Abstract: Implementations of a diode may include a first electrode; a first dielectric layer coupled to the first electrode; a second dielectric layer coupled to the first dielectric layer; and a second electrode coupled to the second dielectric layer. The first dielectric layer may be one of silicon dioxide or aluminum oxide; and the second dielectric layer may be one of niobium oxide, tantalum oxide, zirconium oxide, hafnium oxide, or any combination thereof.

Abstract: In a general aspect, a transistor can include a fin having a proximal end and a distal end. The fin can include a dielectric portion longitudinally extending between the proximal end and the distal end, and a semiconductor layer disposed on the dielectric portion. The semiconductor layer can longitudinally extend between the proximal end and the distal end. The transistor can further include a source region disposed at the proximal end of the fin, and a drain region disposed at the distal end of the fin. The transistor can also include a gate dielectric layer disposed on a channel region of the semiconductor layer. The channel region can be disposed between the gate dielectric layer and the dielectric portion. The channel region can be longitudinally disposed between the source region and the drain region. The transistor can further include a conductive gate electrode disposed on the gate dielectric layer.

Abstract: A semiconductor device having a fuse structure includes a region of semiconductor material having a major surface. A dielectric region is over the major surface. A first fuse terminal is over a first part of the dielectric region, a second fuse terminal is over a second part of the dielectric region and spaced apart from the first fuse terminal to provide a gap region, and a fuse body over a third part of the dielectric region interposed between and connected to the first fuse terminal and the second fuse terminal. A dummy structure is over the dielectric region in the gap region on a first side of the fuse body, the dummy structure spaced apart and electrically isolated from the fuse body, the first fuse terminal, and the second fuse terminal. The dummy structure is configured to reduce the presence of or reduce the effects of defects, such as cracks or voids that can emanate from the fuse structure.

Abstract: A semiconductor structure includes a region of semiconductor material having a major surface and a first a first insulating structure over the major surface. A first conductive electrode is over the first insulating structure and a laminate film structure is over the first conductive electrode. The laminate film structure includes a first film comprising rutile phase ruthenium dioxide adjacent to the first conductive electrode, and a second film over the first film, wherein the second film comprises a high dielectric constant dielectric material. A second conductive electrode is over the laminate film structure. In some examples, the first film is provided using atomic layer deposition. In some examples, the second film comprises rutile phase titanium dioxide formed using atomic layer deposition. In some examples, the laminate film structure can be used as part of a MIM capacitor.

Abstract: A semiconductor device having a fuse structure includes a region of semiconductor material having a major surface. A dielectric region is over the major surface. A first fuse terminal is over a first part of the dielectric region, a second fuse terminal is over a second part of the dielectric region and spaced apart from the first fuse terminal to provide a gap region, and a fuse body over a third part of the dielectric region interposed between and connected to the first fuse terminal and the second fuse terminal. A dummy structure is over the dielectric region in the gap region on a first side of the fuse body, the dummy structure spaced apart and electrically isolated from the fuse body, the first fuse terminal, and the second fuse terminal. The dummy structure is configured to reduce the presence of or reduce the effects of defects, such as cracks or voids that can emanate from the fuse structure.

Abstract: Implementations of capacitors may include: a first electrode having a first side and a second side. The capacitor may also include a silicon nitride (SiN) layer including on the second side of the first electrode. An opening may be included in the silicon nitride layer. The capacitors may include a dielectric layer within the opening of the SiN layer. The dielectric layer may include a recess. The capacitor may also include a second electrode having a first side and a second side. The first side of the second electrode may be included within the recess of the dielectric layer.

Abstract: An energy storage device such as a metal-insulator-metal capacitor and a method for manufacturing the energy storage device. The metal-insulator-metal capacitor includes an insulating material positioned between a bottom electrode or bottom plate and a top electrode or top plate. The surface area of the bottom electrode is greater than the surface area of the insulating material and the surface area of the insulating material is greater than the surface area of the top electrode. The top electrode and the insulating layer have edges that are laterally within and spaced apart from edges of the bottom electrode. A protective layer covers the top electrode, the edges of the top electrode, and the portions of the insulating layer that are uncovered by the top electrode. The protective layer serves as an etch mask during the formation of the bottom electrode.

Abstract: An energy storage device such as a metal-insulator-metal capacitor and a method for manufacturing the energy storage device. The metal-insulator-metal capacitor includes an insulating material positioned between a bottom electrode or bottom plate and a top electrode or top plate. The surface area of the bottom electrode is greater than the surface area of the insulating material and the surface area of the insulating material is greater than the surface area of the top electrode. The top electrode and the insulating layer have edges that are laterally within and spaced apart from edges of the bottom electrode. A protective layer covers the top electrode, the edges of the top electrode, and the portions of the insulating layer that are uncovered by the top electrode. The protective layer serves as an etch mask during the formation of the bottom electrode.

Abstract: A system and method for collecting and analyzing integrated circuit test vehicle test data by identifying various blocks of circuitry through at least two different intersecting test paths. In one embodiment, the process test circuits may be arranged in a matrix format and connected so that they may be tested along rows or columns. When a failure along a specific row and a specific column is identified, the process test circuit at the intersection may be identified as the failure point.

