Abstract: A method is presented for incorporating skip vias in a place and route flow of an integrated circuit design. The method includes employing a place and route tool to add the skip vias, each skip via extending through a metallization layer to electrically connect a metal layer above the metallization layer to a metal layer below the metallization layer and, when a violation of a design rule is detected due to the addition of one or more of the skip vias, substituting skip vias that violate the design rule with a standard via.

Abstract: Methods and systems for performing an electronic design. A layout of a via of an electronic design is obtained and a determination is made if the layout of the via satisfies one or more retargeting conditions, at least one of the retargeting conditions being that a first edge of a metal line is within a specified distance from a first edge of the via and a second edge of the metal line is within the specified distance from a second edge of the via, the first edge of the metal line being parallel to the first edge of the via and the second edge of the metal line being parallel to the second edge of the via; and reducing a resistance of the via by the layout of the via is retargeted in response to the retargeting conditions being satisfied.

Abstract: A quantum computing device includes a first chip having a first substrate and one or more qubits disposed on the first substrate. Each of the one or more qubits has an associated resonance frequency. The quantum computing device further includes a second chip having a second substrate and at least one conductive surface disposed on the second substrate opposite the one or more qubits. The at least one conductive surface has at least one dimension configured to adjust the resonance frequency associated with at least one of the one or more qubits to a determined frequency adjustment value.

Abstract: A method for predicting local layout effect in a circuit design pattern includes obtaining a plurality of circuit design patterns, generating layout images from the circuit design patterns, extracting feature vectors from the layout images by processing the layout images in a computer vision machine learning algorithm, comparing the feature vector extracted from a selected layout image to clusters of feature vectors extracted from the layout images, wherein the clusters of feature vectors include an in-range cluster and an outlier cluster, and labelling a circuit design pattern corresponding to the selected layout image, for which threshold voltage has not been experimentally measured, as being an in-range circuit design pattern or an outlier circuit design pattern, in response to the selected layout image respectively correlating with the in-range cluster or with the outlier cluster.

Abstract: A method for predicting local layout effect in a circuit design pattern includes obtaining a plurality of circuit design patterns, generating layout images from the circuit design patterns, extracting feature vectors from the layout images by processing the layout images in a computer vision machine learning algorithm, comparing the feature vector extracted from a selected layout image to clusters of feature vectors extracted from the layout images, wherein the clusters of feature vectors include an in-range cluster and an outlier cluster, and labelling a circuit design pattern corresponding to the selected layout image, for which threshold voltage has not been experimentally measured, as being an in-range circuit design pattern or an outlier circuit design pattern, in response to the selected layout image respectively correlating with the in-range cluster or with the outlier cluster.

Abstract: Horizontal-trench on-chip capacitors are provided. In one aspect, a method of forming a capacitor includes: forming alternating sacrificial/active nanosheets on a wafer; patterning the nanosheets into a fin stack(s); burying the fin stack(s) in an ILD; removing the ILD from a first side of the fin stack(s), forming a first cavity; filling the first cavity with a semiconductor material that interconnects the nanosheets of the active material; implanting ions into the nanosheets, semiconductor material and wafer; removing the ILD from a second side of the fin stack(s) forming a second cavity; selectively removing the nanosheets of the sacrificial material, creating gaps between the nanosheets of the active material; depositing a dielectric into/lining the gaps and second cavity; and filling the gaps and second cavity with a conductor. A capacitor is also provided.

Abstract: A method is presented for incorporating skip vias in a place and route flow of an integrated circuit design. The method includes employing a place and route tool to add the skip vias, each skip via extending through a metallization layer to electrically connect a metal layer above the metallization layer to a metal layer below the metallization layer and, when a violation of a design rule is detected due to the addition of one or more of the skip vias, substituting skip vias that violate the design rule with a standard via.

Abstract: A configuration of wirebonds for reducing cross-talk in a quantum computing chip includes a first wirebond coupling a first conductor of a quantum computing circuit with a first conductor of an external circuit. The embodiment further includes in the configuration a second wirebond coupling a second conductor of the quantum computing circuit with a second conductor of the external circuit, wherein the first wirebond and the second wirebond are separated by a first vertical distance in a direction of a length of the first conductor.

Abstract: A quantum computing device includes a first chip having a first substrate and one or more qubits disposed on the first substrate. Each of the one or more qubits has an associated resonance frequency. The quantum computing device further includes a second chip having a second substrate and at least one conductive surface disposed on the second substrate opposite the one or more qubits. The at least one conductive surface has at least one dimension configured to adjust the resonance frequency associated with at least one of the one or more qubits to a determined frequency adjustment value.

Abstract: Methods and systems for performing an electronic design. A layout of a via of an electronic design is obtained and a determination is made if the layout of the via satisfies one or more retargeting conditions, at least one of the retargeting conditions being that a first edge of a metal line is within a specified distance from a first edge of the via and a second edge of the metal line is within the specified distance from a second edge of the via, the first edge of the metal line being parallel to the first edge of the via and the second edge of the metal line being parallel to the second edge of the via; and reducing a resistance of the via by the layout of the via is retargeted in response to the retargeting conditions being satisfied.

Abstract: Within a layout of a first surface in a flip chip configuration, a bump restriction area is mapped according to a set of bump placement restrictions, wherein a first bump placement restriction specifies an allowed distance range between a bump and a qubit chip element in a layout of the first surface, and wherein a second bump placement restriction specifies an allowed distance range between the bump and a qubit chip element in a layout of a second surface in the flip chip configuration. An electrically conductive material is deposited outside the bump restriction area, to form the bump, wherein the bump comprises an electrically conductive structure that electrically couples a signal between the first surface and the second surface and is positioned according to the set of bump placement restrictions.

