Abstract: Acoustic filtering circuitry includes a piezoelectric layer, a dielectric layer, a plurality of acoustic resonators, and a capacitor. The dielectric layer is over a surface of the piezoelectric layer. The plurality of acoustic resonators each includes a transducer on the surface of the piezoelectric layer such that the transducer is between the piezoelectric layer and the dielectric layer. The capacitor includes a first plate on the surface of the piezoelectric layer such that the first plate is between the piezoelectric layer and the dielectric layer and a second plate over the first plate such that the second plate and the first plate are separated by at least a portion of the dielectric layer.

Abstract: An acoustic wave device includes a piezoelectric layer, an interdigital transducer, and a slow wave propagation overlay over a portion of the interdigital transducer. By providing electrode fingers of the interdigital transducer such that a portion of the width thereof is dependent on an electrode period, a desirable wave mode may be maintained in the acoustic wave device. Further, by varying a width of the slow wave propagation overlay based on the electrode period, the desirable wave mode may be further maintained.

Abstract: Embodiments of a Surface Acoustic Wave (SAW) device, or filter, and methods of fabrication thereof are disclosed. In some embodiments, the SAW filter comprises a piezoelectric substrate and an Interdigitated Transducer (IDT) on a surface of the piezoelectric substrate. The IDT includes multiple fingers, each comprising a metal stack. The SAW filter further includes a cap layer on a surface of the IDT opposite the piezoelectric substrate and on areas of the surface of the piezoelectric substrate exposed by the IDT. The cap layer has a thickness in a range of and including 10 to 500 Angstroms and a high electrical resistivity (and thus a low electrical conductivity). For instance, in some embodiments, the electrical resistivity of the cap layer is greater than 10 kilo-ohm meters (K?·m). The SAW filter further includes an oxide overcoat layer on a surface of the cap layer opposite the IDT and the piezoelectric substrate.

Abstract: An acoustic wave device includes a piezoelectric layer, an interdigital transducer, and a slow wave propagation overlay over a portion of the interdigital transducer. By providing electrode fingers of the interdigital transducer such that a portion of the width thereof is dependent on an electrode period, a desirable wave mode may be maintained in the acoustic wave device. Further, by varying a width of the slow wave propagation overlay based on the electrode period, the desirable wave mode may be further maintained.

Abstract: Acoustic filtering circuitry includes a piezoelectric layer, a dielectric layer, a plurality of acoustic resonators, and a capacitor. The dielectric layer is over a surface of the piezoelectric layer. The plurality of acoustic resonators each includes a transducer on the surface of the piezoelectric layer such that the transducer is between the piezoelectric layer and the dielectric layer. The capacitor includes a first plate on the surface of the piezoelectric layer such that the first plate is between the piezoelectric layer and the dielectric layer and a second plate over the first plate such that the second plate and the first plate are separated by at least a portion of the dielectric layer.

Abstract: Embodiments of a Surface Acoustic Wave (SAW) device, or filter, and methods of fabrication thereof are disclosed. In some embodiments, the SAW filter comprises a piezoelectric substrate and an Interdigitated Transducer (IDT) on a surface of the piezoelectric substrate. The IDT includes multiple fingers, each comprising a metal stack. The SAW filter further includes a cap layer on a surface of the IDT opposite the piezoelectric substrate and on areas of the surface of the piezoelectric substrate exposed by the IDT. The cap layer has a thickness in a range of and including 10 to 500 Angstroms and a high electrical resistivity (and thus a low electrical conductivity). For instance, in some embodiments, the electrical resistivity of the cap layer is greater than 10 kilo-ohm meters (K?·m). The SAW filter further includes an oxide overcoat layer on a surface of the cap layer opposite the IDT and the piezoelectric substrate.

Abstract: The present invention provides a solder bump structure. In one aspect, the solder bump structure is utilized in a semiconductor device, such as an integrated circuit. The semiconductor device comprises active devices located over a semiconductor substrate, interconnect layers comprising copper formed over the active devices, and an outermost metallization layer positioned over the interconnect layers. The outermost metallization layer comprises aluminum and includes at least one bond pad and at least one interconnect runner each electrically connected to an interconnect layer. An under bump metallization layer (UBM) is located over the bond pad, and a solder bump is located over the UBM.

Abstract: An acoustic wave device operable as a piston mode wave guide includes electrodes forming an interdigital transducer on a surface of the piezoelectric substrate, wherein each of the plurality of electrodes is defined as having a transversely extending center region and transversely opposing edge regions for guiding an acoustic wave longitudinally through the transducer. A Silicon Oxide overcoat covers the transducer and a Silicon Nitride layer covers the Silicon Oxide overcoat within only the center and edge regions. The thickness of the Silicon Nitride layer is sufficient for providing a frequency modification to the acoustic wave within the center region and is optimized with a positioning of a Titanium strip within each of the opposing edge regions. The Titanium strip reduces the acoustic wave velocity within the edge regions with the velocity in the edge regions being less than the wave velocity within the transducer center region.

Abstract: An acoustic wave device operable as a piston mode wave guide includes electrodes forming an interdigital transducer on a surface of the piezoelectric substrate, wherein each of the plurality of electrodes is defined as having a transversely extending center region and transversely opposing edge regions for guiding an acoustic wave longitudinally through the transducer. A Silicon Oxide overcoat covers the transducer and a Silicon Nitride layer covers the Silicon Oxide overcoat within only the center and edge regions. The thickness of the Silicon Nitride layer is sufficient for providing a frequency modification to the acoustic wave within the center region and is optimized with a positioning of a Titanium strip within each of the opposing edge regions. The Titanium strip reduces the acoustic wave velocity within the edge regions with the velocity in the edge regions being less than the wave velocity within the transducer center region.

