Abstract: An organic material layer is lithographically patterned to include a linear array portion of lines and spaces. In one embodiment, the organic material layer can be an organic planarization layer that is patterned employing a photoresist layer, which is consumed during patterning of the organic planarization layer. Volume expansion of the organic planarization layer upon exposure to a halogen-including gas causes portions of the linear array to collapse at random locations. In another embodiment, the height of the photoresist layer is selected such that the linear array portion of the photoresist layer is mechanically unstable and produces random photoresist collapses. The pattern including random modifications due to the collapse of the organic material layer is transferred into an underlying layer to generate an array of conductive material lines with random electrical disruption of shorts or opens. The structure with random shorts can be employed as a physical unclonable function.

Abstract: A capacitor structure can include a parallel connection of a plurality of trench capacitors. First nodes of the plurality of trench capacitors are electrically tied to provide a first node of the capacitor structure. Second nodes of the plurality of trench capacitors are electrically tied together through at least one programmable electrical connection at a second node of the capacitor structure. Each programmable electrical connection can include at least one of a programmable electrical fuse and a field effect transistor, and can disconnect a corresponding trench capacitor temporarily or permanently. The total capacitance of the capacitor structure can be tuned by programming, temporarily or permanently, the at least one programmable electrical connection.

Abstract: A Physical Unclonable Function (PUF) semiconductor device includes a semiconductor substrate, and a well formed in the semiconductor substrate. The well includes a first region having a first concentration of ions, and at least one second region having a second concentration that is less than the first concentration. First and second FETs are formed on the well. The first and second FETs have a voltage threshold mismatch with respect to one another based on the first region and the at least one second region.

Abstract: A through-substrate via (TSV) structure includes at least two electrically conductive via segments embedded in a substrate and separated from each other by an electrically conductive barrier layer therebetween. The length of each individual conductive via segment is typically equal to, or less than, the Blech length of the conductive material so that the stress-induced back flow force, generated by each conductive barrier layer, cancels the electromigration force in each conductive via segment. Consequently, the TSV structures are immune to electromigration, and provide reliable electrical connections among a chips stacked in 3 dimensions.

Abstract: A set of first substrate and second substrate are manufactured with a built-in N-fold rotational symmetry around the center axis of each substrate, wherein N is an integer greater than 1. A set of N different interposers is provided such that an i-th interposer provides electrical connection between the first substrate and the second substrate with a rotational angle of (i?1)/N×2?. The first and second substrates are tested with each of the N different interposers therebetween. Once the rotational angle that provides the highest stacked chip yield is determined, the first and the second substrates can be bonded with an azimuthal rotation that provides the highest stacked chip yield.

Abstract: A test structure used to determine reliability performance includes a patterned metallization structure having multiple interfaces, which provide stress risers. A dielectric material surrounds the metallization structure, where a mismatch in coefficients of thermal expansion (CTE) between the metallization structure and the surrounding dielectric material exist such that a thermal strain value is provided to cause failures under given stress conditions as a result of CTE mismatch to provide a yield indicative of reliability for a manufacturing design.

Abstract: A method of forming a wiring structure for an integrated circuit device includes forming a first metal line within an interlevel dielectric (ILD) layer, and forming a second metal line in the ILD layer adjacent the first metal line; masking selected regions of the first and second metal lines; selectively plating metal cap regions over exposed regions of the first and second metal lines at periodic intervals such that a spacing between adjacent metal cap regions of an individual metal line corresponds to a critical length, L, at which a back stress gradient balances an electromigration force in the individual metal line, so as to suppress mass transport of electrons; and wherein the metal cap regions of the first metal line are formed at staggered locations with respect to the metal cap regions of the second metal line, along a common longitudinal axis.

Abstract: A method of forming a wiring structure for an integrated circuit device includes forming a first metal line within an interlevel dielectric (ILD) layer, and forming a second metal line in the ILD layer adjacent the first metal line; masking selected regions of the first and second metal lines; selectively plating metal cap regions over exposed regions of the first and second metal lines at periodic intervals such that a spacing between adjacent metal cap regions of an individual metal line corresponds to a critical length, L, at which a back stress gradient balances an electromigration force in the individual metal line, so as to suppress mass transport of electrons; and wherein the metal cap regions of the first metal line are formed at staggered locations with respect to the metal cap regions of the second metal line, along a common longitudinal axis.

Abstract: The present invention relates generally to flip chip technology and more particularly, to a method and structure for fabricating a mechanically anchored controlled collapse chip connection (C4) pad on a semiconductor structure. In an embodiment, a method is disclosed that may include forming a bonding pad having one or more anchor regions that extend into a semiconductor structure and may inhibit the bonding pad from physically separating from the TSV during temperature fluctuations.

Abstract: Embodiments of the invention include a semiconductor structure containing a back end of line randomly patterned interconnect structure for implementing a physical unclonable function (PUF), a method for forming the semiconductor device, and a circuit for enabling the interconnect structure to implement the physical unclonable function. The method includes forming a semiconductor substrate and a dielectric layer on the substrate. The randomly patterned interconnect structure is formed in the dielectric layer. The random pattern of the interconnect structure is used to implement the physical unclonable function and is a result of defect occurrences during the manufacturing of the semiconductor structure. The circuit includes n-channel and p-channel metal oxide semiconductor field effect transistors (MOSFETs) and the randomly patterned interconnect structure, which acts as electrical connections between the MOSFETs.

