Abstract: A rapid thermal annealing (“RTA”) process providing for an RTA equipment is disclosed. The RTA equipment has a pyrometer providing for measuring an operation parameter, e.g., a temperature of the RTA process. The RTA process comprises steps of proceeding a first RTA step to a wafer in the RTA equipment, then comparing a measured value of the operation parameter with a reference range of value of the operation parameter, thereafter proceeding a second RTA step to the wafer in the RTA equipment when the measured value of the operation parameter is in between the reference range of value of the operation parameter. When the measured value of the operation parameter is out of the reference range of value of the operation parameter, the RTA equipment is turned off, and the wafer is unloaded from the RTA equipment and loaded into another RTA equipment to complete the RTA process.

Abstract: A method is provided for forming features in a polyimide layer that is employed as an insulating layer or buffer layer during the fabrication of semiconductor devices or chip packaging structures. A pattern is formed in a photosensitive layer that has a high film retention after the development step and a crosslinked network that strengthens and stabilizes it for subsequent processing. The process involves exposing a negative tone photosensitive layer with a first exposure dose that is less than the normal dose used to image the material. The exposed layer is developed to provide a scum free substrate. A second exposure dose then strengthens the formed image by crosslinking unreacted components. First and second exposure doses are determined from a plot of film thickness loss vs. exposure energy. The method applies to photosensitive polyimide precursors as well as negative photoresists that are crosslinked by free radical or chemical amplification mechanisms.

Abstract: An apparatus and a method for forming a substrate having a palladium metal layer over at least one contact point of the substrate and having a flexible conductive polymer bump, preferably a two-stage epoxy, on the palladium plated contact point, are provided. The present invention also relates to assemblies comprising one or more of these substrates.

Abstract: There is provided a light emitting device in which low power consumption can be realized even in the case of a large screen. The surface of a source signal line or a power supply line in a pixel portion is plated to reduce a resistance of a wiring. The source signal line in the pixel portion is manufactured by a step different from a source signal line in a driver circuit portion. The power supply line in the pixel portion is manufactured by a step different from a power supply line led on a substrate. A terminal is similarly plated to made the resistance reduction. It is desirable that a wiring before plating is made of the same material as a gate electrode and the surface of the wiring is plated to form the source signal line or the power supply line.

Abstract: A conductive layer which is formed on an insulative layer on a semiconductor substrate is connected to the semiconductor substrate via a through portion which passes through the insulative layer and reaches the semiconductor substrate. In a state where the conductive layer is electrically connected to the semiconductor substrate via the through portion, a patterning process using a plasma etching is performed on the conductive layer, thereby forming a conductive path. After the formation of the conductive path, a heating process is performed on the substrate or the conductive path in order to disconnect the electrical connection between the through portion and the substrate by a reaction between the through portion and the semiconductor substrate which is in contact therewith.

Abstract: The present invention provides a semiconductor transistor using an L-shaped spacer. The semiconductor transistor includes a gate pattern formed on a semiconductor substrate and an L-shaped third spacer formed beside the gate pattern and having a horizontal protruding portion. An L-shaped fourth spacer is formed between the third spacer and the gate pattern, and between the third spacer and the substrate. A high-concentration junction area is positioned in the substrate beyond the third spacer, and a low-concentration junction area is positioned under the horizontal protruding portion of the third spacer. A medium-concentration junction area is positioned between the high- and low-concentration junction areas.

Abstract: Methods of forming a nano-scale electronic and optoelectronic devices include forming a substrate having a semiconductor layer therein and a substrate insulating layer on the semiconductor layer. An etching template having a first array of non-photolithographically defined nano-channels extending therethrough, is formed on the substrate insulating layer. This etching template may comprise an anodized metal oxide, such as an anodized aluminum oxide (AAO) thin film. The substrate insulating layer is then selectively etched to define a second array of nano-channels therein. This selective etching step preferably uses the etching template as an etching mask to transfer the first array of nano-channels to the underlying substrate insulating layer, which may be thinner than the etching template. An array of semiconductor nano-pillars is then formed in the second array of nano-channels. The semiconductor nano-pillars in the array may have an average diameter in a range between about 8 nm and about 50 nm.

Abstract: A storage capacitor has a double cylinder type structure, with a small cylinder in a lower part thereof and a cylindrical lower electrode structure disposed on the cylindrical contact plug. A method of fabricating the storage capacitor includes: forming a contact hole for exposing an activation region of a transistor; depositing a conductive film to form within the contact hole a contact plug of the storage capacitor having a void therein; opening an upper part of the void of the contact plug; and covering a surface of the device with material to form the storage capacitor electrode, to obtain the storage capacitor electrode having a double cylindrical structure.

Abstract: A process gas consisting of one of N2, N2O or a mixture thereof is converted to a plasma and then a surface of a copper wiring layer is exposed to the plasma of the process gas, whereby a surface portion of the copper wiring layer is reformed and made into a copper diffusion preventing barrier. According to this method, a noble semiconductor device can be provided having increased operational speed and less copper diffusion.

Abstract: A first interlayer insulating film (3) having low dielectric constant is formed on an underlying insulating film (2) and a second interlayer insulating film (4) is formed on the first interlayer insulating film (3). Subsequently, a photoresist (5) having a pattern with openings above regions in which copper wirings are to be formed is formed on the second interlayer insulating film (4). Using the photoresist (5) as an etching mask, the second interlayer insulating film (4) and the first interlayer insulating film (3) are etched, to form a recess (6). Next, an ashing process using oxygen gas plasma (7) is performed, to remove the photoresist (5). This ashing process is performed under a plasma forming condition that the RF power is 300 W, the chamber pressure is 30 Pa, the oxygen flow is 100 sccm and the substrate temperature is 25° C.