Abstract: A test vehicle a system and method for evaluating an interconnect module manufacturing process while dynamically testing performance with high-speed operational frequencies is disclosed. The test vehicle incorporates a self-timed or gated speed circuit that can detect subtle resistive faults and also show the exact location in the array where the speed fault occurred based on test program data logs from scan flip flops. One embodiment incorporates a gated clock in the gated speed circuit producing gated data that delivers greater statistical properties with respect to Integrated Circuit Direct Drain Quiescent Current (IDDQ) testing.

Abstract: A method of diverting void diffusion in an integrated circuit includes steps of forming an electrical conductor having a boundary in a first electrically conductive layer of an integrated circuit, forming a via inside the boundary of the electrical conductor in a dielectric layer between the first electrically conductive layer and a second electrically conductive layer of the integrated circuit, and forming a slot between the via and the boundary of the electrical conductor for diverting void diffusion in the electrical conductor away from the via.

Abstract: An integrated circuit (IC) includes one or more inductors that have magnetic flux lines substantially parallel to a generally horizontal plane of the IC. The inductor is formed in a plurality of conductor layers separated by insulating layers of the IC. Regions of highest magnetic flux density of the inductor may preferably be located near the edge of the IC. Additionally, the inductor may preferably be segmented. The over-all inductance may preferably be controlled by turning on and off selected inductors or inductor segments.

Abstract: A system and method for collecting and analyzing optical inspection results obtained during the manufacturing process and comparing those results to actual functional results of a specially designed test vehicle integrated circuit. The test vehicle integrated circuit allows failures to be localized to very small areas, which allows more accurate correlation between inspection faults and functional failures. The correlation of inspection faults to actual functional failures is used to change the sensitivity settings for an optical inspection system to more accurately detect defects that are likely to be functional failures.

Abstract: A method and apparatus for redirecting void diffusion away from vias in an integrated circuit design includes steps of forming an electrical conductor in a first electrically conductive layer of an integrated circuit design, forming a via between a distal end of the electrical conductor and a second electrically conductive layer of the integrated circuit design, and reducing tensile stress in the electrical conductor to divert void diffusion away from the via.

Abstract: A method of forming a carbon nanotube fuse by depositing a carbon nanotube layer, then depositing a cap layer directly over the carbon nanotube layer. The cap layer is formed of a material that has an insufficient amount of oxygen to significantly oxidize the carbon nanotube layer under operating conditions, and is otherwise sufficiently robust to protect the carbon nanotube layer from oxygen and plasmas. A photoresist layer is formed over the cap layer, and the photoresist layer is patterned to define a desired size of fuse. Both the cap layer and the carbon nanotube layer are completely etched, without removing the photoresist layer, to define the fuse having two ends in the carbon nanotube layer. Just the cap layer is etched, without removing the photoresist layer, so as to reduce the cap layer by a desired amount at the edges of the cap layer under the photoresist layer, without damaging the carbon nanotube layer.

Abstract: A system and method for collecting and analyzing integrated circuit test vehicle test data by identifying various blocks of circuitry through at least two different intersecting test paths. In one embodiment, the process test circuits may be arranged in a matrix format and connected so that they may be tested along rows or columns. When a failure along a specific row and a specific column is identified, the process test circuit at the intersection may be identified as the failure point.

Abstract: A system and method for collecting and analyzing optical inspection results obtained during the manufacturing process and comparing those results to actual functional results of a specially designed test vehicle integrated circuit. The test vehicle integrated circuit allows failures to be localized to very small areas, which allows more accurate correlation between inspection faults and functional failures. The correlation of inspection faults to actual functional failures is used to change the sensitivity settings for an optical inspection system to more accurately detect defects that are likely to be functional failures.

Abstract: Embodiments of the invention include an extreme low-K circuit structure formed on a substrate having a plurality of electrically conductive structures. A lattice structure of bracing material configured to support the electrically conductive structures is formed on the substrate and also can define regions of extreme low-K dielectric space between the electrically conductive structures. Additionally, methods for creating dielectric structures on a substrate are disclosed.

Abstract: A capacitor and a capacitor dielectric material are fabricated by adjusting the amount of an ionic conductive species, such as hydrogen, contained in the capacitor dielectric material to obtain predetermined electrical or functional characteristics. Forming the capacitor dielectric material from silicon, nitrogen and hydrogen allows a stoichiometric ratio control of silicon to nitrogen to limit the amount of hydrogen. Forming the capacitor by dielectric material plasma enhanced chemical vapor deposition (PECVD) allows hydrogen bonds to be broken by ionic bombardment, so that stoichiometric control is achieved by controlling the power of the PECVD. Applying a predetermined number of thermal cycles of temperature elevation and temperature reduction also breaks the hydrogen bonds to control the amount of the hydrogen in the formed capacitor dielectric material.

Abstract: An integrated circuit having a gate region, a source drain region, and an electrically nonconductive spacer separating the gate region and the source drain region. A local interconnect electrically connects the gate region to the source drain region across the electrically nonconductive spacer. The local interconnect is formed of a semiconducting material reacted with a metal. The local interconnect may be formed by implanting a precursor species into the electrically nonconductive spacer. A metal layer is deposited over at least the electrically nonconductive spacer, and the integrated circuit is heated to form an electrically conductive local interconnect from the metal layer and the precursor species implanted in the electrically nonconductive spacer.