source-drain terminals. The edges of the field oxide may be separated from the nearest gate finger edges by a distance that is adjusted automatically with a computer-aided-design tool and that may be larger than the gate-to-gate spacing. Dummy gate finger structures may be provided to ensure desired levels of stress are produced.

Abstract: A method to design an IC is disclosed to provide a uniform deposition of strain-inducing composites is disclosed. The method to design the IC comprises, determining a total strain-inducing deposition area on an IC design. Then, the total strain inducing deposition area is compared with a predefined size. A dummy diffusion area is modified to increase the total strain-inducing deposition area, when the total strain-inducing deposition area is below the predefined size. Finally, the strain-inducing deposition area is optimized. A method to manufacture the IC and the IC is also disclosed.

Abstract: In an illustrative embodiment, holes are formed in an insulating layer where the gates of NMOS and PMOS transistors are to be formed; and a hard mask spacer layer is formed on the exposed surfaces. Next, spacers are formed on the sidewalls of the holes by anisotropically etching the spacer layer to remove the portion of the spacer layer exposed at the bottom of each hole while leaving some of the spacer layer formed on the sidewalls of the holes. A high-k dielectric layer is then formed between the spacers; and a metal layer is formed on the high-k dielectric layer. Bulk metal layer is then formed on the metal layer. Chemical mechanical polishing is performed to remove the bulk gate metal down to the insulating layer, thereby isolating individual NMOS and PMOS gate structures.

Abstract: Integrated circuits containing transistors are provided. A transistor may include a gate structure formed over an associated well region. The well region may be actively biased and may serve as a body terminal. The well region of one transistor may be formed adjacent to a gate structure of a neighboring transistor. If the gate structure of the neighboring transistor and the well region of the one transistor are both actively biased and are placed close to one another, substantial leakage may be generated. Computer-aided design tools may be used to identify actively driven gate terminals and well regions and may be used to determine whether each gate-well pair is spaced sufficiently far from one another. If a gate-well pair is too close, the design tools may locate an existing gate cut layer and extend the existing gate cut layer to cut the actively driven gate structure.

Abstract: An integrated circuit may include a substrate in which transistors are formed. The transistors may be associated with blocks of circuitry. Some of the blocks of circuitry may be configured to reduce leakage current. A selected subset of the blocks of circuitry may be selectively heated to reduce the channel length of their transistors through dopant diffusion and thereby strengthen those blocks of circuitry relative to the other blocks of circuitry. Selective heating may be implemented by coating the blocks of circuitry on the integrated circuit with a patterned layer of material such as a patterned anti-reflection coating formed of amorphous carbon or a reflective coating. During application of infrared light, the coated and uncoated areas will rise to different temperatures, selectively strengthening desired blocks of circuitry on the integrated circuit.

Abstract: An insulating layer is formed on a semiconductor substrate; and holes are patterned in the insulating layer where transistor gates are to be formed. A hard mask spacer layer is formed on the upper surface of the insulating layer and the holes. Next, the spacer layer is anisotropically etched to remove the portion of the spacer layer exposed at the bottom of each hole as well as the portion of the spacer layer on the upper surface of the insulating layer. However, the etching process does not remove all of the portion of the spacer layer formed on the substantially vertical sidewalls of the holes. A high-k dielectric layer is then formed on the remaining vertical portion of the spacer layer and on the exposed upper surfaces of the substrate and the insulating layer. A metal layer is then formed on the high-k dielectric layer; and individual gate structures are completed.

Abstract: A method to design an IC is disclosed to provide a uniform deposition of strain-inducing composites is disclosed. The method to design the IC comprises, determining a total strain-inducing deposition area on an IC design. Then, the total strain inducing deposition area is compared with a predefined size. A dummy diffusion area is modified to increase the total strain-inducing deposition area, when the total strain-inducing deposition area is below the predefined size. Finally, the strain-inducing deposition area is optimized. A method to manufacture the IC and the IC is also disclosed.