Abstract: A method of forming a wiring structure for an integrated circuit device includes forming a first metal line within an interlevel dielectric (ILD) layer, and forming a second metal line in the ILD layer adjacent the first metal line; masking selected regions of the first and second metal lines; selectively plating metal cap regions over exposed regions of the first and second metal lines at periodic intervals such that a spacing between adjacent metal cap regions of an individual metal line corresponds to a critical length, L, at which a back stress gradient balances an electromigration force in the individual metal line, so as to suppress mass transport of electrons; and wherein the metal cap regions of the first metal line are formed at staggered locations with respect to the metal cap regions of the second metal line, along a common longitudinal axis.

Abstract: Embodiments of the invention include a semiconductor structure containing a back end of line randomly patterned interconnect structure for implementing a physical unclonable function (PUF), a method for forming the semiconductor device, and a circuit for enabling the interconnect structure to implement the physical unclonable function. The method includes forming a semiconductor substrate and a dielectric layer on the substrate. The randomly patterned interconnect structure is formed in the dielectric layer. The random pattern of the interconnect structure is used to implement the physical unclonable function and is a result of defect occurrences during the manufacturing of the semiconductor structure. The circuit includes n-channel and p-channel metal oxide semiconductor field effect transistors (MOSFETs) and the randomly patterned interconnect structure, which acts as electrical connections between the MOSFETs.

Abstract: An organic material layer is lithographically patterned to include a linear array portion of lines and spaces. In one embodiment, the organic material layer can be an organic planarization layer that is patterned employing a photoresist layer, which is consumed during patterning of the organic planarization layer. Volume expansion of the organic planarization layer upon exposure to a halogen-including gas causes portions of the linear array to collapse at random locations. In another embodiment, the height of the photoresist layer is selected such that the linear array portion of the photoresist layer is mechanically unstable and produces random photoresist collapses. The pattern including random modifications due to the collapse of the organic material layer is transferred into an underlying layer to generate an array of conductive material lines with random electrical disruption of shorts or opens. The structure with random shorts can be employed as a physical unclonable function.

Abstract: A through-silicon-via (TSV) structure is formed within a trench located within a semiconductor structure. The TSV structure may include a first electrically conductive liner layer located on an outer surface of the trench and a first electrically conductive structure located on the first electrically conductive liner layer, whereby the first electrically conductive structure partially fills the trench. A second electrically conductive liner layer is located on the first electrically conductive structure, a dielectric layer is located on the second electrically conductive liner layer, while a third electrically conductive liner layer is located on the dielectric layer. A second electrically conductive structure is located on the third electrically conductive liner layer, whereby the second electrically conductive structure fills a remaining opening of the trench.

Abstract: A method including a first interconnect level including a first electrode embedded in a first dielectric layer, a top surface of the first electrode is substantially flush with a top surface of the first dielectric layer, a second interconnect level including a via embedded in a second dielectric layer above the first dielectric layer, a third dielectric layer in direct contact with and separating the first dielectric layer and the second dielectric layer, an entire top surface of the first electrode is in direct physical contact with a bottom surface of the third dielectric layer, and an interface between the first dielectric layer and the third dielectric layer extending from the top surface of the first electrode to the via, the interface including a length less than a minimum width of the via, a bottom surface of the via is in direct physical contact with the first dielectric layer.

Abstract: Embodiments of the present invention provide an apparatus and method for wafer thinning endpoint detection. Embodiments of the present invention utilize through silicon via (TSV) structures formed in the wafer. A specially made wafer handle is bonded to the wafer. Conductive slurry is used in the wafer backside thinning process. The wafer handle provides electrical connectivity to an electrical measurement tool, and conductive posts in the wafer handle are proximal to a test structure on the wafer. A plurality of electrically isolated TSVs is monitored via the electrical measurement tool. When the TSVs are exposed on the backside as a result of thinning, the conductive slurry shorts the electrically isolated TSVs, changing the electrical properties of the plurality of TSVs. The change in electrical properties is detected and used to trigger termination of the wafer backside thinning process.

Abstract: A Physical Unclonable Function (PUF) semiconductor device includes a semiconductor substrate, and a well formed in the semiconductor substrate. The well includes a first region having a first concentration of ions, and at least one second region having a second concentration that is less than the first concentration. First and second FETs are formed on the well. The first and second FETs have a voltage threshold mismatch with respect to one another based on the first region and the at least one second region.

Abstract: A semiconductor article which includes a semiconductor base portion including a semiconductor material; a back end of the line (BEOL) wiring portion on the semiconductor base portion and comprising a plurality of wiring layers having metallic wiring and insulating material, said BEOL wiring portion excluding a semiconductor material; and a guard ring in the BEOL wiring portion and surrounding a structure in the semiconductor chip, the guard ring having a zig-zag configuration.

Abstract: A clock phase shift detector circuit may include a phase detector that receives a first and a second clock signal, whereby the phase detector generates a phase signal based on a phase difference between the first and the second clock signal. A first integrator is coupled to the phase detector, receives the phase signal, and generates an integrated phase signal. A second integrator receives the first clock signal and generates an integrated first clock signal. A comparator is coupled to the first and the second integrator, whereby the comparator receives the integrated phase signal and the integrated first clock signal. The comparator may then generate a control signal that detects a change between the phase difference of the first and the second clock signal and an optimized phase difference based on an amplitude comparison between the integrated phase signal and the integrated first clock signal.

Abstract: A through-silicon via (TSV) capacitive test structure and method of determining TSV depth based on capacitance is disclosed. The TSV capacitive test structure is formed from a plurality of TSV bars that are evenly spaced. A first group of bars are electrically connected to form a first capacitor node, and a second group of bars is electrically connected to form a second capacitor node. The capacitance is measured, and a TSV depth is computed, prior to backside thinning. The computed TSV depth may then be fed to downstream grinding and/or polishing tools to control the backside thinning process such that the semiconductor wafer is thinned such that the backside is flush with the TSV.