Abstract: Roughly described, methods and systems for improving integrated circuit layouts and fabrication processes in order to better account for stress effects. Dummy features can be added to a layout either in order to improve uniformity, or to relax known undesirable stress, or to introduce known desirable stress. The dummy features can include dummy diffusion regions added to relax stress, and dummy trenches added either to relax or enhance stress. A trench can relax stress by filling it with a stress-neutral material or a tensile strained material. A trench can increase stress by filling it with a compressive strained material. Preferably dummy diffusion regions and stress relaxation trenches are disposed longitudinally to at least the channel regions of N-channel transistors, and transversely to at least the channel regions of both N-channel and P-channel transistors. Preferably stress enhancement trenches are disposed longitudinally to at least the channel regions of P-channel transistors.

Abstract: Roughly described, the invention includes layouts and masks for an integrated circuit, in which the diffusion shape for a transistor includes a transversely extending jog on one or both transversely opposite sides, the jog having inner and outer corners, at least one of which is located relative to the gate conductor longitudinally such that during lithographic printing of the diffusion shape onto the integrated circuit, the corner will round and extend at least partly into the channel region. The invention also includes aspects for a system and method for introducing such jogs, and for an integrated circuit device having a non-rectangular channel region, the channel region being wider where it meets the source region than at some other longitudinal position under the gate.

Abstract: A method for smoothing variations in threshold voltage in an integrated circuit layout. The method begins by identifying recombination surfaces associated with transistors in the layout. Such recombination surfaces are treated to affect the recombination of interstitial atoms adjacent such surfaces, thus minimizing variations in threshold voltage of transistors within the layout.

Abstract: A method for smoothing variations in threshold voltage in an integrated circuit layout. The method begins by identifying recombination surfaces associated with transistors in the layout. Such recombination surfaces are treated to affect the recombination of interstitial atoms adjacent such surfaces, thus minimizing variations in threshold voltage of transistors within the layout.

Abstract: A system that places an integrated circuit (IC) device within an IC chip layout is presented. During operation, the system receives the IC device to be placed within the IC chip layout, wherein the IC chip layout includes one or more continuous rows of diffusion. Next, the system places the IC device within a continuous row of diffusion. The system then determines whether the IC device is to be electrically isolated from other IC devices. If so, the system inserts one or more isolation devices within the continuous row of diffusion so that the IC device can be electrically isolated from other IC devices. The system then biases the one or more isolation device so that the IC device is electrically isolated from other IC devices within the continuous row of diffusion.

Abstract: Roughly described, a method for approximating stress-induced mobility enhancement in a channel region in an integrated circuit layout, including approximating the stress at each of a plurality of sample points in the channel, converting the stress approximation at each of the sample points to a respective mobility enhancement value, and averaging the mobility enhancement values at all the sample points. The method enables integrated circuit stress analysis that takes into account stresses contributed by multiple stress generation mechanisms, stresses having vector components other than along the length of the channel, and stress contributions (including mitigations) due to the presence of other structures in the neighborhood of the channel region under study, other than the nearest STI interfaces. The method also enables stress analysis of large layout regions and even full-chip layouts, without incurring the computation costs of a full TCAD simulation.

Abstract: Improved layouts take better advantage of desirable cap-layer induced transverse and vertical stress. In one aspect, roughly described, a tensile strained cap material overlies the transistor channels in the N-channel diffusion regions but not the P-channel diffusion regions. The material terminates at an edge that is located as far as practical from the N-channel diffusion, toward the P-channel diffusion. In another aspect, roughly described, a gate conductor crosses a P-channel diffusion region and terminates as far as practical beyond the edge without making undesirable electrical contact with any other features of the integrated circuit design, and without overlying any other diffusion regions. A compressively strained cap layer overlies the P-channel diffusion. In yet another aspect, roughly described, a gate conductor crosses an N-channel diffusion and extends by as short a distance as practical before terminating or turning. A tensile strained cap material overlies the N-channel diffusion.