Abstract: A transistor may include a semiconductor region such as a rectangular doped silicon well. Gate fingers may overlap the silicon well. The gate fingers may be formed from polysilicon and may be spaced apart from each other along the length of the well by a fixed gate-to-gate spacing. The edges of the well may be surrounded by field oxide. Epitaxial regions may be formed in the well to produce compressive or tensile stress in channel regions that lie under the gate fingers. The epitaxial regions may form source-drain terminals. The edges of the field oxide may be separated from the nearest gate finger edges by a distance that is adjusted automatically with a computer-aided-design tool and that may be larger than the gate-to-gate spacing. Dummy gate finger structures may be provided to ensure desired levels of stress are produced.

Abstract: A method for forming a submicron device includes depositing a hard mask over a first region that includes a polysilicon well of a first dopant type and a gate of a second dopant type and a second region that includes a polysilicon well of a second dopant type and a gate of a first dopant type. The hard mask over the first region is removed. Angled implantation of the first dopant type is performed to form pockets under the gate of the second dopant type.

Abstract: Integrated circuits containing transistors are provided. A transistor may include a gate structure formed over an associated well region. The well region may be actively biased and may serve as a body terminal. The well region of one transistor may be formed adjacent to a gate structure of a neighboring transistor. If the gate structure of the neighboring transistor and the well region of the one transistor are both actively biased and are placed close to one another, substantial leakage may be generated. Computer-aided design tools may be used to identify actively driven gate terminals and well regions and may be used to determine whether each gate-well pair is spaced sufficiently far from one another. If a gate-well pair is too close, the design tools may locate an existing gate cut layer and extend the existing gate cut layer to cut the actively driven gate structure.

Abstract: An access pad is used to provide access to a functional block of an integrated circuit (IC) device. The access pad is formed using dummy metal in an open space in a metallization level that is between a top metallization level and a base level on which the functional block is formed in the IC device. The access pad at the metallization level provides a contact to access an underlying circuit of the functional block so that the functional integrity of the functional block of the IC device can be verified during probing.

Abstract: An access pad is used to provide access to a functional block of an integrated circuit (IC) device. The access pad is formed using dummy metal in an open space in a metallization level that is between a top metallization level and a base level on which the functional block is formed in the IC device. The access pad at the metallization level provides a contact to access an underlying circuit of the functional block so that the functional integrity of the functional block of the IC device can be verified during probing.

Abstract: Photolithographic reticles are provided that have electrostatic discharge protection features. A photolithographic reticle may be formed from metal structures such as chrome structures on a transparent substrate such as fused silica. Some of the metal structures on the reticle correspond to transistors and other electronic devices on integrated circuits that are fabricated when using the reticles in a step-and-repeat lithography tool. These metal device structures may be susceptible to damage due to electrostatic charge build up during handling of the reticle. To prevent damage, dummy ring structures are formed in the vicinity of device structures. The dummy ring structures may be constructed to be more sensitive to electrostatic discharge than the device structures, so that in the event of an electrostatic discharge, damage is confined to portions of the reticle that are not critical.

Abstract: An access pad is used to provide access to a functional block of an integrated circuit (IC) device. The access pad is formed using dummy metal in an open space in a metallization level that is between a top metallization level and a base level on which the functional block is formed in the IC device. The access pad at the metallization level provides a contact to access an underlying circuit of the functional block so that the functional integrity of the functional block of the IC device can be verified during probing.

Abstract: A method for forming a submicron device includes depositing a hard mask over a first region that includes a polysilicon well of a first dopant type and a gate of a second dopant type and a second region that includes a polysilicon well of a second dopant type and a gate of a first dopant type. The hard mask over the first region is removed. Angled implantation of the first dopant type is performed to form pockets under the gate of the second dopant type.

Abstract: Photolithographic reticles are provided that have electrostatic discharge protection features. A photolithographic reticle may be formed from metal structures such as chrome structures on a transparent substrate such as fused silica. Some of the metal structures on the reticle correspond to transistors and other electronic devices on integrated circuits that are fabricated when using the reticles in a step-and-repeat lithography tool. These metal device structures may be susceptible to damage due to electrostatic charge build up during handling of the reticle. To prevent damage, dummy ring structures are formed in the vicinity of device structures. The dummy ring structures may be constructed to be more sensitive to electrostatic discharge than the device structures, so that in the event of an electrostatic discharge, damage is confined to portions of the reticle that are not critical.