Abstract: A receiver for detecting a stream of optical data bits which are transmitted at a predetermined frequency includes a plurality of optically-active devices arranged on an integrated circuit substrate in an array. The plurality of optically-active devices are capable of being positioned to receive the stream of optical data bits which are transmitted as light, and each of the optically active devices is capable of detecting light in an optically active state and generating a detected signal corresponding thereto. A control circuit receives a clock signal at a rate corresponding to the predetermined frequency and generates control signals which cause a different one of the plurality of optically-active devices to be in the optically active state during each successive period and thereby detect the presence of light during each of said successive periods and generate the detected signals corresponding to the data bit stream.

Abstract: A horizontal deflecting optical waveguide is formed in an integrated circuit-like structure having a substrate and at least one layer of dielectric material above the substrate. A trench is formed in the dielectric material, and the trench has first and second portions angularly joined at a bent portion. A reflective layer of material adjoins, conforms to and extends along the side walls of the trench. A core of optically transmissive material conforms to the reflective layer within the trench. The reflective layer forms a wall at the bent portion which reflects light from the core located in one portion into the core located in the other portion.

Abstract: A method of planarizing a first side of a semiconductor wafer with a polishing system includes the step of polishing the first side of the wafer in order to remove material from the wafer. The method also includes the step of moving a lens of a confocal optical system between a number of lens positions so as to maintain focus on the first side of the wafer during the polishing step. The method further includes the step of determining a rate-of-movement value based on movement of the lens during the moving step. Moreover, the method includes the step of stopping the polishing step if the rate-of-movement value has a predetermined relationship with a movement threshold value. An apparatus for polishing a first side of a semiconductor wafer is also disclosed.

Abstract: A metal-insulator-metal capacitor is formed between interconnect layers of an integrated circuit with one of the plates of the capacitor formed integrally with one of the interconnect layers. A dielectric layer is formed on top of the interconnect layer, and a top capacitor plate is formed thereon. A bottom plate is defined by the interconnect layer and extends laterally beyond the top plate so that via interconnects may connect to both plates. An intermetal dielectric (IMD) layer separates the interconnect layer and the capacitor from the next interconnect layer above, and the via interconnects are formed through the IMD layer to connect the above interconnect layer to the capacitor plates. The dielectric layer on top of the interconnect layer that defines the bottom plate and another dielectric layer formed on top of the top plate may serve as etch stops for forming the vias for the via interconnects to different levels.

Abstract: A capacitor has a pair of plates separated by a capacitor dielectric material which is formed of multiple separate layers of different dielectric materials having different electrical characteristics. The different electrical characteristics are represented by linearity curves that curve relatively oppositely with respect to one another. Combining the different dielectric materials and separate layers achieves selected electrical characteristics from the overall capacitor dielectric material. The capacitor dielectric material may be formed with a top layer, a middle layer and a bottom layer. The middle layer may be formed of relatively high leakage dielectric and/or relatively high dielectric constant material, and the top and bottom layers may be formed of barrier material which is substantially resistant to leakage current and which exhibits a relatively lower dielectric constant.

Abstract: An optical waveguide extends vertically within the interior of an IC-like structure to route optical signals between horizontal waveguides in different layers of horizontal optical interconnects. A light reflecting structure is positioned at the intersection of the horizontal and vertical waveguides to reflect the light. Multiple horizontal waveguides may join the vertical waveguide at a common intersection, to form a beam splitter or a beam combiner. Optical signals from one horizontal waveguide are diverted within the IC-like structure into another horizontal or vertical waveguide. The waveguide is formed with a light reflective structure at an intersection of the horizontal and vertical waveguides, and the waveguide is completed using damascene fabrication techniques.

Abstract: A horizontal deflecting optical waveguide is formed in an integrated circuit-like structure having a substrate and at least one layer of dielectric material above the substrate. A trench is formed in the dielectric material, and the trench has first and second portions angularly joined at a bent portion. A reflective layer of material adjoins, conforms to and extends along the side walls of the trench. A core of optically transmissive material conforms to the reflective layer within the trench. The reflective layer forms a wall at the bent portion which reflects light from the core located in one portion into the core located in the other portion.

Abstract: A method of planarizing a semiconductor that includes (i) a substrate material, (ii) a first reflective substance positioned on the substrate material, (iii) an intermediate material positioned on the first reflective substance, wherein a channel is defined in a structure which includes the substrate, the first reflective substance, and the intermediate material, and (iv) a second reflective substance positioned on the intermediate material and in the channel is disclosed.

Abstract: A method of planarizing a first side of a semiconductor wafer with a polishing system includes the step of polishing the first side of the wafer in order to remove material from the wafer. The method also includes the step of moving a lens of a confocal optical system between a number of lens positions so as to maintain focus on the first side of the wafer during the polishing step. The method further includes the step of determining a rate-of-movement value based on movement of the lens during the moving step. Moreover, the method includes the step of stopping the polishing step if the rate-of-movement value has a predetermined relationship with a movement threshold value. An apparatus for polishing a first side of a semiconductor wafer is also disclosed.

Abstract: A method of creating a layer-to-layer alignment mark in a semiconductor wafer includes the step of depositing a first conductor layer on a substrate associated with the semiconductor wafer. The method also includes the step of fabricating a number of alignment trenches in the first conductor layer. Moreover, the method includes the step of depositing a first insulator layer on the first conductor layer so as to fill the number of alignment trenches. Yet further, the method includes the step of removing material associated with the first insulator layer from the number of alignment trenches such that an upper surface of the first conductor layer and an upper surface of the first insulator layer define a first alignment step feature which possesses a predetermined height. The method also includes the step of depositing a second conductor layer on the semiconductor wafer subsequent to the removing step. A semiconductor wafer is also disclosed.

