Abstract: A method for fabricating an interconnect function array includes forming a first plurality of conductive lines on a substrate, forming an insulator layer over the first plurality of conductive lines and the substrate, removing portions of the insulator layer to define cavities in the insulator layer that expose portions of the substrate and the first plurality of conductive lines, wherein the removal of the portions of the insulator layer results in a substantially random arrangement of cavities exposing portions of the substrate and the first plurality of conductive lines, depositing a conductive material in the cavities, and forming a second plurality of conductive lines on portions of the conductive material in the cavities and the insulator layer.

Abstract: A physical unclonable function (PUF) semiconductor device includes a semiconductor substrate extending along a first direction to define a length and a second direction opposite the first direction to define a thickness. At least one pair of semiconductor structures is formed on the semiconductor substrate. The semiconductor structures include a first semiconductor structure and a second semiconductor structure. The first semiconductor structure includes a first gate dielectric layer having a first shape that defines a first threshold voltage. The second semiconductor structure includes a second gate dielectric layer having a second dielectric shape that is reversely arranged with respect to the first shape and that defines a second threshold voltage different from the first threshold voltage.

Abstract: A back end of the line (BEOL) fuse structure having a stack of vias. The stacking of vias leads to high aspect ratios making liner and seed coverage inside the vias poorer. The weakness of the liner and seed layers leads to a higher probability of electromigration (EM) failure. The fuse structure addresses failures due to poor liner and seed coverage. Design features permit determining where failures occur, determining the extent of the damaged region after fuse programming and preventing further propagation of the damaged dielectric region.

Abstract: A method for fabricating an interconnect function array includes forming a first plurality of conductive lines on a substrate, forming an insulator layer over the first plurality of conductive lines and the substrate, removing portions of the insulator layer to define cavities in the insulator layer that expose portions of the substrate and the first plurality of conductive lines, wherein the removal of the portions of the insulator layer results in a substantially random arrangement of cavities exposing portions of the substrate and the first plurality of conductive lines, depositing a conductive material in the cavities, and forming a second plurality of conductive lines on portions of the conductive material in the cavities and the insulator layer.

Abstract: A back end of the line (BEOL) fuse structure having a stack of vias. The stacking of vias leads to high aspect ratios making liner and seed coverage inside the vias poorer. The weakness of the liner and seed layers leads to a higher probability of electromigration (EM) failure. The fuse structure addresses failures due to poor liner and seed coverage. Design features permit determining where failures occur, determining the extent of the damaged region after fuse programming and preventing further propagation of the damaged dielectric region.

Abstract: A wafer probing system includes a probe card assembly having a plurality of individual probe structures configured make contact with a semiconductor wafer mounted on a motor driven wafer chuck, with each probe structure configured with a pressure sensing unit integrated therewith; and a controller configured to drive the probe card assembly with one or more piezoelectric driver units response to feedback from the pressure sensing units of the individual probe structures.

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 method for fabricating an interconnect function array includes forming a first plurality of conductive lines on a substrate, forming an insulator layer over the first plurality of conductive lines and the substrate, removing portions of the insulator layer to define cavities in the insulator layer that expose portions of the substrate and the first plurality of conductive lines, wherein the removal of the portions of the insulator layer results in a substantially random arrangement of cavities exposing portions of the substrate and the first plurality of conductive lines, depositing a conductive material in the cavities, and forming a second plurality of conductive lines on portions of the conductive material in the cavities and the insulator layer.

Abstract: The present disclosure generally provides for integrated circuit (IC) structures with through-semiconductor vias (TSV). In an embodiment, an IC structure may include a through-semiconductor via (TSV) embedded in a substrate, the TSV having a cap; a dielectric layer adjacent to the substrate; a metal layer adjacent to the dielectric layer; a plurality of vias each embedded within the dielectric layer and coupling the metal layer to the cap of the TSV at respective contact points, wherein the plurality of vias is configured to create a substantially uniform current density throughout the TSV.

