Abstract: A method of forming memory circuitry having a memory array having a plurality of memory capacitors and having peripheral memory circuitry operatively configured to write to and read from the memory array, includes forming a dielectric well forming layer over a semiconductor substrate. A portion of the well forming layer is removed effective to form at least one well within the well forming layer. An array of memory cell capacitors is formed within the well. The peripheral memory circuitry is formed laterally outward of the well forming layer memory array well. In one implementation, memory circuitry includes a semiconductor substrate. A plurality of word lines is received over the semiconductor substrate. An insulative layer is received over the word lines and the substrate. The insulative layer has at least one well formed therein. The well has a base received over the word lines. The well peripherally defines an outline of a memory array area.

Abstract: A method used to manufacture a semiconductor device comprises providing a first conductive container capacitor top plate layer and etching the first conductive container capacitor top plate layer to form a plurality of openings therein. Subsequently, a container capacitor bottom plate layer is formed within the plurality of openings in the top plate layer such that the bottom plate layer defines a plurality of openings. A second conductive container capacitor top plate layer is formed within the plurality of openings in the bottom plate layer. The first conductive container capacitor top plate layer is electrically coupled with the second conductive container capacitor top plate layer. The first and second conductive container capacitor top plate layers and the container capacitor bottom plate layer form a plurality of container capacitors. A structure resulting from the method is also disclosed.

Abstract: The present invention prevents cross-linking between multiple resists that are used in the fabrication of a semiconductor device. In order to prevent resists in close proximity or contact with one another from cross-linking, a non-reactive separation layer is disposed between the resists. The separation layer prevents incompatible components of the resists from reacting with one another. Forming the separation layer between the resists allows a resist located above the separation layer to be polymerized and patterned as desired without patterning another resist located below the separation layer. Methods of patterning multiple resists are also disclosed.

Abstract: A method used to form a semiconductor device comprises forming a layer such as a container capacitor layer having a bottom plate layer. The bottom plate layer is formed to define a receptacle, and a rim which defines an opening to an interior of the receptacle. The bottom plate layer is formed to have a smooth texture. Subsequently, an inhibitor layer is formed on the rim of the bottom plate layer while a majority of the receptacle defined by the bottom plate layer remains free from the inhibitor. With the inhibitor layer on the rim of the bottom plate layer, at least a portion of the receptacle is converted to have a rough texture, such as to hemispherical silicon grain (HSG) polysilicon, while subsequent to the conversion the smooth texture of the rim which defines the opening to the interior of the receptacle remains. A resulting structure is also described.

Abstract: A method used to form a semiconductor device comprises forming a layer such as a container capacitor layer having a bottom plate layer. The bottom plate layer is formed to define a receptacle, and a rim which defines an opening to an interior of the receptacle. The bottom plate layer is formed to have a smooth texture. Subsequently, an inhibitor layer is formed on the rim of the bottom plate layer while a majority of the receptacle defined by the bottom plate layer remains free from the inhibitor. With the inhibitor layer on the rim of the bottom plate layer, at least a portion of the receptacle is converted to have a rough texture, such as to hemispherical silicon grain (HSG) polysilicon, while subsequent to the conversion the smooth texture of the rim which defines the opening to the interior of the receptacle remains. A resulting structure is also described.

Abstract: A method of forming memory circuitry having a memory array having a plurality of memory capacitors and having peripheral memory circuitry operatively configured to write to and read from the memory array, includes forming a dielectric well forming layer over a semiconductor substrate. A portion of the well forming layer is removed effective to form at least one well within the well forming layer. An array of memory cell capacitors is formed within the well. The peripheral memory circuitry is formed laterally outward of the well forming layer memory array well. In one implementation, memory circuitry includes a semiconductor substrate. A plurality of word lines is received over the semiconductor substrate. An insulative layer is received over the word lines and the substrate. The insulative layer has at least one well formed therein. The well has a base received over the word lines. The well peripherally defines an outline of a memory array area.

Abstract: A capacitor including a first plate of conductive material that is formed in a predetermined shape. A layer of dielectric material is formed on at least a portion of the first plate and substantially conforms to the predetermined shape of the first plate. A second plate of conductive material is formed over the layer of dielectric material.

Abstract: A method of forming memory circuitry having a memory array having a plurality of memory capacitors and having peripheral memory circuitry operatively configured to write to and read from the memory array, includes forming a dielectric well forming layer over a semiconductor substrate. A portion of the well forming layer is removed effective to form at least one well within the well forming layer. An array of memory cell capacitors is formed within the well. The peripheral memory circuitry is formed laterally outward of the well forming layer memory array well. In one implementation, memory circuitry includes a semiconductor substrate. A plurality of word lines is received over the semiconductor substrate. An insulative layer is received over the word lines and the substrate. The insulative layer has at least one well formed therein. The well has a base received over the word lines. The well peripherally defines an outline of a memory array area.

