Abstract: An interconnect structure for an integrated circuit (IC) device includes a metal line formed within a dielectric layer, the metal line having one or more vertical diffusion barriers therein; wherein the one or more vertical diffusion barriers correspond to a liner material of a via formed above the metal line, with the via extending completely through a thickness of the metal line such that a bottom most portion of the via comprises a portion of the metal line

Abstract: A method of recovering gain in a bipolar transistor includes: providing a bipolar transistor including an emitter, a collector, and a base disposed between junctions at the emitter and the collector; reverse biasing the junction disposed between the emitter and the base with an operational voltage and for an operational time period, so that a current gain ? of the transistor is degraded; idling the transistor, and generating a repair current Ibr into the base, while forward biasing the junction disposed between the emitter and the base with a first repair voltage (VEBR), and while at least partly simultaneously reverse biasing the junction disposed between the collector and the base with a second repair voltage (VCBR), for a repair time period (TR), so that the gain is at least party recovered; wherein VEBR, VCBR and TR have the proportional relationship: TR ? (??)2×exp [1/(Tam+Rth×le×VCER)], VCER=VBER+VCBR, and le=?×Ibr, ? is the normal current gain of the transistor, ?? is the target recovery gain of the tr

Abstract: A method of recovering gain in a bipolar transistor includes: providing a bipolar transistor including an emitter, a collector, and a base disposed between junctions at the emitter and the collector; reverse biasing the junction disposed between the emitter and the base with an operational voltage and for an operational time period, so that a current gain ? of the transistor is degraded; idling the transistor, and generating a repair current Ibr into the base, while forward biasing the junction disposed between the emitter and the base with a first repair voltage (VEBR), and while at least partly simultaneously reverse biasing the junction disposed between the collector and the base with a second repair voltage (VCBR), for a repair time period (TR), so that the gain is at least party recovered; wherein VEBR, VCBR and TR have the proportional relationship: TR ? (??)2×exp [1/(Tam+Rth×1e×VCER], VCER=VBER+VCBR, and 1e=?×Ibr, ? is the normal current gain of the transistor, ?? is the target recovery gain of the tra

Abstract: A modularized interposer includes a plurality of interposer units that are assembled to provide a complete set of electrical connections between two semiconductor chips. At least some of the plurality of interposer units can be replaced with other interposer units having an alternate configuration to enable selection of different functional parts of semiconductor chips to be connected through the modularized interposer. Bonding structures, connected to conductive metal pads located at peripheries of neighboring interposer units and an overlying or underlying portion of a semiconductor chip, can provide electrical connections between the neighboring interposer units. The interposer units can be provided by forming through-substrate vias (TSV's) in a substrate, forming patterned conductive structures on the substrate, and cutting the substrate into interposers.

Abstract: The invention comprises a 3D chip stack with an intervening thermoelectric coupling (TEC) plate. Through silicon vias in the 3D chip stack transfer electronic signals among the chips in the 3D stack, power the TEC plate, as well as distribute heat in the stack from hotter chips to cooler chips.

Abstract: An accelerated failure indicator embedded on a semiconductor chip includes an insulating region; a circuit located inside the insulating region; a heating element located inside the insulating region, the heating element configured to heat the circuit to a temperature higher than an operating temperature of the semiconductor chip; and a reliability monitor configured to monitor the circuit for degradation, and further configured to trigger an alarm in the event that the degradation of the circuit exceeds a predetermined threshold. A method of operating an accelerated failure indicator embedded on a semiconductor chip includes determining an operating temperature of the semiconductor chip; heating a circuit located inside an insulating region of the accelerated failure indicator to a temperature higher than the determined operating temperature; monitoring the circuit for degradation; and triggering an alarm in the event that the degradation of the circuit exceeds a predetermined threshold.

Abstract: Through silicon vias (TSVs) in silicon chips are both programmable and non-programmable. The programmable TSVs may employ metal/insulator/metal structures to switch from an open to shorted condition with programming carried out by complementary circuitry on two adjacent chips in a multi-story chip stack.

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: One or more multilayer back side metallurgy (BSM) stack structures are formed on thru-silicon-vias (TSV). The multiple layers of metal may include an adhesion layer of chromium on the semiconductor wafer back side, a conductive layer of copper, diffusion barrier layer of nickel and a layer of nobel metal, such as, gold. To prevent edge attack of copper after dicing, the layer of nickel is formed to seal the copper edge. To also prevent edge attack of the layer of nickel after dicing, the layer of gold is formed to seal both the layer of copper and the layer of nickel.

Abstract: A test structure for a through-silicon-via (TSV) in a semiconductor chip includes a first contact, the first contact being electrically connected to a first TSV; and a second contact, wherein the first contact, second contact, and the first TSV form a first channel, and a depth of the first TSV is determined based on a resistance of the first channel. A method of determining a depth of a through-silicon-via (TSV) in a semiconductor chip includes etching a first TSV into the semiconductor chip; forming a first channel, the first channel comprising the first TSV, a first contact electrically connected to the first TSV, and a second contact; connecting a current source to the second contact; determining a resistance across the first channel; and determining a depth of the first TSV based on the resistance of the first channel.

