Abstract: Methods of planarizing structures formed on the surfaces of substrates and wafers are disclosed. The methods form a planarizing layer over the surface and the structures, or the locations where the structures are to be formed, such that the top surface of the layer has low areas between the locations of the structures, and such that the low areas lie substantially within a plane which is below the tops of the structures. A polish-stop layer is then formed over the low areas of the planarizing layer, the polish-stop layer being more resistant to polishing than the planarizing layer and, preferably, the structures. The resulting surface is then polished. The polishing may be accomplished by, for example, standard mechanical polishing, and chemical-mechanical polishing.

Abstract: An air-gap spacer of a metal-oxide-semiconductor device comprises a spacer and a cross-sectional L-shaped air-gap. The spacer is adjacent to a sidewall of the gate electrode but not directly contacts to the gate electrode. The cross-sectional L-shaped air-gap is located between the spacer and the gate electrode and between the spacer and the substrate so that the spacer is separated from the gate electrode and the spacer is partially separated from the substrate.

Abstract: A method is provided for fabricating a read-only memory (ROM) device of the type including an array of diode-based memory cells for permanent storage of binary-coded data. The ROM device is partitioned into a memory division and an output division. The memory cells are formed over an insulating layer in the memory division. The insulating layer separates the memory cells from the underlying substrate such that the leakage current that can otherwise occur therebetween can be prevented. Moreover, the coding process is performing by forming contact windows at selected locations rather than by performing ion-implantation as in conventional methods. The fabrication process is thus easy to perform. Since the memory cells are diode-based rather than MOSFET-based, the punch-through effect that usually occurs in MOSFET-based memory cells can be prevented.

Abstract: A ROM device of the type including an array of diode-type memory cells and a method for fabricating the same are provided. The bit lines of this ROM device are a plurality of diffusion regions formed in an alternate manner on the bottom of a plurality of parallel-spaced trenches and on the top of the solid portions between these trenches. This particular arrangement of the bit lines allows for an increased integration of the diode-type memory cells on a limited wafer surface without having to reduce the feature size of the semiconductor components of the ROM device. The diode-type memory cells that are set to a permanently-ON state involve a P-N junction diode being formed therein, wherein the P-N junction diode is electrically connected via a contact window in an insulating layer to the associated one of the overlaying word lines. Other memory cells that are set to a permanently-OFF state are formed with no P-N junction diode therein.

Abstract: A method for forming shallow trench isolation comprising the steps of providing a substrate having a mask layer formed thereon. Next, the mask layer is patterned to form a first trench in the substrate. Then, dielectric spacers are formed on the sidewalls of the first trench. After that, a second trench is formed in the substrate by an etching operation following the profile of the dielectric spacers. Next, a second dielectric layer is formed filling the second trench, wherein the second dielectric layer and the dielectric spacers are formed from different materials. Thereafter, the dielectric spacers are removed to form recess cavities, and then a filler material is deposited into the recess cavities. Subsequently, a gate oxide layer is formed over the filler material and the substrate. Finally, a polysilicon gate layer is formed over the gate oxide layer.

Abstract: Methods of wet etching through a silicon substrate using composite etch-stop layers are disclosed. In one embodiment, the composite etch stop comprises a layer of silicon dioxide and a layer of polyimide.

Abstract: A method of reducing the fringe capacitance between a gate and a substrate in a semiconductor device. A silicon nitride is formed over a substrate with a buffer oxide layer thereon and patterned to form an opening. The buffer oxide layer within the opening is removed and another oxide layer is formed at the same place as a gate oxide layer. A poly-gate is formed at the opening with a wider width than the opening. Thus, a part of the poly-gate at both ends covers a part of the silicon nitride layer. The silicon nitride layer is then removed and leaves the poly-gate as a T-shape with two ends suspended over the substrate. With a large angle, a light dopant is implanted into the substrate under the suspended part of the poly-gate to form a lightly doped region. With another smaller angle, a heavy dopant is implanted into the substrate beside the poly-gate. Therefore, a source/drain is formed.

Abstract: A selective switch includes a switch housing, and a button cap with two opposite side portions. A contact assembly includes first, second and third conductive members which are all fixed in the switch housing. A helical spring is mounted in the switch housing, and has an outer end portion to support the button cap thereon and an inner end portion adjacent to the contact assembly. A flexible mandrel has an inner end portion and an outer end portion which is integrally formed with the outer end portion of the helical spring. The helical spring extends around the flexible mandrel.

Abstract: An improved bearing mechanism works in conjunction with the control rod of a vertical blind system or a roller shade system to provide superior bearing and load handling capability. A conical bore has a plurality of grooves into the surface of the conical bore. A series of cylindrical rollers are supported within the grooves, and against a central rotational member having a conical surface for bearing against the rollers. A set screw is used to control the seating of the central rotational member within the conical bore, is used to make up any tolerance created through the manufacturing process, and can be used to increase the tension necessary to hold a roller shade in place.

Abstract: The channel doping profile of a PMOS field effect transistor consists of a shallow distribution of a P-type dopant as a threshold adjust implant, a deeper distribution of an N-type dopant as an buried channel stop implant and a still deeper implantation of an N-type dopant as an antipunchthrough implant. A junction is formed between the P-type threshold adjust implant and the N-type buried channel stop implant at a relatively shallow depth so that the depth of the buried channel region is limited by the buried channel stop implant, reducing the short channel effect. The channel doping profile is formed so that diffusion of impurities from the channel region to the gate oxide is prevented. The buried channel stop implant is made first through a sacrificial oxide layer. The sacrificial oxide is etched and a gate oxide layer and a thin film of polysilicon are deposited on the surface of the gate oxide.

