Abstract: A method for forming NMOS and PMOS transistors that includes cutting a substrate along a higher order orientation and fabricating deep sub-micron NMOS and PMOS transistors on the vertical surfaces thereof. The complementary NMOS and PMOS transistors form a CMOS transistor pair. The transistors are preferably used in structures such as memory circuits, e.g., DRAMs, which are, in turn, used in a processor-based system. Ideally, the deep sub-micron NMOS and PMOS transistors are operated in velocity saturation for optimal switching operation.

Abstract: Methods of forming electrical connections with an integrated circuitry substrate node location are described. According to one aspect of the invention, a substrate node location is laterally surrounded with insulating material and left outwardly exposed. Conductive material is deposited over the exposed node location. Subsequently, a photomaskless etch of the conductive material is conducted to a degree sufficient to leave a plug of conductive material over the node location. In a preferred implementation, the insulating material with which such node location is surrounded constitutes insulating material portions which are provided relative to conductive lines which are formed over the substrate. In another preferred implementation, such conductive lines form a grid of insulating material which, in turn, defines the node location.

Abstract: A memory cell and a method of fabricating the memory cell having a small active area. By forming a spacer in a window that is sized at the photolithographic limit, a pore may be formed in dielectric layer which is smaller than the photolithographic limit. Electrode material is deposited into the pore, and a layer of structure changing material, such as chalcogenide, is deposited onto the lower electrode, thus creating a memory element having an extremely small and reproducible active area.

Abstract: A microelectronic device fabricating method includes providing a substrate having a mean global outer surface extending along a plane. A first portion is formed over the substrate comprising a straight linear segment which is angled from the plane and forming a second portion over the substrate comprising a straight linear segment which is angled from the plane at a different angle than the first portion. A layer of structural material is formed over the first and second portions. The structural material layer is anisotropically etched and a first device feature is ultimately left over the first portion having a first base width and a second device feature is ultimately left over the second portion having a second base width which is different from the first base width. Integrated circuitry includes a substrate having a mean global outer surface extending along a plane.

Abstract: Memory integrated circuitry includes an array of memory cells formed over a semiconductive substrate and occupying area thereover, at least some memory cells of the array being formed in lines of active area formed within the semiconductive substrate which are continuous between adjacent memory cells. Adjacent memory cells are isolated from one another relative to the continuous active area formed therebetween by a conductive line formed over said continuous active area between said adjacent memory cells. At least some adjacent lines of continuous active area within the array are isolated from one another by LOCOS field oxide formed therebetween. The respective area consumed by individual memory cells is less than 8F2, where “F” is no greater than 0.25 micron.

Abstract: Mechanical stress is diminished by forming an oxidation mask with silicon nitride having a graded silicon concentration. Grading is accomplished by changing the silicon content in the silicon nitride. The silicon nitride can be graded in a substantially linear or non-linear fashion. In one embodiment, the graded silicon nitride may be formed with one type of non-linear silicon grading, an abrupt junction. In other embodiments, the silicon nitride is formed in a variety of shapes fashioned during or after silicon nitride growth. In one embodiment, the stress is reduced by forming a polysilicon buffer layer between two silicon nitride layers. In another embodiment, stress is reduced by forming the silicon nitride on a pad layer, which in turn is formed on a base layer.

Abstract: A toy, such as a toy pager or a toy telephone, generates an attention signal and plays a recorded message to the user. The attention signal is generated in a seemingly random fashion to simulate the operation of a real pager or telephone.

Abstract: A patterning method includes providing a first material (e.g., copper) and transforming at a least a surface region of the first material to a second material (e.g., copper oxide). One or more portions of the second material (e.g., copper oxide) are converted to one or more converted portions of first material (e.g., copper) while one or more portions of the second material (e.g., copper oxide) remain. One or more portions of the remaining second material (e.g., copper oxide) are removed selectively relative to converted portions of first material (e.g., copper). Further, a thickness of the converted portions may be increased. Yet further, a diffusion barrier layer may be used for certain applications.

Abstract: Improved methods and structures are provided that are lateral to surfaces with a (110) crystal plane orientation such that an electrical current of such structures is conducted in the <110> direction. Advantageously, improvements in hole carrier mobility of approximately 50% can be obtained by orienting the structure's channel in a (110) plane such that the electrical current flow is in the <110> direction. Moreover, these improved methods and structures can be used in conjunction with existing fabrication and processing techniques with minimal or no added complexity.

Abstract: An apparatus and a method for photoreducing copper oxide layers from semiconductor wafers during the processes of forming interconnects in advanced IC manufacturing. The apparatus comprises a reaction chamber with a high intensity UV light source and a wafer holder in the chamber. The UV light source is made of arrays of microdischarge devices fabricated on a semiconductor wafer where each of the microdischarge devices has the structure of a hollow cathode. Multiple arrays of microdischarge devices can be assembled together to make a planar UV lamp so as to provide a sufficient area for the UV illumination. The wafer holder in the chamber is made rotatable for a better uniformity during the photoreduction process. A non-oxidizing gas is flowed into the chamber to prevent instant and subsequent oxidation on the copper surface.

Abstract: Stress resulting from silicon nitride is diminished by forming an oxidation mask with silicon nitride having a graded silicon concentration. Grading is accomplished by changing the silicon content in the silicon nitride by varying the amount of hydride, such as dichlorosilane (DCS), mixed with ammonia. The silicon nitride can be graded in a substantially linear or non-linear fashion. Silicon nitride formed with higher levels of DCS mixed with ammonia is referred to as silicon rich nitride because of its relatively higher silicon content. In one embodiment, the graded silicon nitride may be formed with one type of non-linear silicon grading, an abrupt junction. In other embodiments, the silicon nitride is formed in a variety of shapes fashioned during or after silicon nitride growth. In one embodiment, the stress from the silicon nitride is reduced by forming a polysilicon buffer layer between two silicon nitride layers.