Abstract: Improved layouts take better advantage of desirable cap-layer induced transverse and vertical stress. In one aspect, roughly described, a tensile strained cap material overlies the transistor channels in the N-channel diffusion regions but not the P-channel diffusion regions. The material terminates at an edge that is located as far as practical from the N-channel diffusion, toward the P-channel diffusion. In another aspect, roughly described, a gate conductor crosses a P-channel diffusion region and terminates as far as practical beyond the edge without making undesirable electrical contact with any other features of the integrated circuit design, and without overlying any other diffusion regions. A compressively strained cap layer overlies the P-channel diffusion. In yet another aspect, roughly described, a gate conductor crosses an N-channel diffusion and extends by as short a distance as practical before terminating or turning. A tensile strained cap material overlies the N-channel diffusion.

Abstract: A method for suppressing the formation of leakage-promoting defects in a crystal lattice following dopant implantation in the lattice. The process provides a compressive layer of atoms, these atoms having a size greater than that of the lattice member atoms. The lattice is then annealed for a time sufficient for interstitial defect atoms to be emitted from the compressive layer, and in that manner energetically stable defects are formed in the lattice at a distance from the compressive layer.

Abstract: Roughly described, a method for approximating stress-induced mobility enhancement in a channel region in an integrated circuit layout, including approximating the stress at each of a plurality of sample points in the channel, converting the stress approximation at each of the sample points to a respective mobility enhancement value, and averaging the mobility enhancement values at all the sample points. The method enables integrated circuit stress analysis that takes into account stresses contributed by multiple stress generation mechanisms, stresses having vector components other than along the length of the channel, and stress contributions (including mitigations) due to the presence of other structures in the neighborhood of the channel region under study, other than the nearest STI interfaces. The method also enables stress analysis of large layout regions and even full-chip layouts, without incurring the computation costs of a full TCAD simulation.

Abstract: Roughly described, a method for approximating stress-induced mobility enhancement in a channel region in an integrated circuit layout, including approximating the stress at each of a plurality of sample points in the channel, converting the stress approximation at each of the sample points to a respective mobility enhancement value, and averaging the mobility enhancement values at all the sample points. The method enables integrated circuit stress analysis that takes into account stresses contributed by multiple stress generation mechanisms, stresses having vector components other than along the length of the channel, and stress contributions (including mitigations) due to the presence of other structures in the neighborhood of the channel region under study, other than the nearest STI interfaces. The method also enables stress analysis of large layout regions and even full-chip layouts, without incurring the computation costs of a full TCAD simulation.

Abstract: Roughly described, a method for approximating stress-induced mobility enhancement in a channel region in an integrated circuit layout, including approximating the stress at each of a plurality of sample points in the channel, converting the stress approximation at each of the sample points to a respective mobility enhancement value, and averaging the mobility enhancement values at all the sample points. The method enables integrated circuit stress analysis that takes into account stresses contributed by multiple stress generation mechanisms, stresses having vector components other than along the length of the channel, and stress contributions (including mitigations) due to the presence of other structures in the neighborhood of the channel region under study, other than the nearest STI interfaces. The method also enables stress analysis of large layout regions and even full-chip layouts, without incurring the computation costs of a full TCAD simulation.

Abstract: Roughly described, a method for approximating stress-induced mobility enhancement in a channel region in an integrated circuit layout, including approximating the stress at each of a plurality of sample points in the channel, converting the stress approximation at each of the sample points to a respective mobility enhancement value, and averaging the mobility enhancement values at all the sample points. The method enables integrated circuit stress analysis that takes into account stresses contributed by multiple stress generation mechanisms, stresses having vector components other than along the length of the channel, and stress contributions (including mitigations) due to the presence of other structures in the neighborhood of the channel region under study, other than the nearest STI interfaces. The method also enables stress analysis of large layout regions and even full-chip layouts, without incurring the computation costs of a full TCAD simulation.

