Abstract: Various embodiments include a silicon-based optical waveguide structure locally on a bulk silicon substrate, and systems and program products for forming such a structure by modifying an integrated circuit (IC) design structure. Embodiments include implementing processes of preparing manufacturing data for formation of the IC design structure in a computer-implemented IC formation system, wherein the preparing of the manufacturing data includes inserting instructions into the manufacturing data to convert an edge of the at least one shape from a <110> crystallographic direction to a <100> crystallographic direction.

Abstract: A dual bond pad structure for a wafer with laser die attachment and methods of manufacture are disclosed. The method includes forming a bonding layer on a surface of a substrate. The method further includes forming solder bumps on the bonding layer. The method further includes patterning the bonding layer to form bonding pads some of which comprise the solder bumps thereon. The method further includes attaching a laser diode to selected bonding pads using solder connections formed on the laser diode. The method further includes attaching an interposer substrate to the solder bumps formed on the bonding pads.

Abstract: Device structures and design structures for a bipolar junction transistor. The device structure includes a collector region in a substrate, a plurality of isolation structures extending into the substrate and comprised of an electrical insulator, and an isolation region in the substrate. The isolation structures have a length and are arranged with a pitch transverse to the length such that each adjacent pair of the isolation structures is separated by a respective section of the substrate. The isolation region is laterally separated from at least one of the isolation structures by a first portion of the collector region. The isolation region laterally separates a second portion of the collector region from the first portion of the collector region. The device structure further includes an intrinsic base on the second portion of the collector region and an emitter on the intrinsic base. The emitter has a length transversely oriented relative to the length of the isolation structures.

Abstract: Tunable filter structures, methods of manufacture and design structures are disclosed. The method of forming a filter structure includes forming a piezoelectric resonance filter over a cavity structure. The forming of the piezoelectric resonance filter includes: forming an upper electrode on one side of a piezoelectric material; and forming a lower electrode on an opposing side of the piezoelectric material. The method further includes forming a micro-electro-mechanical structure (MEMS) cantilever beam at a location in which, upon actuation, makes contact with the piezoelectric resonance filter.

Abstract: Device structures for a bipolar junction transistor. The device structure includes a collector region, an intrinsic base formed on the collector region, an emitter coupled with the intrinsic base and separated from the collector by the intrinsic base, and an isolation region extending through the intrinsic base to the collector region. The isolation region is formed with a first section having first sidewalls that extend through the intrinsic base and a second section with second sidewalls that extend into the collector region. The second sidewalls are inclined relative to the first sidewalls. The isolation region is positioned in a trench that is formed with first and second etching process in which the latter etches different crystallographic directions of a single-crystal semiconductor material at different etch rates.

Abstract: Disclosed is a trench formation technique wherein an opening having a first sidewall with planar contour and a second sidewall with a saw-tooth contour is etched through a semiconductor layer and into a semiconductor substrate. Then, a crystallographic wet etch process expands the portion of the opening within the semiconductor substrate to form a trench. Due to the different contours of the sidewalls and, thereby the different crystal orientations, one sidewall etches faster than the other, resulting in an asymmetric trench. Also disclosed is a bipolar semiconductor device formation method that incorporates the above-mentioned trench formation technique when forming a trench isolation region that undercuts an extrinsic base region and surrounds a collector pedestal.

Abstract: Various embodiments include a silicon-based optical waveguide structure locally on a bulk silicon substrate, and systems and program products for forming such a structure by modifying an integrated circuit (IC) design structure. Embodiments include implementing processes of preparing manufacturing data for formation of the IC design structure in a computer-implemented IC formation system, wherein the preparing of the manufacturing data includes inserting instructions into the manufacturing data to convert an edge of the at least one shape from a <110> crystallographic direction to a <100> crystallographic direction.

Abstract: Device structures for a bipolar junction transistor. The device structure includes a collector region, an intrinsic base formed on the collector region, an emitter coupled with the intrinsic base and separated from the collector by the intrinsic base, and an isolation region extending through the intrinsic base to the collector region. The isolation region is formed with a first section having first sidewalls that extend through the intrinsic base and a second section with second sidewalls that extend into the collector region. The second sidewalls are inclined relative to the first sidewalls. The isolation region is positioned in a trench that is formed with first and second etching process in which the latter etches different crystallographic directions of a single-crystal semiconductor material at different etch rates.

Abstract: Tunable filter structures, methods of manufacture and design structures are disclosed. The method of forming a filter structure includes forming a piezoelectric resonance filter over a cavity structure. The forming of the piezoelectric resonance filter includes: forming an upper electrode on one side of a piezoelectric material; and forming a lower electrode on an opposing side of the piezoelectric material. The method further includes forming a micro-electro-mechanical structure (MEMS) cantilever beam at a location in which, upon actuation, makes contact with the piezoelectric resonance filter.

Abstract: Disclosed is a trench formation technique wherein an opening having a first sidewall with planar contour and a second sidewall with a saw-tooth contour is etched through a semiconductor layer and into a semiconductor substrate. Then, a crystallographic wet etch process expands the portion of the opening within the semiconductor substrate to form a trench. Due to the different contours of the sidewalls and, thereby the different crystal orientations, one sidewall etches faster than the other, resulting in an asymmetric trench. Also disclosed is a bipolar semiconductor device formation method that incorporates the above-mentioned trench formation technique when forming a trench isolation region that undercuts an extrinsic base region and surrounds a collector pedestal.