Abstract: An apparatus is provided and includes a thermally isolated device under test to which first and second voltages are sequentially applied, a local heating element to impart first and second temperatures to the device under test substantially simultaneously while the first and second voltages are sequentially applied, respectively and a temperature-sensing unit to measure the temperature of the device under test.

Abstract: A dormant mode target semiconductor device within a leakage current target unit is identified for mitigating leakage current to prevent it from reaching catastrophic runaway. A leakage current shift monitor unit is electrically connected to the output node of the leakage current target unit and collects leakage current from the selected target semiconductor device for two consecutive predefined temporal periods and measures the difference between the collected leakage currents. A comparator receives and compares the outputs of the current shift monitor unit and a reference voltage generator. The comparator propagates an alert signal to the leakage current target unit when the leakage voltage output from the leakage current shift monitor unit exceeds the reference voltage, a condition that indicates that the leakage current is about to approach catastrophic runaway levels.

Abstract: A system, method and device for measuring a depth of a Through-Silicon-Via (TSV) in a semiconductor device region on a wafer during in-line semiconductor fabrication, includes a resistance measurement trench structure having length and width dimensions in a substrate, ohmic contacts on a surface of the substrate disposed on opposite sides of the resistance measurement trench structure, and an unfilled TSV structure in semiconductor device region having an unknown depth. A testing circuit makes contact with the ohmic contacts and measures a resistance therebetween, and a processor connected to the testing circuit calculates a depth of the trench structure and the unfilled TSV structure based on the resistance measurement. The resistance measurement trench structure and the unfilled TSV are created simultaneously during fabrication.

Abstract: A design structure including a semiconductor structure. The semiconductor structure includes (a) a substrate; (b) a first semiconductor device on the substrate; (c) N ILD (Inter-Level Dielectric) layers on the first semiconductor device, wherein N is an integer greater than one; and (d) an electrically conductive line electrically coupled to the first semiconductor device. The electrically conductive line is adapted to carry a lateral electric current in a lateral direction parallel to an interfacing surface between two consecutive ILD layers of the N ILD layers. The electrically conductive line is present in at least two ILD layers of the N ILD layers. The electrically conductive line does not comprise an electrically conductive via that is adapted to carry a vertical electric current in a vertical direction perpendicular to the interfacing surface.

Abstract: The invention comprises a 3D chip stack with an intervening thermoelectric coupling (TEC) plate. Through silicon vias in the 3D chip stack transfer electronic signals among the chips in the 3D stack, power the TEC plate, as well as distribute heat in the stack from hotter chips to cooler chips.

Abstract: Through silicon vias (TSVs) in silicon chips are both programmable and non-programmable. The programmable TSVs may employ metal/insulator/metal structures to switch from an open to shorted condition with programming carried out by complementary circuitry on two adjacent chips in a multi-story chip stack.

Abstract: A central reference clock is placed in a substantially middle chip of a 3-D chip-stack. The central reference clock is distributed to each child chip of the 3-D chip-stack, so that a plurality of clocks is generated for each individual chip in the 3-D-stack in a synchronous manner. A predetermined number of through-silicon-vias and on-chip wires are employed to form a delay element for each slave clock, ensuring that the clock generated for each child chip is substantially synchronized. Optionally, an on-chip clock trimming circuit is embedded for further precision tuning to eliminate local clock skews.

Abstract: A dormant mode target semiconductor device within a leakage current target unit is identified for mitigating leakage current to prevent it from reaching catastrophic runaway. A leakage current shift monitor unit is electrically connected to the output node of the leakage current target unit and collects leakage current from the selected target semiconductor device for two consecutive predefined temporal periods and measures the difference between the collected leakage currents. A comparator receives and compares the outputs of the current shift monitor unit and a reference voltage generator. The comparator propagates an alert signal to the leakage current target unit when the leakage voltage output from the leakage current shift monitor unit exceeds the reference voltage, a condition that indicates that the leakage current is about to approach catastrophic runaway levels.

Abstract: An embodiment of the invention provides a semiconductor structure, which may include a stud of a first conductive material formed inside a dielectric layer; a via of a second conductive material having a bottom and sidewalls with the bottom and the sidewalls being covered by a conductive liner, and the bottom being formed directly on top of the stud and being in contact with the via through the conductive liner; and one or more conductive paths of a third conductive material connecting to the via through the conductive liner at the sidewalls of said the. A method of making the semiconductor structure is also provided.

Abstract: Structures including a refractory metal collar at a copper wire and dielectric layer liner-less interface, and a related method, are disclosed. In one embodiment, a structure includes a copper wire having a liner-less interface with a dielectric layer thereabove; a via extending upwardly from the copper wire through the dielectric layer; and a refractory metal collar extending from a side of the via and partially along the liner-less interface. Refractory metal collar prevents electromigration induced slit voiding by improving the interface around the via, and prevents void nucleation from occurring near the via. Also, the refractory metal collar provides electrical redundancy in the presence of voids around the via and dielectric layer liner-less interface.