Abstract: A patterning method includes providing a first material (e.g., copper) and transforming at a least a surface region of the first material to a second material (e.g., copper oxide). One or more portions of the second material (e.g., copper oxide) are converted to one or more converted portions of first material. (e.g., copper) while one or more portions of the second material (e.g., copper oxide) remain. One or more portions of the remaining second material (e.g., copper oxide) are removed selectively relative to converted portions of first material (e.g., copper). Further, a thickness of the converted portions may be increased. Yet further, a diffusion barrier layer may be used for certain applications.

Abstract: Methods of forming electrical connections with an integrated circuitry substrate node location are described. According to one aspect of the invention, a substrate node location is laterally surrounded with insulating material and left outwardly exposed. Conductive material is deposited over the exposed node location. Subsequently, a photomaskless etch of the conductive material is conducted to a degree sufficient to leave a plug of conductive material over the node location. In a preferred implementation, the insulating material with which such node location is surrounded constitutes insulating material portions which are provided relative to conductive lines which are formed over the substrate. In another preferred implementation, such conductive lines form a grid of insulating material which, in turn, defines the node location. According to a preferred aspect of the invention, a plurality of insulated conductive lines are formed over a substrate.

Abstract: Methods are disclosed for forming shaped structures from silicon and/or germanium containing material with a material removal process that is selective to low stress portions of the material. In general, the method initially provides a layer of the material on a semiconductor substrate. The material, which has uniform stress therein, is then masked, and the stress in a portion of the material is reduced, such as by implanting ions into an unmasked portion. The mask is removed, and either the high stress masked portion or the low stress unmasked portion of the material is selectively removed, preferably by an etching process. The portion of the material not removed remains and forms a shaped structure. The various methods are used to form raised shaped structures, shaped openings, polysilicon plugs, capacitor storage nodes, surround-gate transistors, free-standing walls, interconnect lines, trench capacitors, and trench isolation regions.

Abstract: Methods of forming capacitors, methods of forming capacitor-over-bit line memory circuitry, and related integrated circuitry constructions are described. In one embodiment, a capacitor storage node is formed having an uppermost surface and an overlying insulative material over the uppermost surface. Subsequently, a capacitor dielectric functioning region is formed discrete from the overlying insulative material operably proximate at least a portion of the capacitor storage node. A cell electrode layer is formed over the capacitor dielectric functioning region and the overlying insulative material.

Abstract: Methods of forming capacitors, methods of forming capacitor-over-bit line memory circuitry, and related integrated circuitry constructions are described. In one embodiment, a capacitor storage node is formed having an uppermost surface and an overlying insulative material over the uppermost surface. Subsequently, a capacitor dielectric functioning region is formed discrete from the overlying insulative material operably proximate at least a portion of the capacitor storage node. A cell electrode layer is formed over the capacitor dielectric functioning region and the overlying insulative material.

Abstract: Methods are disclosed for forming shaped structures from silicon and/or germanium containing material with a material removal process that is selective to low stress portions of the material. In general, the method initially provides a layer of the material on a semiconductor substrate. The material, which has uniform stress therein, is then masked, and the stress in a portion of the material is reduced, such as by implanting ions into an unmasked portion. The mask is removed, and either the high stress masked portion or the low stress unmasked portion of the material is selectively removed, preferably by an etching process. The portion of the material not removed remains and forms a shaped structure. The various methods are used to form raised shaped structures, shaped openings, polysilicon plugs, capacitor storage nodes, surround-gate transistors, free-standing walls, interconnect lines, trench capacitors, and trench isolation regions.

Abstract: Methods are disclosed for forming shaped structures from silicon and/or germanium containing material with a material removal process that is selective to low stress portions of the material. In general, the method initially provides a layer of the material on a semiconductor substrate. The material, which has uniform stress therein, is then masked, and the stress in a portion of the material is reduced, such as by implanting ions into an unmasked portion. The mask is removed, and either the high stress masked portion or the low stress unmasked portion of the material is selectively removed, preferably by an etching process. The portion of the material not removed remains and forms a shaped structure. The various methods are used to form raised shaped structures, shaped openings, polysilicon plugs, capacitor storage nodes, surround-gate transistors, free-standing walls, interconnect lines, trench capacitors, and trench isolation regions.

Abstract: A microelectronic device fabricating method includes providing a substrate having a mean global outer surface extending along a plane. A first portion is formed over the substrate comprising a straight linear segment which is angled from the plane and forming a second portion over the substrate comprising a straight linear segment which is angled from the plane at a different angle than the first portion. A layer of structural material is formed over the first and second portions. The structural material layer is anisotropically etched and a first device feature is ultimately left over the first portion having a first base width and a second device feature is ultimately left over the second portion having a second base width which is different from the first base width. Integrated circuitry includes a substrate having a mean global outer surface extending along a plane.

Abstract: An apparatus and a method for photoreducing copper oxide layers from semiconductor wafers during the processes of forming interconnects in advanced IC manufacturing. The apparatus comprises a reaction chamber with a high intensity UV light source and a wafer holder in the chamber. The UV light source is made of arrays of microdischarge devices fabricated on a semiconductor wafer where each of the microdischarge devices has the structure of a hollow cathode. Multiple arrays of microdischarge devices can be assembled together to make a planar UV lamp so as to provide a sufficient area for the UV illumination. The wafer holder in the chamber is made rotatable for a better uniformity during the photoreduction process. A non-oxidizing gas is flowed into the chamber to prevent instant and subsequent oxidation on the copper surface.