Abstract: A method of forming memory circuitry having a memory array having a plurality of memory capacitors and having peripheral memory circuitry operatively configured to write to and read from the memory array, includes forming a dielectric well forming layer over a semiconductor substrate. A portion of the well forming layer is removed effective to form at least one well within the well forming layer. An array of memory cell capacitors is formed within the well. The peripheral memory circuitry is formed laterally outward of the well forming layer memory array well. In one implementation, memory circuitry includes a semiconductor substrate. A plurality of word lines is received over the semiconductor substrate. An insulative layer is received over the word lines and the substrate. The insulative layer has at least one well formed therein. The well has a base received over the word lines. The well peripherally defines an outline of a memory array area.

Abstract: A method of forming memory circuitry having a memory array having a plurality of memory capacitors and having peripheral memory circuitry operatively configured to write to and read from the memory array, includes forming a dielectric well forming layer over a semiconductor substrate. A portion of the well forming layer is removed effective to form at least one well within the well forming layer. An array of memory cell capacitors is formed within the well. The peripheral memory circuitry is formed laterally outward of the well forming layer memory array well. In one implementation, memory circuitry includes a semiconductor substrate. A plurality of word lines is received over the semiconductor substrate. An insulative layer is received over the word lines and the substrate. The insulative layer has at least, one well formed therein. The well has a base received over the word lines. The well peripherally defines an outline of a memory array area.

Abstract: A method of forming memory circuitry having a memory array having a plurality of memory capacitors and having peripheral memory circuitry operatively configured to write to and read from the memory array, includes forming a dielectric well forming layer over a semiconductor substrate. A portion of the well forming layer is removed effective to form at least one well within the well forming layer. An array of memory cell capacitors is formed within the well. The peripheral memory circuitry is formed laterally outward of the well forming layer memory array well. In one implementation, memory circuitry includes a semiconductor substrate. A plurality of word lines is received over the semiconductor substrate. An insulative layer is received over the word lines and the substrate. The insulative layer has at least one well formed therein. The well has a base received over the word lines. The well peripherally defines an outline of a memory array area.

Abstract: A method of forming memory circuitry having a memory array having a plurality of memory capacitors and having peripheral memory circuitry operatively configured to write to and read from the memory array, includes forming a dielectric well forming layer over a semiconductor substrate. A portion of the well forming layer is removed effective to form at least one well within the well forming layer. An array of memory cell capacitors is formed within the well. The peripheral memory circuitry is formed laterally outward of the well forming layer memory array well. In one implementation, memory circuitry includes a semiconductor substrate. A plurality of word lines is received over the semiconductor substrate. An insulative layer is received over the word lines and the substrate. The insulative layer has at least one well formed therein. The well has a base received over the word lines. The well peripherally defines an outline of a memory array area.

Abstract: In one aspect of the invention, an amorphous layer of silicon is provided which has a gradient of thickness variation. The amorphous layer of silicon is transformed into a hemispherical grain polysilicon layer that has varying grain size therein. In another aspect of the invention, a material is provided and has an upper surface and inwardly tapered openings. A first electrically conductive electrode layer is formed within the openings and includes a plurality of hemispherical grain polysilicon layers. At least one of the hemispherical grain polysilicon layers has a grain size gradient defined by a smaller grain size in a region proximate the upper surface and a larger grain size beneath the region with the smaller grain size. An electrically insulative layer is formed over the first electrode layer and a second electrically conductive electrode layer is formed over the electrically insulative layer.

Abstract: A method of forming memory circuitry having a memory array having a plurality of memory capacitors and having peripheral memory circuitry operatively configured to write to and read from the memory array, includes forming a dielectric well forming layer over a semiconductor substrate. A portion of the well forming layer is removed effective to form at least one well within the well forming layer. An array of memory cell capacitors is formed within the well. The peripheral memory circuitry is formed laterally outward of the well forming layer memory array well. In one implementation, memory circuitry includes a semiconductor substrate. A plurality of word lines is received over the semiconductor substrate. An insulative layer is received over the word lines and the substrate. The insulative layer has at least one well formed therein. The well has a base received over the word lines. The well peripherally defines an outline of a memory array area.

Abstract: In one aspect of the invention, an amorphous layer of silicon is provided which has a gradient of thickness variation. The amorphous layer of silicon is transformed into a hemispherical grain polysilicon layer that has varying grain size therein. In another aspect of the invention, a material is provided and has an upper surface and inwardly tapered openings. A first electrically conductive electrode layer is formed within the openings and includes a plurality of hemispherical grain polysilicon layers. At least one of the hemispherical grain polysilicon layers has a grain size gradient defined by a smaller grain size in a region proximate the upper surface and a larger grain size beneath the region with the smaller grain size. An electrically insulative layer is formed over the first electrode layer and a second electrically conductive electrode layer is formed over the electrically insulative layer.