Abstract: Roughly described, methods and systems for improving integrated circuit layouts and fabrication processes in order to better account for stress effects. Dummy features can be added to a layout either in order to improve uniformity, or to relax known undesirable stress, or to introduce known desirable stress. The dummy features can include dummy diffusion regions added to relax stress, and dummy trenches added either to relax or enhance stress. A trench can relax stress by filling it with a stress-neutral material or a tensile strained material. A trench can increase stress by filling it with a compressive strained material. Preferably dummy diffusion regions and stress relaxation trenches are disposed longitudinally to at least the channel regions of N-channel transistors, and transversely to at least the channel regions of both N-channel and P-channel transistors. Preferably stress enhancement trenches are disposed longitudinally to at least the channel regions of P-channel transistors.

Abstract: Roughly described, methods and systems for improving integrated circuit layouts and fabrication processes in order to better account for stress effects. Dummy features can be added to a layout either in order to improve uniformity, or to relax known undesirable stress, or to introduce known desirable stress. The dummy features can include dummy diffusion regions added to relax stress, and dummy trenches added either to relax or enhance stress. A trench can relax stress by filling it with a stress-neutral material or a tensile strained material. A trench can increase stress by filling it with a compressive strained material. Preferably dummy diffusion regions and stress relaxation trenches are disposed longitudinally to at least the channel regions of N-channel transistors, and transversely to at least the channel regions of both N-channel and P-channel transistors. Preferably stress enhancement trenches are disposed longitudinally to at least the channel regions of P-channel transistors.

Abstract: Roughly described, a method for approximating stress-induced mobility enhancement in a channel region in an integrated circuit layout, including approximating the stress at each of a plurality of sample points in the channel, converting the stress approximation at each of the sample points to a respective mobility enhancement value, and averaging the mobility enhancement values at all the sample points. The method enables integrated circuit stress analysis that takes into account stresses contributed by multiple stress generation mechanisms, stresses having vector components other than along the length of the channel, and stress contributions (including mitigations) due to the presence of other structures in the neighborhood of the channel region under study, other than the nearest STI interfaces. The method also enables stress analysis of large layout regions and even full-chip layouts, without incurring the computation costs of a full TCAD simulation.

Abstract: An automated method for estimating layout-induced variations in threshold voltage in an integrated circuit layout. The method begins with the steps of selecting a diffusion area within the layout for analysis. Then, the system identifies Si/STI edges on the selected area as well as channel areas and their associated gate/Si edges. Next, the threshold voltage variations in each identified channel area are identified, which requires further steps of calculating threshold voltage variations due to effects in a longitudinal direction; calculating threshold voltage variations due to effects in a transverse direction; and combining the longitudinal and transverse variations to provide an overall variation. Finally, a total variation is determined by combining variations from individual channel variations.

Abstract: Roughly described, methods and systems for improving integrated circuit layouts and fabrication processes in order to better account for stress effects. Dummy features can be added to a layout either in order to improve uniformity, or to relax known undesirable stress, or to introduce known desirable stress. The dummy features can include dummy diffusion regions added to relax stress, and dummy trenches added either to relax or enhance stress. A trench can relax stress by filling it with a stress-neutral material or a tensile strained material. A trench can increase stress by filling it with a compressive strained material. Preferably dummy diffusion regions and stress relaxation trenches are disposed longitudinally to at least the channel regions of N-channel transistors, and transversely to at least the channel regions of both N-channel and P-channel transistors. Preferably stress enhancement trenches are disposed longitudinally to at least the channel regions of P-channel transistors.

Abstract: A method for smoothing variations in threshold voltage in an integrated circuit layout. The method begins by identifying recombination surfaces associated with transistors in the layout.

Abstract: An automated method for estimating layout-induced variations in threshold voltage in an integrated circuit layout. The method begins with the steps of selecting a diffusion area within the layout for analysis. Then, the system identifies Si/STI edges on the selected area as well as channel areas and their associated gate/Si edges. Next, the threshold voltage variations in each identified channel area are identified, which requires further steps of calculating threshold voltage variations due to effects in a longitudinal direction; calculating threshold voltage variations due to effects in a transverse direction; and combining the longitudinal and transverse variations to provide an overall variation. Finally, a total variation is determined by combining variations from individual channel variations.