Abstract: A method for fabricating a semiconductor device, in which a sufficient misalignment margin is obtained when forming interconnections and contact holes, is provided. Dielectric layer patterns which define recesses in which damascene interconnections are to be formed, are formed. Then, first contact holes between the dielectric layer patterns are etched, and the first contact holes and the recesses are concurrently filled with a conductive material. The recesses can be filled with the conductive material by performing an etch-back process. The dielectric layer patterns are then etched, thereby forming the damascene interconnections and concurrently covering only a region in which second contact holes are to be formed with the dielectric layer patterns. Spaces between the dielectric layer patterns are filled with a mask layer, and then the dielectric layer patterns are selectively removed from the resultant structure, thereby forming the second contact holes aligned with the damascene interconnections.

Abstract: A light-emitting diode with which the LED chip will not be destroyed comprises an LED chip 40 mounted on plate-shaped wiring means 60 inside a light-emitting diode. Wiring means 60 comprises conductive paths 61 and 62 that electrically lead to a pair of opposing surfaces. The top surface is used for mounting the LED chip. Part of the conductive paths 61, 62 are connected electrically to LED chip 40, extending from the position where the LED is mounted to leads 21 and 22, to which they are connected by soldering. LED chip 40 is supported by being held inside concave part 23 in one lead 21 at this time.

Abstract: A semiconductor device enabling word lines to be arranged at close intervals, comprising a plurality of memory transistors arranged in an array and a plurality of word lines serving also as gate electrodes of memory transistors in a same row, extending in a row direction, and repeating in a column direction, where insulating films are formed between the plurality of word lines to insulate and isolate the word lines from each other and where a dimension of separation of word lines is defined by the thickness of the insulating films.

Abstract: A semiconductor chip carrier having an increased chip connector and plated through hole density. In particular, a substrate having a plurality of plated through holes therein, and a fatigue resistant redistribution layer thereon. The redistribution layer includes a plurality of vias selectively positioned over and contacting the plated through holes. The substrate further including a ground plane, two pair of signal planes, and two pair of power planes, wherein the second pair of power planes are located directly underneath the external dielectric layer. A buried plated through hole within the substrate.

Abstract: A method is provided for manufacturing a semiconductor device on a semiconductor substrate using a dielectric as a bottom anti-reflective coating for formation of a photoresist contact opening which is used to enlarge the Final Inspection Critical Dimension (FICD) of the conductive contact. A high selectivity etch is used to form a tapered contact.

Abstract: A new process is provided for the creation of sub-micron conductive lines and patterns. A conductive layer is deposited over the surface of a substrate, a sacrificial layer that differs with the conductive layer in etch characteristics is deposited over the surface of the conductive layer. The sacrificial layer is patterned and etched, creating an opening in the sacrificial layer that aligns with but is larger in cross section than the to be created sub-micron conductive lines and patterns. A spacer layer is deposited over the surface of which a hard mask layer is deposited, filling the opening in the sacrificial layer. The hard mask layer is polished down to the surface of the spacer layer, leaving the hard mask layer in place overlying the spacer layer inside the opening created in the sacrificial layer.

Abstract: The reliability and performance of planarized metallization patterns in an electrical device, for example copper, inlaid in the surface of a layer of dielectric material overlying a semiconductor wafer substrate, are enhanced by a method for reliably depositing a barrier layer selective to the metallization patterns. The method comprises forming a sacrificial dielectric layer above a substrate. Metallization patterns are formed in the sacrificial dielectric layer. The barrier layer is selectively deposited on the metallization patterns. Portions of the barrier material undesirably deposited on the sacrificial dielectric layer are removed by removing the sacrificial dielectric layer, thus preventing bridging of adjacent metallization features by the barrier layer portions. An interlevel dielectric layer is then formed in place of the sacrificial dielectric layer.

Abstract: A low-k dielectric sacrificial material is formed within a microelectronic structure covered with a layer defining an exhaust vent. At an appropriate time, the underlying sacrificial material is decomposed and exhausted away through the exhaust vent. Residue from the exhausted sacrificial material accumulates at the vent location during exhaustion until the vent is substantially occluded. As a result, an air gap is created having desirable characteristics as a dielectric.

Abstract: A heterogeneous device comprises a substrate and a plurality of heterogeneous circuit devices defined in the substrate. In embodiments, a plurality of heterogeneous circuit devices are integrated by successively masking and ion implanting the substrate. The heterogeneous device may further comprise at least one microelectromechanical system-based element and/or at least one photodiode. In embodiments, the heterogeneous circuit devices comprise at least one CMOS transistor and at least one DMOS transistor. In embodiments, the substrate comprises a layer of silicon or a layer of p-type silicon. In other embodiments, the substrate comprises a silicon-on-insulator wafer comprising a single-crystal-silicon layer or a single-crystal-P-silicon layer, a substrate and an insulator layer therebetween.

Abstract: A structure and a method for forming buffer cells in power line areas between macro cell in a macro block area. In a power line level, a pin is formed between VSS and VDD lines. The pin is connected to the buffer cell. Next a signal line layer is formed and the signal line is connected to the pin and to a driver. In a first embodiment the driver is formed in a standard cell area. In a second embodiment, the driver is formed in a macro cell. A signal line is connected to the pin and the driver.