Abstract: The present disclosure generally provides for an integrated circuit (IC) structure with a TSV, and methods of manufacturing the IC structure and the TSV. An IC structure according to embodiments of the present invention may include a through-semiconductor via (TSV) embedded within a substrate, the TSV having an axial end; and a metal cap contacting the axial end of the TSV, wherein the metal cap has a greater electrical resistivity than the TSV.

Abstract: An e-fuse structure including a fuse link having a first region made of a first conductor and a second region made of a second conductor. The first conductor and the second conductor are in the same wiring level. The first conductor has a higher electrical resistance than the second conductor. The first conductor has a higher resistance to electromigration than the second conductor. The first region and the second region have a common width. The length of the first region is longer than the length of the second region.

Abstract: An method including forming a back end of the line (BEOL) wiring portion directly on top of a semiconductor base portion, the BEOL wiring portion including a plurality of layers of a metallic material and a dielectric material and excluding a semiconductor material, forming a through-substrate via through the BEOL wiring portion and the semiconductor base portion, forming an electronic fuse in the BEOL wiring portion adjacent to the through-substrate via, and forming a guard ring in the BEOL wiring portion surrounding the through-substrate via and the electronic fuse in the BEOL wiring portion, the through-substrate via in the semiconductor base portion being free from the guard ring.

Abstract: A device and method for evaluating reliability of a semiconductor chip structure built by a manufacturing process includes a test structure built in accordance with a manufacturing process. The test structure is thermal cycled and the yield of the test structure is measured. The reliability of the semiconductor chip structure built by the manufacturing process is evaluated based on the yield performance before the thermal cycling.

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: 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 on-chip frequency calibration apparatus is described. A ring oscillator generates a clock signal. A trimmable resistor is coupled to the ring oscillator. A frequency detector detects the frequency of the clock signal generated from the ring oscillator. The frequency detector includes a frequency divider component that divides the frequency of the clock signal by a predetermined number to derive an output signal having a pulse duration that is equal to at least one period of the clock signal, a capacitor, a capacitor charging current source, and a capacitor charge transistor directs a charging current generated from the capacitor charging current source to the capacitor as a function of the output signal generated from the frequency divider component. A resistor trimming unit trims the trimmable resistor in response to determining that the frequency detected by the frequency detector is less than a target frequency threshold.

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 structure, such as a wafer, chip, IC, design structure, etc., includes a through silicon via (TSV) and an electromigration (EM) monitor. The TSV extends completely through a semiconductor chip and the EM monitor includes a plurality of EM wires proximately arranged about the TSV perimeter. An EM testing method includes forcing electrical current through EM monitor wiring arranged in close proximity to the perimeter of the TSV, measuring an electrical resistance drop across the EM monitor wiring, determining if an electrical short exists between the EM monitor wiring and the TSV from the measured electrical resistance, and/or determining if an early electrical open or resistance increase exists within the EM monitoring wiring due to TSV induced proximity effect.

Abstract: A method for fabricating an interconnect function array includes forming a first plurality of conductive lines on a substrate, forming an insulator layer over the first plurality of conductive lines and the substrate, removing portions of the insulator layer to define cavities in the insulator layer that expose portions of the substrate and the first plurality of conductive lines, wherein the removal of the portions of the insulator layer results in a substantially random arrangement of cavities exposing portions of the substrate and the first plurality of conductive lines, depositing a conductive material in the cavities, and forming a second plurality of conductive lines on portions of the conductive material in the cavities and the insulator layer.

Abstract: A set of physical unclonable function (PUF) cells is configured with a set of capacitive devices in an integrated circuit (IC). A subset of PUF cells includes a corresponding subset of capacitive devices that have failed during fabrication. A charging current sufficient to charge an operational capacitive device in a PUF cell is sent to the set of PUF cells. A determination is made whether an output voltage of a PUF cell exceeds a threshold. When the output voltage exceeding the threshold, a logic value of 1 is produced at a position in a bit-string. The determination and the producing is repeated for each PUF cell in the set to output a bit-string, which includes 1s and 0s in random positions. The bit-string is used in a security application as a random stable value owing to a random pattern of 1s and 0s present in the bit-string.