Abstract: Disclosed herein a method, including depositing a silicon nitride layer over an inter layer dielectric (ILD); depositing a first conductive layer having a first thickness; forming a mask over a first portion of the first conductive layer to expose a second portion of the first conductive layer; etching the first conductive layer; etching the silicon nitride layer with a fluorine-based etch; and depositing a second conductive layer having a second thickness.

Abstract: Fabrication methods, device structures, and design structures for a bipolar junction transistor. The device structure includes a collector region, an intrinsic base formed on the collector region, an emitter coupled with the intrinsic base and separated from the collector by the intrinsic base, and an isolation region extending through the intrinsic base to the collector region. The isolation region is formed with a first section having first sidewalls that extend through the intrinsic base and a second section with second sidewalls that extend into the collector region. The second sidewalls are inclined relative to the first sidewalls. The isolation region is positioned in a trench that is formed with first and second etching process in which the latter etches different crystallographic directions of a single-crystal semiconductor material at different etch rates.

Abstract: Disclosed is a trench formation technique wherein an opening having a first sidewall with planar contour and a second sidewall with a saw-tooth contour is etched through a semiconductor layer and into a semiconductor substrate. Then, a crystallographic wet etch process expands the portion of the opening within the semiconductor substrate to form a trench. Due to the different contours of the sidewalls and, thereby the different crystal orientations, one sidewall etches faster than the other, resulting in an asymmetric trench. Also disclosed is a bipolar semiconductor device formation method that incorporates the above-mentioned trench formation technique when forming a trench isolation region that undercuts an extrinsic base region and surrounds a collector pedestal.

Abstract: Disclosed herein an image sensor chip, including a substrate having at least one via extending through at least one inter layer dielectric (ILD); a first conductive layer over the ILD, wherein the first conductive layer has a first thickness; a second conductive layer over the first conductive layer, wherein the second conductive layer has a second thickness of less than the first thickness; a polymer layer over the second conductive layer, the polymer layer including a cavity; a plurality of cavity components in the cavity; and protective layer contacting the polymer layer and covering the cavity.

Abstract: A design structure embodied in a machine readable medium used in a design process includes a first dielectric layer disposed on an intermediary layer, a first conductive pad portion and a first interconnect portion disposed on the first dielectric layer, a second dielectric layer disposed on the first dielectric layer, a first capping layer disposed on the first interconnect portion and a portion of the first conductive pad portion, a second capping layer disposed on the first capping layer and a portion of the second dielectric layer, an n-type doped silicon layer disposed on the second capping layer and the first conductive pad portion, an intrinsic silicon layer disposed on the n-type doped silicon layer, and a p-type doped silicon layer disposed on the intrinsic silicon layer.

Abstract: Tunable filter structures, methods of manufacture and design structures are disclosed. The method of forming a filter structure includes forming a piezoelectric resonance filter over a cavity structure. The forming of the piezoelectric resonance filter includes: forming an upper electrode on one side of a piezoelectric material; and forming a lower electrode on an opposing side of the piezoelectric material. The method further includes forming a micro-electro-mechanical structure (MEMS) cantilever beam at a location in which, upon actuation, makes contact with the piezoelectric resonance filter.

Abstract: Disclosed is a trench formation technique wherein an opening having a first sidewall with planar contour and a second sidewall with a saw-tooth contour is etched through a semiconductor layer and into a semiconductor substrate. Then, a crystallographic wet etch process expands the portion of the opening within the semiconductor substrate to form a trench. Due to the different contours of the sidewalls and, thereby the different crystal orientations, one sidewall etches faster than the other, resulting in an asymmetric trench. Also disclosed is a bipolar semiconductor device formation method that incorporates the above-mentioned trench formation technique when forming a trench isolation region that undercuts an extrinsic base region and surrounds a collector pedestal.

Abstract: An integrated waveguide structure with perforated chip edge seal and methods of manufacture are disclosed herein. The structure includes a guard ring structure surrounding an active region of an integrated circuit chip. The structure further includes a gap in the guard ring structure which is located at a predetermined level of the integrated circuit chip. The structure further includes a waveguide structure formed on a substrate of the integrated circuit chip. The structure further includes a fiber optic optically coupled to the waveguide structure through the gap formed in the guard ring structure.

Abstract: An integrated circuit (IC), design structure, and a method of making the same. In one embodiment, the IC includes: a substrate; a dielectric layer disposed on the substrate; a set of wire components disposed on the dielectric layer, the set of wire components including a first wire component disposed proximate a second wire component; a bond pad disposed on the first wire component, the bond pad including an exposed portion; a passivation layer disposed on the dielectric layer about a portion of the bond pad and the set of wire components, the passivation layer defining a wire structure via connected to the second wire component; and a wire structure disposed on the passivation layer proximate the bond pad and connected to the second wire component through the wire structure via.

Abstract: Device structures and design structures for a bipolar junction transistor. The device structure includes a collector region in a substrate, a plurality of isolation structures extending into the substrate and comprised of an electrical insulator, and an isolation region in the substrate. The isolation structures have a length and are arranged with a pitch transverse to the length such that each adjacent pair of the isolation structures is separated by a respective section of the substrate. The isolation region is laterally separated from at least one of the isolation structures by a first portion of the collector region. The isolation region laterally separates a second portion of the collector region from the first portion of the collector region. The device structure further includes an intrinsic base on the second portion of the collector region and an emitter on the intrinsic base. The emitter has a length transversely oriented relative to the length of the isolation structures.