Abstract: The present invention relates to a semiconductor device, preferably a capacitor, and a method of forming the same. The method adds only a single additional masking step to the the fabrication process and reduces problems relating to alignment of various layers. A relatively thick insulation layer is formed over a bottom electrode. An opening having a sidewall that is etched in the insulation layer using a mask to expose a portion of the bottom electrode. Once the mask is removed, a dielectric layer and conductive layer are then sequentially deposited over the entire structure, including sidewalls. Thereafter, chemical-mechanical polishing is used to remove portions of the conductive layer and the dielectric layer so that the conductive layer and dielectric layer which remains forms, for example, the top electrode and dielectric layer of the integrated circuit capacitor.

Abstract: A horizontal deflecting optical waveguide is formed in an integrated circuit-like structure having a substrate and at least one layer of dielectric material above the substrate. A trench is formed in the dielectric material, and the trench has first and second portions angularly joined at a bent portion. A reflective layer of material adjoins, conforms to and extends along the side walls of the trench. A core of optically transmissive material conforms to the reflective layer within the trench. The reflective layer forms a wall at the bent portion which reflects light from the core located in one portion into the core located in the other portion.

Abstract: A method of polishing a first layer of a semiconductor wafer down to a second layer of the semiconductor wafer is disclosed. One step of the method includes polishing the first layer of the semiconductor wafer with a polishing surface having a chemical slurry positioned thereon. The polishing step causes an infrared spectrum to be emitted through the semiconductor wafer. Another step of the method includes detecting a rate of change of intensity level of the infrared spectrum and generating a control signal in response thereto. The method also includes halting the polishing step in response to generation of the control signal. Polishing systems are also disclosed which determine a polishing endpoint for a semiconductor wafer based upon an infrared spectrum generated due to a chemical slurry reacting with the semiconductor wafer.

Abstract: The invention concerns the use of spin-on-glass (SOG) to bond two layers of semiconductor together, in order to form a Silicon-on-Insulator (SOI) structure. One type of SOG is a cross-linked siloxane polymer, preferably of the poly-organo-siloxane type, comprising a carbon content of at least 5 atomic weight percent.

Abstract: A method is shown for manufacturing a semiconductor device in which a silicon oxide film acts as an insulating film for electrically isolating conductive layers included in the semiconductor device. An oxynitride silicon-oxide-like film is formed containing fluorine, carbon and nitrogen and having a given dielectric constant by CVD method using a source gas which contains at least silicon, nitrogen, carbon, oxygen and fluorine contributors. By controlling the ratio of nitrogen to oxygen in the source gas as used in the CVD method, the ultimate nitrogen, carbon and fluorine concentrations in the film can be controlled and hence the dielectric constant of the film so produced.

Abstract: A low dielectric material is applied, as by spinning on, over the passivation layer of a semiconductor chip to fill the gaps which may exist between the top layer metal lines, and thereby minimize the possibility of cross talk which might otherwise be present between those lines.

Abstract: A method of planarizing a first side of a semiconductor wafer with a polishing system includes the step of polishing the first side of the wafer in order to remove material from the wafer. The method also includes the step of moving a lens of a confocal optical system between a number of lens positions so as to maintain focus on the first side of the wafer during the polishing step. The method further includes the step of determining a rate-of-movement value based on movement of the lens during the moving step. Moreover, the method includes the step of stopping the polishing step if the rate-of-movement value has a predetermined relationship with a movement threshold value. An apparatus for polishing a first side of a semiconductor wafer is also disclosed.

Abstract: Techniques for fabricating metal-insulator-metal (MIM) capacitive structures by chemical vapor deposition (CVD) help avoid the formation of a porous metal oxide film at the interface between the lower electrode and the insulating layer. One method of fabricating an integrated circuit includes depositing a first titanium nitride electrode layer on a wafer by CVD and subsequently depositing an insulating layer on the first electrode. The insulating layer can comprise a material selected from the group consisting of titanium oxide (TiOx), titanium oxynitride (TiOxNy), titanium oxycarbonitride (TiOxNyCz) and silicon oxide (SiOx), and is deposited by CVD without exposing the first titanium nitride electrode to atmosphere. A second titanium nitride electrode layer also is deposited on the insulating layer by CVD. The various layers of the capacitive structure, including the insulating layer, can be deposited in situ in a single CVD chamber.

Abstract: The present invention provides a method and apparatus for conditioning a polishing pad in which slurry is directed under pressure at the polishing pad. Additionally, energy (i.e., ultrasonic energy) may be added to the slurry as it is directed towards the polishing pad, wherein embedded material in the polishing pad is removed or dislodged.

Abstract: A method of creating a layer-to-layer alignment mark in a semiconductor wafer includes the step of depositing a first conductor layer on a substrate associated with the semiconductor wafer. The method also includes the step of fabricating a number of alignment trenches in the first conductor layer. Moreover, the method includes the step of depositing a first insulator layer on the first conductor layer so as to fill the number of alignment trenches. Yet further, the method includes the step of removing material associated with the first insulator layer from the number of alignment trenches such that an upper surface of the first conductor layer and an upper surface of the first insulator layer define a first alignment step feature which possesses a predetermined height. The method also includes the step of depositing a second conductor layer on the semiconductor wafer subsequent to the removing step. A semiconductor wafer is also disclosed.