Abstract: A test arrangement is designed to test whether one in a chain of vias or contacts has abnormally high resistance. The arrangement contains a plurality of via or contact chains and a plurality of decoders. The chains are switchably connected to a resistance measurement device. Each decoder has a unique address such that it will generate a control signal when a predetermined address is address thereon. The control signal is used to close a switch, which connect one of the chains to the resistance measurement device. By sequentially applying different addresses to the decoders, the resistance of the chains can be individually measured.

Abstract: For IC devices that have repeating structures, a method of generating a database for making a mask layer starts with a hierarchical database describing at least one repeating element in the layer, a skeleton that surrounds the repeating elements, and instructions as to where to locate the repeating elements within the skeleton. This database is modified to generate a database that has optical proximity correction (OPC) for diffraction of light that will pass through the mask and expose photoresist on the IC layer. The optical-proximity corrected mask database is fractured by a mask house using instructions on how the modified data base will be divided to form repeating elements that are still identical after OPC, a mask skeleton that includes non-repeating elements, and instructions for placement of the repeating elements in the skeleton. Thus the resulting mask database is smaller than a mask database that includes all copies of repeating elements.

Abstract: A test arrangement is designed to test whether one in a chain of vias or contacts has abnormally high resistance. The arrangement contains a plurality of via or contact chains and a plurality of decoders. The chains are switchably connected to a resistance measurement device. Each decoder has a unique address such that it will generate a control signal when a predetermined address is address thereon. The control signal is used to close a switch, which connect one of the chains to the resistance measurement device. By sequentially applying different addresses to the decoders, the resistance of the chains can be individually measured.

Abstract: A test arrangement is designed to test whether one in a chain of vias or contacts has abnormally high resistance. The arrangement contains a plurality of via or contact chains and a plurality of decoders. The chains are switchably connected to a resistance measurement device. Each decoder has a unique address such that it will generate a control signal when a predetermined address is address thereon. The control signal is used to close a switch, which connect one of the chains to the resistance measurement device. By sequentially applying different addresses to the decoders, the resistance of the chains can be individually measured.

Abstract: A method of developing a transistor, such as a complimentary MOS (CMOS) transistor, that includes lightly doped drain (LDD) regions which uses disposable spacers, and includes the step of adding an oxide spacer etch after a disposable nitride spacer removal and between source/drain implant and LDD implant. Because of this additional step, an ultra shallow LDD implant can be achieved. Moreover, uniformity of the depth of the junction is improved as the non-uniformity of the screen/liner oxide is eliminated.

Abstract: A test arrangement is designed to test whether one in a chain of vias or contacts has abnormally high resistance. The arrangement contains a plurality of via or contact chains and a plurality of decoders. The chains are switchably connected to a resistance measurement device. Each decoder has a unique address such that it will generate a control signal when a predetermined address is address thereon. The control signal is used to close a switch, which connect one of the chains to the resistance measurement device. By sequentially applying different addresses to the decoders, the resistance of the chains can be individually measured.

Abstract: A test arrangement is designed to test whether one in a chain of vias or contacts has abnormally high resistance. The arrangement contains a plurality of via or contact chains and a plurality of decoders. The chains are switchably connected to a resistance measurement device. Each decoder has a unique address such that it will generate a control signal when a predetermined address is address thereon. The control signal is used to close a switch, which connect one of the chains to the resistance measurement device. By sequentially applying different addresses to the decoders, the resistance of the chains can be individually measured.

Abstract: Critical dimension variation of photolithographically formed features on a semiconductor substrate is reduced by measuring the reflectivity of a photoresist layer and an underlying layer, such as a polysilicon layer, and adjusting the exposure level of the photoresist in accordance with the measured reflectivity. This allows precise control of feature width on the photoresist, which in turn allows precision etching of the underlying layer to accurately form a feature, such as a gate electrode.

Abstract: CMOS semiconductor devices comprising MOS transistors of different channel conductivity type are formed in or on a common semiconductor substrate using a minimum number of critical masks. Embodiments include forming conductive gate/insulator layer stacks on spaced-apart, different conductivity portions of the main surface of the substrate, forming etch-resistant inner sidewall spacers on side surfaces of the layer stacks, and forming easily etched, amorphous semiconductor disposable outer sidewall spacers on the inner sidewall spacers. The use of disposable outer sidewall spacers allows heavy and light source/drain implantations of opposite conductivity type to be performed for forming PMOS and NMOS transistors with the use of only two critical masks, thereby reducing production cost and duration, while increasing manufacturing throughput.

Abstract: The CD variation of semiconductor devices on a wafer due to the variation in thickness of the underlying nitride layer is corrected by varying the lithographic exposure level as a function of the nitride layer thickness. Embodiments include decreasing the exposure level in areas where the nitride layer is relatively thicker.

