Abstract: A method of forming a top via is provided. The method includes forming a sacrificial trench layer and conductive trench plug in an interlayer dielectric (ILD) layer on a conductive line. The method further includes forming a cover layer on the ILD layer, sacrificial trench layer, and conductive trench plug, and forming a sacrificial channel layer and a conductive channel plug on the conductive trench plug. The method further includes removing the cover layer and the ILD layer to expose the sacrificial trench layer and the sacrificial channel layer. The method further includes removing the sacrificial trench layer and the sacrificial channel layer, and forming a barrier layer on the conductive channel plug and conductive trench plug.

Abstract: A method of forming an interconnect structure includes forming at least one second-level interconnect in a sacrificial dielectric layer that is formed on an upper surface of a sacrificial etch stop layer, and removing the sacrificial dielectric layer and the sacrificial etch stop layer while maintaining the at least one second-level interconnect so as to expose an underlying dielectric layer. The method further includes depositing a replacement dielectric layer on an upper surface of the underlying dielectric layer to embed the at least one second-level interconnect in the replacement dielectric layer. Accordingly, an interconnect structure can be formed that includes one or more first-level interconnect in a dielectric layer and one or more second-level interconnects in a replacement dielectric layer stacked on the dielectric layer. The replacement dielectric layer directly contacts the dielectric layer.

Abstract: Embodiments of the present invention are directed to fabrication methods and resulting interconnect structures having a conductive thin metal layer on a top via that promotes the selective growth of the next level interconnect lines (the line above). In a non-limiting embodiment of the invention, a first conductive line is formed in a dielectric layer. A via is formed on the first conductive line and a seed layer is formed on the via and the dielectric layer. A surface of the seed layer is exposed and a second conductive line is deposited onto the exposed surface of the seed layer. In a non-limiting embodiment of the invention, the second conductive line is selectively grown from the seed layer.

Abstract: A method of forming fully aligned top vias is provided. The method includes forming a fill layer on a conductive line, wherein the fill layer is adjacent to one or more vias. The method further includes forming a spacer layer selectively on the exposed surface of the fill layer, wherein the top surface of the one or more vias is exposed after forming the spacer layer. The method further includes depositing an etch-stop layer on the exposed surfaces of the spacer layer and the one or more vias, and forming a cover layer on the etch-stop layer.

Abstract: A computer system interacts with a user with a behavioral state. An activity performed by an entity with a behavioral state is determined. A virtual character corresponding to the entity and performing the determined activity of the entity is generated and displayed. A mental state of the entity responsive to the virtual character is detected. In response to detection of a positive mental state of the entity, one or more natural language terms are provided to the entity corresponding to the activity performed by the virtual character. Embodiments of the present invention further include a method and program product for interacting with a user with a behavioral state in substantially the same manner described above.

Abstract: Embodiments of the invention include a method of forming a multi-layer integrated circuit (IC) structure that includes forming a first dielectric layer. A first interconnect is formed in the first dielectric layer and includes a first top surface, a first bottom surface, and a first sidewall extending from an edge of the first top surface to an edge of the first bottom surface. A second interconnect is formed in the first dielectric layer and includes a second top surface, a second bottom surface, and a second sidewall extending from an edge of the second top surface to an edge of the second bottom surface. A spacing from the edge of the first top surface to the edge of the second top surface is greater than a spacing from the edge of the first bottom surface to the edge of the second bottom surface.

Abstract: Embodiments of the invention include a method of forming a multi-layer integrated circuit (IC) structure that includes forming a first dielectric layer. A first interconnect is formed in the first dielectric layer and includes a first top surface, a first bottom surface, and a first sidewall extending from an edge of the first top surface to an edge of the first bottom surface. A second interconnect is formed in the first dielectric layer and includes a second top surface, a second bottom surface, and a second sidewall extending from an edge of the second top surface to an edge of the second bottom surface. A spacing from the edge of the first top surface to the edge of the second top surface is greater than a spacing from the edge of the first bottom surface to the edge of the second bottom surface.

Abstract: A semiconductor structure includes a first metallization layer disposed on a first etch stop layer. The first metallization layer includes a first conductive line and a second conductive line disposed in a first dielectric layer. The height of the first conductive line is greater than a height of the second conductive line. The semiconductor structure further includes a first via layer having a second dielectric layer disposed on a top surface of the first metallization layer and a first via in the second dielectric layer. The first via is configured to expose a portion of a top surface of the second conductive line. The semiconductor structure further includes a first conductive material disposed in the first via.

Abstract: An article is authenticated by providing a magnetic security mark in the form of an optically-passive randomly-generated nanoscale magnetic pattern. The pattern is pre-imaged and this reference image is uploaded to a secure database along with an identifier for the article such as a serial number. A user of the article verifies its authenticity by scanning it magnetically to obtain a scanned image of the magnetic pattern. The serial number is used to retrieve the previously uploaded reference image which is compared to the scanned image. If the images match, the article's authenticity is confirmed. A single article may have multiple magnetic security marks, each unique, placed at predetermined, non-uniform locations. The magnetic patterns are generated using thin film deposition of yttrium iron garnet. In one embodiment the article is a physical key having additional security features, such as mechanical features and a radio-frequency identification chip.