Abstract: A method of fabricating a metal-oxide semiconductor (MOS) transistor is provided. This method is devised particularly to reduce the level of degradation to the MOS transistor caused by hot carriers. In the fabrication process, a plasma treatment is applied to the wafer to as to cause the forming of a thin layer of silicon nitride on the wafer which covers the gate and the lightly-doped diffusion (LDD) regions on the source/drain regions of the MOS transistor. This thin layer of silicon nitride acts as a barrier which prevents hot carriers from crossing the gate dielectric layer, such that the degradation of the MOS transistor due to hot carriers crossing the gate dielectric layer can be greatly minimized.

Abstract: An interposer substrate for mounting an integrated circuit chip to a substrate, and method of making the same, are shown. The interposer substrate comprises power supply paths and controlled impedance signal paths that are substantially isolated from each other. Power supply is routed though rigid segments and signals are routed though a thin film flexible connector that runs from the upper surface of the interposer substrate to the lower surface. Bypass capacitance is incorporated into the interposer substrate and connected to the power supply so that it is positioned very close to the integrated circuit chip. The interposer may be fabricated by forming a multilayered thin film structure including the signal paths over a rigid substrate having vias formed therein, removing the central portion of the substrate leaving the two end segments, and folding and joining the end segments such that the vias are connected.

Abstract: A socket-compatible plug which includes a plug body with a plurality of holes, plurality of plug pins respectively insertable into selected ones of the plurality holes, and a medium mounted into respective selected ones of the plural holes for urging selected ones of the plurality of plug pins beyond the respectively selected ones of the plurality of holes. The plug further includes a back cover. The plurality of holes of the plug body includes a medium-mounting hole and the selected ones of the plurality of holes. Each of the selected ones can include a plug pin positioning region and a medium positioning region. The plug pin positioning region can include an upper edge and the plug pin includes a flange engaged with the upper edge. The back cover urges the medium to the medium positioning region, while the plug body is assembled with the back cover.

Abstract: An improved system utilizes a series of structures which permit magnetic closure to be used in existing carriers and components. Magnetic support structures include members which ride in the carrier, as well as special size members which mount in the lead or wand carrier and which reside in the vertical blind track end caps. All of the structures are installable as retro-fit and which can work with existing tracks, carriers and end caps, even though these structures have been optimized for small size.

Abstract: The improved system utilizes a track (51) which has a bowed internal surface to prevent the wheel of the carrier (17) from frictional engagement with the side of the track (51). The curved surface (55) which faces the wheels (27) will not be engaged by the wheels (27) even where the carrier (17) turns to one side or the other. This is accomplished while leaving the innermost portions of the raceway (53) in the same width position with regard to the wheels (27) as is usual to prevent the carrier (17) from coming off-track. The tolerances for the inner corners of the raceway (53) opposing the wheels (27) may be reduced to further prevent the possibility of jamming in the track (51).

Abstract: A method of fabricating flat-cell mask ROM devices having buried bit-lines that will not be subject to punch-through between neighboring bit lines as a result of heating in subsequent steps after the buried bit-lines are formed. In the method, the first step is to prepare a semiconductor substrate with a gate oxide layer formed thereon. Thereafter, a first polysilicon layer is formed over the gate oxide layer, and a plurality of trenches at predetermined positions, with these trenches extending through the gate oxide and first polysilicon layer and into the substrate to a predetermined depth. Then, trenches are filled with tungsten to form a plurality of source/drain regions. A second polysilicon layer is then formed over the first polysilicon layer, and an insulating layers is formed over each of the source/drain regions.

Abstract: A diode-based ROM device and a method for fabricating the same are provided. The ROM device is of the type including an array of diode-based memory cells for permanent storage of binary-coded data therein. In the semiconductor structure of the ROM device, a plurality of insulator-filled trenches are formed for isolation of the diode-based memory cells. This feature allows the prevention of the punch-through effect when the ROM device is downsized. Further, the bit lines for the ROM device are formed with an increased junction depth such that the resistance of the bit lines can be reduced to allow an increase in the magnitude of the currents in the bit lines for easier detection and distinguishing of the binary state the currents represent.

Abstract: A mechanical-type automatic circuit-breaking appliance switch assembly includes a switch housing, a switch unit, an elongate switch actuator and a biasing member. The switch housing is formed with a slide channel and is formed with an opening that is aligned with the slide channel. The switch unit is disposed in the switch housing adjacent to the slide channel. The switch unit has contact terminals that extend out of the switch housing, and a switch contact that faces the slide channel and that is capable of being pressed to operate the switch unit from a circuit-breaking state to a circuit-making state. The switch actuator is received in the slide channel and has first and second portions.

Abstract: A ROM device of the type including an array of diode-type memory cells and a method for fabricating the same are provided. The bit lines of this ROM device are a plurality of diffusion regions formed in an alternate manner on the bottom of a plurality of parallel-spaced trenches and on the top of the solid portions between these trenches. This particular arrangement of the bit lines allows for an increased integration of the diode-type memory cells on a limited wafer surface without having to reduce the feature size of the semiconductor components of the ROM device. The diode-type memory cells that are set to a permanently-ON state involve a P-N junction diode being formed therein, wherein the P-N junction diode is electrically connected via a contact window in an insulating layer to the associated one of the overlaying word lines. Other memory cells that are set to a permanently-OFF state are formed with no P-N junction diode therein.