Abstract: According to certain embodiments, integrated circuits are fabricated using brittle low-k dielectric material to reduce undesired capacitances between conductive structures. To avoid permanent damage to such dielectric material, bond pads are fabricated with support structures that shield the dielectric material from destructive forces during wire bonding. In one implementation, the support structure includes a passivation structure between the bond pad and the topmost metallization layer. In another implementation, the support structure includes metal features between the topmost metallization layer and the next-topmost metallization layer. In both cases, the region of the next-topmost metallization layer under the bond pad can have multiple metal lines corresponding to different signal routing paths.

Abstract: Provided is a method for separating a semiconductor wafer into individual semiconductor dies. The method for separating the semiconductor wafer, among other steps, may include implanting an impurity into regions of a semiconductor wafer proximate junctions where semiconductor dies join one another, the impurity configured to disrupt bonds in the semiconductor wafer proximate the junctions and lead to weakened regions. The method for separating the semiconductor wafer may further include separating the semiconductor wafer having the impurity into individual semiconductor dies along the weakened regions.

Abstract: A SAW device having metal electrodes on a surface of the piezoelectric substrate includes a dielectric layer deposited on the surface. Depositing the layer results in seams extending upward from the electrodes extending above the surface of the substrate. An additional seam results from one seam extending from one electrode joining a second seam extending from an adjacent electrode within the dielectric layer and is generally formed above the height of the electrodes. The additional seam is removed through planarization or the like. The dielectric layer may be further planarized for providing a thickness of the dielectric layer above the electrodes as desired.

Abstract: A SAW device having metal electrodes on a surface of the piezoelectric substrate includes a dielectric layer deposited on the surface. Depositing the layer results in seams extending upward from the electrodes extending above the surface of the substrate. An additional seam results from one seam extending from one electrode joining a second seam extending from an adjacent electrode within the dielectric layer and is generally formed above the height of the electrodes. The additional seam is removed through planarization or the like. The dielectric layer may be further planarized for providing a thickness of the dielectric layer above the electrodes as desired.

Abstract: Provided is a method for separating a semiconductor wafer into individual semiconductor dies. The method for separating the semiconductor wafer, among other steps, may include implanting an impurity into regions of a semiconductor wafer proximate junctions where semiconductor dies join one another, the impurity configured to disrupt bonds in the semiconductor wafer proximate the junctions and lead to weakened regions. The method for separating the semiconductor wafer may further include separating the semiconductor wafer having the impurity into individual semiconductor dies along the weakened regions.

Abstract: According to certain embodiments, integrated circuits are fabricated using brittle low-k dielectric material to reduce undesired capacitances between conductive structures. To avoid permanent damage to such dielectric material, bond pads are fabricated with support structures that shield the dielectric material from destructive forces during wire bonding. In one implementation, the support structure includes a passivation structure between the bond pad and the topmost metallization layer. In another implementation, the support structure includes metal features between the topmost metallization layer and the next-topmost metallization layer. In both cases, the region of the next-topmost metallization layer under the bond pad can have multiple metal lines corresponding to different signal routing paths.

Abstract: The present invention provides a semiconductor device capable of substantially retarding boron penetration within the semiconductor device and a method of manufacture therefor. In the present invention the semiconductor device includes a gate dielectric located over a substrate of a semiconductor wafer, wherein the gate dielectric includes a nitrided layer and a dielectric layer. The present invention further includes a nitrided transition region located between the dielectric layer and the nitrided layer and a gate located over the gate dielectric.

Abstract: The present invention provides a semiconductor device capable of substantially retarding boron penetration within the semiconductor device and a method of manufacture therefor. In the present invention the semiconductor device includes a gate dielectric located over a substrate of a semiconductor wafer, wherein the gate dielectric includes a nitrided layer and a dielectric layer. The present invention further includes a nitrided transition region located between the dielectric layer and the nitrided layer and a gate located over the gate dielectric.

Abstract: A film structure includes low-k dielectric films and N—H base source films such as barrier layer films, etch-stop films and hardmask films. Interposed between the low-k dielectric film and adjacent N—H base film is a TEOS oxide film which suppresses the diffusion of amines or other N—H bases from the N—H base source film to the low-k dielectric film. The film structure may be patterned using DUV lithography and a chemically amplified photoresist since there are no base groups present in the low-k dielectric films to neutralize the acid catalysts in the chemically amplified photoresist.

Abstract: A method of surface treating a surface and semiconductor article is disclosed. A deposited surface layer on a substrate, such as a semiconductor surface, is treated and annealed within an alkyl environment of a chemical vapor deposition chamber to passivate the surface layer by bonding with the silicon and attaching alkyl terminating chemical species on the surface of the surface layer to aid in dehydroxylating the surface. The surface layer comprises a silicon-oxy-carbide surface layer having a carbon content ranging from about 5% to about 20% at the molecular level and a dielectric constant of about 2.5 to about 3.0.

Abstract: A film structure includes low-k dielectric films and N—H base source films such as barrier layer films, etch-stop films and hardmask films. Interposed between the low-k dielectric film and adjacent N—H base film is a TEOS oxide film which suppresses the diffusion of amines or other N—H bases from the N—H base source film to the low-k dielectric film. The film structure may be patterned using DUV lithography and a chemically amplified photoresist since there are no base groups present in the low-k dielectric films to neutralize the acid catalysts in the chemically amplified photoresist.