Abstract: A technique relates to an integrated circuit (IC). The IC includes a conductive line formed on a conductive via, the conductive line being formed though a dielectric material. The IC includes an etch stop layer having one or more extended portions intervening between one or more edge portions of the conductive line and the conductive via, the one or more edge portions being at a periphery of the conductive line and the conductive via, the etch stop layer including a higher dielectric breakdown than the dielectric material. The one or more extended portions of the etch stop layer cause the conductive line to be formed with a bottom part having a reduced dimension than an upper part of the conductive line.

Abstract: A method of forming an interconnect structure includes forming at least one second-level interconnect in a sacrificial dielectric layer that is formed on an upper surface of a sacrificial etch stop layer, and removing the sacrificial dielectric layer and the sacrificial etch stop layer while maintaining the at least one second-level interconnect so as to expose an underlying dielectric layer. The method further includes depositing a replacement dielectric layer on an upper surface of the underlying dielectric layer to embed the at least one second-level interconnect in the replacement dielectric layer. Accordingly, an interconnect structure can be formed that includes one or more first-level interconnect in a dielectric layer and one or more second-level interconnects in a replacement dielectric layer stacked on the dielectric layer. The replacement dielectric layer directly contacts the dielectric layer.

Abstract: Techniques for forming trapezoidal-shaped interconnects are provided. In one aspect, a method for forming an interconnect structure includes: patterning a trench(es) in a dielectric having a V-shaped profile with a rounded bottom; depositing a liner into the trench(es) using PVD which opens-up the trench(es) creating a trapezoidal-shaped profile in the trench(es); removing the liner from the trench(es) selective to the dielectric whereby, following the removing, the trench(es) having the trapezoidal-shaped profile remains in the dielectric; depositing a conformal barrier layer into and lining the trench(es) having the trapezoidal-shaped profile; depositing a conductor into and filling the trench(es) having the trapezoidal-shaped profile over the conformal barrier layer; and polishing the conductor and the conformal barrier layer down to the dielectric. An interconnect structure is also provided.

Abstract: Embodiments of the present invention are directed to fabrication methods and resulting interconnect structures having a conductive thin metal layer on a top via that promotes the selective growth of the next level interconnect lines (the line above). In a non-limiting embodiment of the invention, a first conductive line is formed in a dielectric layer. A via is formed on the first conductive line and a seed layer is formed on the via and the dielectric layer. A surface of the seed layer is exposed and a second conductive line is deposited onto the exposed surface of the seed layer. In a non-limiting embodiment of the invention, the second conductive line is selectively grown from the seed layer.

Abstract: A technique relates to an integrated circuit (IC). The IC includes a conductive line formed on a conductive via, the conductive line being formed though a dielectric material. The IC includes an etch stop layer having one or more extended portions intervening between one or more edge portions of the conductive line and the conductive via, the one or more edge portions being at a periphery of the conductive line and the conductive via, the etch stop layer including a higher dielectric breakdown than the dielectric material. The one or more extended portions of the etch stop layer cause the conductive line to be formed with a bottom part having a reduced dimension than an upper part of the conductive line.

Abstract: A method for fabricating a semiconductor device includes forming one or more layers including at least one of a liner and a barrier along surfaces of a first interlevel dielectric (ILD) layer within a trench, after forming the one or more liners, performing a via etch to form a via opening exposing a first conductive line corresponding to a first metallization level, and forming, within the via opening and on the first conductive line, a barrier-less prefilled via including first conductive material.

Abstract: A method of fabricating an integrated circuit includes forming a first trench such that a portion of the first trench is defined by a portion of a first-type of interconnect and depositing a sacrificial spacer liner in the first trench to cover the portion of the first-type of interconnect element. The method further includes forming a dielectric cap on the sacrificial spacer liner and above the first-type of interconnect element, removing the dielectric cap to expose at least a portion of the first-type of interconnect element, and forming a second-type of interconnect element on the exposed first-type of interconnect element.

Abstract: Methods and systems of navigating within a virtual environment are described. In an example, a processor may generate a portal that includes a set of portal boundaries. The processor may display the portal within a first scene of the virtual environment being displayed on a device. The processor may display a second scene of the virtual environment within the portal boundaries. The processor may receive sensor data indicating a movement of a motion controller. The processor may reposition the portal and the second scene in the first scene based on the sensor data, wherein the first scene remains stationary on the device during the reposition of the portal and the second scene. The processor may translate a location of the portal within the first scene to move the portal towards a user of the device until the second scene replaces the first scene being displayed on the device.

Abstract: A method of forming a top via is provided. The method includes forming a sacrificial trench layer and conductive trench plug in an interlayer dielectric (ILD) layer on a conductive line. The method further includes forming a cover layer on the ILD layer, sacrificial trench layer, and conductive trench plug, and forming a sacrificial channel layer and a conductive channel plug on the conductive trench plug. The method further includes removing the cover layer and the ILD layer to expose the sacrificial trench layer and the sacrificial channel layer. The method further includes removing the sacrificial trench layer and the sacrificial channel layer, and forming a barrier layer on the conductive channel plug and conductive trench plug.

Abstract: A semiconductor device includes a porous dielectric layer including a recessed portion, a conductive layer formed in the recessed portion, and a cap layer formed on the porous dielectric layer and on the conductive layer in the recessed portion, an upper surface of the porous dielectric layer being exposed through a gap in the cap layer.

Abstract: Integrated chips and methods of forming the same include forming a conductive layer to a line height. A dielectric layer is formed over the conductive layer to a via height, with at least one opening that exposes a via region of the conductive layer. A conductive via is formed in the opening having the via height. The conductive layer is patterned to form a conductive line having the line height.