Abstract: Horizontal-trench on-chip capacitors are provided. In one aspect, a method of forming a capacitor includes: forming alternating sacrificial/active nanosheets on a wafer; patterning the nanosheets into a fin stack(s); burying the fin stack(s) in an ILD; removing the ILD from a first side of the fin stack(s), forming a first cavity; filling the first cavity with a semiconductor material that interconnects the nanosheets of the active material; implanting ions into the nanosheets, semiconductor material and wafer; removing the ILD from a second side of the fin stack(s) forming a second cavity; selectively removing the nanosheets of the sacrificial material, creating gaps between the nanosheets of the active material; depositing a dielectric into/lining the gaps and second cavity; and filling the gaps and second cavity with a conductor. A capacitor is also provided.

Abstract: A method for manufacturing a semiconductor device includes forming a first field-effect transistor (FET) on a substrate, the first FET comprising a first plurality of channel regions extending in a first direction, and stacking a second FET on the first FET, the second FET comprising a second plurality of channel regions extending in a second direction perpendicular to the first direction, wherein the first FET comprises a first gate region extending in the second direction across the first plurality of channel regions, and the second FET comprises a second gate region extending in the first direction across the second plurality of channel regions.

Abstract: A semiconductor structure includes a three-dimensional stacked transistor structure including first and second field-effect transistors of a first type at a first vertical level and third and fourth field-effect transistors of a second type at a second vertical level disposed over the first vertical level. The semiconductor structure also includes a first gate structure shared between the first and second field-effect transistors at the first vertical level, a second gate structure shared between the third and fourth field-effect transistors at the second vertical level, and a gate contact shared by the first and second gate structures. The wherein the first and second gate structures are vertically aligned with another in a layout of the three-dimensional stacked transistor structure between source drain/regions of the first, second, third and fourth field-effect transistors.

Abstract: First lithography and etching are carried out on a semiconductor structure to provide a first intermediate semiconductor structure having a first set of surface features corresponding to a first portion of desired fin formation mandrels. Second lithography and etching are carried out on the first intermediate structure, using a second mask, to provide a second intermediate semiconductor structure having a second set of surface features corresponding to a second portion of the mandrels. The second set of surface features are unequally spaced from the first set of surface features and/or the features have different pitch. The fin formation mandrels are formed in the second intermediate semiconductor structure using the first and second sets of surface features; spacer material is deposited over the mandrels and is etched back to form a third intermediate semiconductor structure having a fin pattern. Etching is carried out on same to produce the fin pattern.

Abstract: A method for detecting hotspots in physical design layout patterns includes receiving a given physical design layout pattern, utilizing a hotspot detection model to detect one or more potential hotspots in the given physical design layout pattern, and performing a verification to determine whether a given potential hotspot of the one or more potential hotspots detected by the hotspot detection model comprises a real hotspot or a nonexistent hotspot. The method also includes, responsive to determining that the given potential hotspot comprises an actual hotspot, modifying the given physical design layout pattern to remove the actual hotspot. The method further includes, responsive to determining that the given potential hotspot comprises a nonexistent hotspot, augmenting the hotspot detection model with additional training data generated based on the nonexistent hotspot.

Abstract: A system, a computer program product, and method for physically fabricating an electronic circuit using design space exploration as part of a design process is described. The method begins with defining a plurality of design space parameters to be tuned along with parameter ranges for each of the plurality of design space parameters. Next an output target to be optimized is defined. A series of one or more test mask shapes are generated to appear on a photo mask using the plurality of design space parameters. A simulation of a post lithography or etch on the series of one or more test mask shapes is performed to produce simulation output values. Next, the simulation output values and corresponding design space parameters are fed into to a Bayesian inference algorithm for assessment and identification of a next combination of design space parameters to investigate.

Abstract: Techniques for designing application or algorithm specific quantum computing circuits for particular applications or algorithms are presented. A design component can comprise an extractor component that can extract qubit pairs determined to satisfy a defined threshold potential of having to use a direct connection between each other in a quantum circuit design based on analysis of an application or algorithm; and a design management component (DMC) that can determine a circuit design of the quantum circuit to use for the application or algorithm based on analysis of characteristics associated with the qubit pairs. DMC can sort the qubit pairs by weighting schemes and the characteristics, comprising the number of affecting downstream qubits, the number of two-qubit gate operations between qubit pairs, and/or whether a qubit pair affects a measurement. Based on the sorting, DMC selects highest ranking qubit pairs to assign a direct connection.

Abstract: A method for detecting hotspots in physical design layout patterns includes receiving a given physical design layout pattern, utilizing a hotspot detection model to detect one or more potential hotspots in the given physical design layout pattern, and performing verification to determine whether a given one of the potential hotspots detected by the hotspot detection model comprises a real hotspot or a nonexistent hotspot. The method also includes, responsive to determining that the given potential hotspot comprises an actual hotspot, modifying the given physical design layout pattern to remove the actual hotspot. The method further includes, responsive to determining that the given potential hotspot comprises a nonexistent hotspot, augmenting the hotspot detection model with additional training data generated based on the nonexistent hotspot.

Abstract: A technique for optimizing integrated circuit (IC) designs based on interaction between multiple integration design rules is provided. For a plurality of IC features, total risk values are determined based on multiple integration design rules. IC features are ordered based on the total risk values. IC features having the highest total risk values are selected based on a threshold count. An IC design is clipped around the high-risk IC features. An overall failure rate is simulated for the clipped area. If the overall failure rate exceeds a threshold, a predicted failure rate for each design rule that applies to IC features within the clipped area is calculated. A high-risk design rule is identified based on the predicted failure rates. The IC design is modified such that a difference between a design rule value of the high-risk design rule and a corresponding design value is reduced.