Abstract: A Logic Built-In Self-Test (LBIST) domain of an integrated circuit is divided into partitions that in turn are subdivided into sub-partitions. Each sub-partition has an associated clock gating logic circuit that enables or inhibits the clock signal supplied to scan chains within the sub-partition. A user-defined number of sub-partitions, which can be specified on the basis of silicon results and power requirements of the integrated circuit, may be activated at any one time during a portion of an LBIST execution, which reduces toggling of concurrent scan chains, resulting in a reduction of energy consumption during testing, and reduces voltage droop due to inertia of power management control modules at the start of an LBIST test.

Abstract: A reset generation circuit of an integrated circuit uses a scan data input pin as a scan mode exit control, which is enabled only when the IC reset pin of the device is active. The reset generation circuit allows a TAP controller to be scan testable yet at the same time the circuit provides a method to exit scan mode without requiring a power-up sequence or an extra pin.

Abstract: A semiconductor device in accordance with some embodiments includes a substrate structure and a conductive interconnect extending through at least a portion of the substrate structure. The conductive interconnect can include a through-silicon via and a stress-relief feature that accommodates thermal expansion and/or thermal contraction of material to manage internal stresses in the semiconductor device. Methods of manufacturing the semiconductor device in accordance with some embodiments includes removing material of the conductive interconnect to form the stress-relief gap.

Abstract: Semiconductor devices having interconnects incorporating negative expansion (NTE) materials are disclosed herein. In one embodiment a semiconductor device includes a substrate having an opening that extends at least partially through the substrate. A conductive material having a positive coefficient of thermal expansion (CTE) partially fills the opening. A negative thermal expansion (NTE) having a negative CTE also partially fills the opening. In one embodiment, the conductive material includes copper and the NTE material includes zirconium tungstate.

Abstract: Methods for making semiconductor devices are disclosed herein. A method configured in accordance with a particular embodiment includes forming a stop layer and a dielectric liner including dielectric material along sidewalls of openings, e.g., through-substrate openings, of the semiconductor device and excess dielectric material outside the openings. The method further includes forming a metal layer including metal plugs within the openings and excess metal. The excess metal and the excess dielectric material are simultaneously chemically-mechanically removed using a slurry including ceria and ammonium persulfate. The slurry is selected to cause selectivity for removing the excess dielectric material relative to the stop layer greater than about 5:1 as well as selectivity for removing the excess dielectric material relative to the excess metal from about 0.5:1 to about 1.5:1.

Abstract: Methods of exposing conductive vias of semiconductor devices may involve positioning a barrier material over conductive vias extending from a backside surface of a substrate to at least substantially conform to the conductive vias. A self-planarizing isolation material may be positioned on a side of the barrier material opposing the substrate. An exposed surface of the self-planarizing isolation material may be at least substantially planar. A portion of the self-planarizing isolation material, a portion of the barrier material, and a portion of at least some of the conductive vias may be removed to expose each of the conductive vias. Removal may be stopped after exposing at least one laterally extending portion of the barrier material proximate the substrate.

Abstract: Methods of exposing conductive vias of semiconductor devices may comprise conformally forming a barrier material over conductive vias extending from a backside surface of a substrate. A self-planarizing isolation material may be formed over the barrier material. An exposed surface of the self-planarizing isolation material may be substantially planar. A portion of the self-planarizing isolation material, a portion of the barrier material, and a portion of protruding material of the conductive vias may be removed to expose the conductive vias. Removal of the self-planarizing isolation material, the barrier material, and the conductive vias may be stopped after exposing at least one laterally extending portion of the barrier material.

Abstract: Methods of manufacturing semiconductor devices and semiconductor devices with through-substrate vias (TSVs). One embodiment of a method of manufacturing a semiconductor device includes forming an opening through a dielectric structure and at least a portion of a semiconductor substrate, and forming a dielectric liner material having a first portion lining the opening and a second portion on an outer surface of the dielectric structure laterally outside of the opening. The method further includes removing the conductive material such that the second portion of the dielectric liner material is exposed, and forming a damascene conductive line in the second portion of the dielectric liner material that is electrically coupled to the TSV.

Abstract: Methods for making semiconductor devices are disclosed herein. A method configured in accordance with a particular embodiment includes forming a stop layer and a dielectric liner including dielectric material along sidewalls of openings, e.g., through-substrate openings, of the semiconductor device and excess dielectric material outside the openings. The method further includes forming a metal layer including metal plugs within the openings and excess metal. The excess metal and the excess dielectric material are simultaneously chemically-mechanically removed using a slurry including ceria and ammonium persulfate. The slurry is selected to cause selectivity for removing the excess dielectric material relative to the stop layer greater than about 5:1 as well as selectivity for removing the excess dielectric material relative to the excess metal from about 0.5:1 to about 1.5:1.

Abstract: Methods of forming multi-tiered semiconductor devices are described, along with apparatuses that include them. In one such method, a silicide is formed in a tier of silicon, the silicide is removed, and a device is formed at least partially in a void that was occupied by the silicide. One such apparatus includes a tier of silicon with a void between tiers of dielectric material. Residual silicide is on the tier of silicon and/or on the tiers of dielectric material and a device is formed at least partially in the void. Additional embodiments are also described.