Abstract: CMOS transistors, i.e., N- and P-type transistors, are formed with substantially the same gate length and source/drain regions with lightly doped extensions. Embodiments include sequentially: ion implanting an N-type impurity, e.g. As, to form the N- type transistor shallow source/drain implants; forming relatively thin first sidewall spacers on the gates of both transistors; ion implanting a P-type impurity, e.g. BF2, to form shallow source/drain extension implants for the P-type transistor; forming relatively thick side wall spacers on the first sidewall spacers of both transistors; ion implanting, e.g. As, to form moderately or heavily doped N-type implants; activation annealing at a first temperature, e.g., about 1050° C. to form the shallow N- and P-type source/drain extensions and moderately or heavily doped P-type source/drain regions; ion implanting a P-type impurity, e.g.

Abstract: Metal oxide semiconductor devices are formed having gates with minimum endcap width and no source/drain leakage. A pair of source/drain regions is formed in a substrate, and a gate oxide is formed on the substrate. A layer of a conductive material, such as polysilicon, is formed on the gate oxide layer, masked and etched to form an extended-width gate having endcaps of a greater width than the endcap design rules. A second mask is formed to cover the extended-width gate up to the desired width of the endcaps (i.e., the design width) and to expose the portions of the extended-width gate beyond the endcap design width. The exposed portions of the extended-width gate are then etched, resulting in a completed gate having endcaps of the design width. Since the endcaps are initially formed to a greater width than the design width, any pullback that occurs during printing of the mask or etching of the gate does not cause the gate to be insufficiently wide to avoid source/drain leakage.

Abstract: Semiconductor devices of different conductivity types with optimized junction locations are formed on a semiconductor substrate using a minimal number of critical masks. Embodiments include forming conductive gates on the main surface of the semiconductor substrate, sidewall spacers on side surfaces of the gates, and aluminum disposable spacers on the sidewall spacers. A photoresist mask is then formed on gates and portions of the main surface intended to be implanted with impurities of a first conductivity type. Moderate or heavy source/drain implants of a second impurity type are then formed in the substrate, the aluminum disposable spacers on the sidewall spacers on the unmasked gates removed, and lightly or moderately doped source/drain extension implants of the second impurity type formed in the substrate. The first mask is then removed and a second photoresist mask is formed on the previously uncovered gates and implanted portions of the main surface.

Abstract: MOS semiconductor devices of different conductivity types are formed on a semiconductor substrate using a minimal number of critical masks. Embodiments include forming conductive gates on the main surface of the semiconductor substrate, and disposable aluminum sidewall spacers on the side surfaces of the gates. A photoresist mask is then formed on gates and portions of the main surface intended to be implanted with impurities of a first conductivity type. Moderate or heavy source/drain implants of a second impurity type are then formed in the substrate, the aluminum sidewall spacers on the unmasked gates are then removed, and lightly or moderately doped source/drain extension implants of the second impurity type are formed in the substrate. The first mask is then removed and a second photoresist mask is formed on the previously uncovered gates and implanted portions of the main surface.

Abstract: Semiconductor devices of different conductivity types with optimized junction locations are formed on a semiconductor substrate using a minimal number of critical masks. Embodiments include forming conductive gates on the main surface of the semiconductor substrate, sidewall spacers on side surfaces of the gates, and nitride disposable spacers on the sidewall spacers. A photoresist mask is then formed on gates and portions of the main surface intended to be implanted with impurities of a first conductivity type. Moderate or heavy source/drain implants of a second impurity type are then formed in the substrate, the nitride disposable spacers on the sidewall spacers on the unmasked gates removed, and lightly or moderately doped source/drain extension implants of the second impurity type formed in the substrate. The first mask is then removed and a second photoresist mask is formed on the previously uncovered gates and implanted portions of the main surface.

Abstract: Semiconductor devices of different conductivity types are formed on a semiconductor substrate using a minimal number of critical masks. Embodiments include forming conductive gates on the main surface of the semiconductor substrate, and disposable amorphous silicon spacers on the sidewalls of the gates. A photoresist mask is then formed on gates and portions of the main surface intended to be implanted with impurities of a first conductivity type. Moderate or heavy source/drain implants of a second impurity type are then formed in the substrate, the disposable spacers on the unmasked gates are then removed, and lightly or moderately doped source/drain extension implants of the second impurity type are formed in the substrate. The first mask is then removed and a second photoresist mask is formed on the previously uncovered gates and implanted portions of the main surface.

Abstract: A method of developing a transistor, such as a complimentary MOS (CMOS) transistor, that includes lightly doped drain (LDD) regions which uses disposable spacers, and includes the step of adding an oxide spacer etch after a disposable nitride spacer removal and between source/drain implant and LDD implant. Because of this additional step, an ultra shallow LDD implant can be achieved. Moreover, uniformity of the depth of the junction is improved as the non-uniformity of the screen/liner oxide is eliminated.

Abstract: Semiconductor devices of different conductivity types are formed on a semiconductor substrate using a minimal number of critical masks. Embodiments include forming conductive gates on the main surface of the semiconductor substrate, and disposable nitride spacers on the sidewalls of the gates. A photoresist mask is then formed on gates and portions of the main surface intended to be implanted with impurities of a first conductivity type. Moderate or heavy source/drain implants of a second impurity type are then formed in the substrate, the disposable spacers on the unmasked gates are then removed, and lightly or moderately doped source/drain extension implants of the second impurity type are formed in the substrate. The first mask is then removed and a second photoresist mask is formed on the previously uncovered gates and implanted portions of the main surface.