Abstract: Semiconductor devices having interconnects incorporating negative expansion (NTE) materials are disclosed herein. In one embodiment a semiconductor device includes a substrate having an opening that extends at least partially through the substrate. A conductive material having a positive coefficient of thermal expansion (CTE) partially fills the opening. A negative thermal expansion (NTE) having a negative CTE also partially fills the opening. In one embodiment, the conductive material includes copper and the NTE material includes zirconium tungstate.

Abstract: A post-W CMP cleaning solution consists of carboxylic acid and deionized water. The carboxylic acid may be selected from the group consisting of (1) monocarboxylic acids; (2) dicarboxylic acids; (3) tricarboxylic acids; (4) polycarboxylic acids; (5) hydroxycarboxylic acids; (6) salts of the above-described carboxylic acids; and (7) any combination thereof. The post-W CMP cleaning solution can work well without adding any other chemical additives such as surfactants, corrosion inhibitors, pH adjusting agents or chelating agents.

Abstract: A blanket stop layer is conformally formed on a layer with a large step height. A first chemical mechanical polishing process is performed to remove the blanket stop layer atop the layer in the raised region. A second chemical mechanical polishing process is performed to planarize the wafer using the blanket stop layer as a stop layer when the layer is lower than or at a same level as the blanket stop layer or using the layer as a stop layer when the blanket stop layer is lower than or at a same level as the layer, or a selective dry etch is performed to remove the layer in the raised region. Thus, the layer in the raised region can be easily removed without occurrence of dishing in the non-raised region which is protected by the blanket stop layer.

Abstract: Methods of forming multi-tiered semiconductor devices are described, along with apparatuses that include them. In one such method, a silicide is formed in a tier of silicon, the silicide is removed, and a device is formed at least partially in a void that was occupied by the silicide. One such apparatus includes a tier of silicon with a void between tiers of dielectric material. Residual silicide is on the tier of silicon and/or on the tiers of dielectric material and a device is formed at least partially in the void. Additional embodiments are also described.

Abstract: An integrated circuit (IC) includes a flip-flop that stores data when the IC is in built-in self-test (BIST) mode. The flip-flop includes a master latch connected to a slave latch, which in turn is connected to a data retention latch. A control circuit is connected to the flip-flop. During normal operation, the master latch receives a data input signal, which is transmitted through the slave latch to another flip-flop of the IC. When the control circuit initiates BIST (scan testing), data stored in the slave latch is transferred to the data retention latch. Upon completion of BIST, the data stored in the retention latch is used to restore the flip-flop to its original state.

Abstract: A processing system includes a clock generator circuit configured to receive a master clock signal and to output a plurality of clock signals, wherein the plurality of clock signals have a first frequency during a built-in self-test (BIST) mode and a plurality of shift-capture clock generator circuits. Each shift-capture clock generator circuit includes a clock gate circuit and a clock divider circuit and is configured to receive a corresponding one of the plurality of clock signals. At least one of the clock divider circuits changes the first frequency of the one of the plurality of clock signals to a second frequency during the BIST mode.

Abstract: Methods of exposing conductive vias of semiconductor devices may comprise conformally forming a barrier material over conductive vias extending from a backside surface of a substrate. A self-planarizing isolation material may be formed over the barrier material. An exposed surface of the self-planarizing isolation material may be substantially planar. A portion of the self-planarizing isolation material, a portion of the barrier material, and a portion of protruding material of the conductive vias may be removed to expose the conductive vias. Removal of the self-planarizing isolation material, the barrier material, and the conductive vias may be stopped after exposing at least one laterally extending portion of the barrier material.

Abstract: A blanket stop layer is conformally formed on a layer with a large step height. A first chemical mechanical polishing process is performed to remove the blanket stop layer atop the layer in the raised region. A second chemical mechanical polishing process is performed to planarize the wafer using the blanket stop layer as a stop layer when the layer is lower than or at a same level as the blanket stop layer or using the layer as a stop layer when the blanket stop layer is lower than or at a same level as the layer, or a selective dry etch is performed to remove the layer in the raised region. Thus, the layer in the raised region can be easily removed without occurrence of dishing in the non-raised region which is protected by the blanket stop layer.

Abstract: Methods for making semiconductor devices are disclosed herein. A method configured in accordance with a particular embodiment includes forming a stop layer and a dielectric liner including dielectric material along sidewalls of openings, e.g., through-substrate openings, of the semiconductor device and excess dielectric material outside the openings. The method further includes forming a metal layer including metal plugs within the openings and excess metal. The excess metal and the excess dielectric material are simultaneously chemically-mechanically removed using a slurry including ceria and ammonium persulfate. The slurry is selected to cause selectivity for removing the excess dielectric material relative to the stop layer greater than about 5:1 as well as selectivity for removing the excess dielectric material relative to the excess metal from about 0.5:1 to about 1.5:1.

Abstract: A method of forming a through-substrate via includes forming a through-substrate via opening at least partially through a substrate from one of opposing sides of the substrate. A first material is deposited to line and narrow the through-substrate via opening. The first material is etched to widen at least an elevationally outermost portion of the narrowed through-substrate via opening on the one side. After the etching, a conductive second material is deposited to fill the widened through-substrate via opening. Additional implementations are disclosed. Integrated circuit substrates are disclosed independent of method of manufacture.