Abstract: The invention is a storage cell capacitor and a method for forming the storage cell capacitor having a storage node electrode comprising a barrier layer interposed between a conductive plug and an oxidation resistant layer. A thick insulative layer protects the sidewalls of the barrier layer during the deposition and anneal of a dielectric layer having a high dielectric constant. The method comprises forming the conductive plug in a thick layer of insulative material such as oxide or oxide/nitride. The conductive plug is recessed from a planarized top surface of the thick insulative layer. The barrier layer is then formed in the recess. The process is continued with a formation of a second insulative layer, a potion of which is removed to form an opening exposing a portion of the barrier layer. An oxidation resistant conductive layer is deposited in the recess and forms at least a portion the storage node electrode of the capacitor.

Abstract: The invention is a storage cell capacitor and a method for forming the storage cell capacitor having a storage node electrode comprising a barrier layer interposed between a conductive plug and an oxidation resistant layer. A layer of titanium silicide is fabricated to lie between the conductive plug and the oxidation resistant layer. A thick insulative layer protects the sidewalls of the barrier layer during the deposition and anneal of a dielectric layer having a high dielectric constant. The method comprises forming the conductive plug in a thick layer of insulative material such as oxide or oxide/nitride. The conductive plug is recessed from a planarized top surface of the thick insulative layer. Titanium is deposited and a rapid thermal anneal is performed. The titanium reacts with silicide of the conductive plug to form TiSi at the bottom of the recess. Unreacted Ti is removed. The barrier layer is then formed in the recess.

Abstract: A stacked v-cell (SVC) capacitor using a modified stacked capacitor storage cell fabrication process. The SVC capacitor is made up of polysilicon structure, having a v-shaped cross-section, located at a buried contact and extending to an adjacent storage node overlaid by polysilicon with a dielectric sandwiched in between. The addition of the polysilicon structure increases storage capability 70% without enlarging the surface area defined for a normal stacked capacitor cell.

Abstract: A polysilicon layer is provided with a p-type impurity, and masked with an oxide mask to define a p-type region of the polysilicon layer. A second impurity is then provided into first unmasked regions of the polysilicon layer. A second oxide mask is deposited and anisotropically etched to form spacers adjacent to the first oxide mask. The spacers define two diffusion barrier regions of the polysilicon layer adjacent to the p-type region. An n-type impurity is then provided into second unmasked regions of the polysilicon layer to form two n-type regions adjacent the diffusion barrier regions. The diffusion barrier regions prevent cross diffusion of the p-type and the n-type impurities within the polysilicon layer, while also being of sufficient dimensions to permit normal p/n operations.

Abstract: Described is a process used during the formation of a semiconductor device to produce a doped layer of polycrystalline silicon having a pair of conductivity types using a single mask step. In a first embodiment, a patterned nonoxidizing layer is formed over the layer of polycrystalline silicon thereby leaving protected and exposed poly. The exposed polycrystalline silicon is doped, then oxidized, with the protected poly being free of oxidation. The nonoxidizing layer is stripped, and a blanket implant is performed. The oxidation prevents the previously doped polycrystalline silicon from being counterdoped. The oxidation is then stripped and wafer processing continues. In a second embodiment, a layer of resist is formed over the polycrystalline silicon layer, and the exposed poly is heavily doped with a material having a first conductivity type. The resist is removed, and the surface is blanket doped with a material having a second conductivity type.

Abstract: A polysilicon layer is provided with a p-type impurity, and masked with an oxide mask to define a p-type region of the polysilicon layer. A second impurity is then provided into first unmasked regions of the polysilicon layer. A second oxide mask is deposited and anisotropically etched to form spacers adjacent to the first oxide mask. The spacers define two diffusion barrier regions of the polysilicon layer adjacent to the p-type region. An n-type impurity is then provided into second unmasked regions of the polysilicon layer to form two n-type regions adjacent the diffusion barrier regions. The diffusion barrier regions prevent cross diffusion of the p-type and the n-type impurities within the polysilicon layer, while also being of sufficient dimensions to permit normal p/n operations.

Abstract: A stacked multi fingered cell (SMFC) capacitor using a modified stacked capacitor storage cell fabrication process. The SMFC is made up of polysilicon structure, having a multi-fingered cross-section, located at a buried contact and extending to an adjacent storage node overlaid by polysilicon with a dielectric sandwiched in between. The addition of the polysilicon structure increases storage capability 120% without enlarging the surface area defined for a normal stacked capacitor cell.

Abstract: A pad oxide is formed on a silicon substrate followed by a layer of polysilicon about 100 .ANG. thick. A silicon nitride layer is formed over said polysilicon layer then patterned with a first, fluorine-based, etch process to expose selected areas of the polysilicon layer. Then the exposed areas of polysilicon are removed using a second, chlorine-based, etch process fundamentally different from the first etch process. The high selectivity of the first etch process for nitride combined with the high selectivity of the second etch process for oxide, results in negligible CD loss in the overall process.

Abstract: A stacked v-cell (SVC) capacitor using a modified stacked capacitor storage cell fabrication process. The SVC capacitor is made up of polysilicon structure, having a v-shaped cross-section, located at a buried contact and extending to an adjacent storage node overlaid by polysilicon with a dielectric sandwiched in between. The addition of the polysilicon structure increases storage capability 70% without enlarging the surface area defined for a normal stacked capacitor cell.

Abstract: A polysilicon layer is provided with a p-type impurity, and masked with an oxide mask to define a p-type region of the polysilicon layer. A second impurity is then provided into first unmasked regions of the polysilicon layer. A second oxide mask is deposited and anisotropically etched to form spacers adjacent to the first oxide mask. The spacers define two diffusion barrier regions of the polysilicon layer adjacent to the p-type region. An n-type impurity is then provided into second unmasked regions of the polysilicon layer to form two n-type regions adjacent the diffusion barrier regions. The diffusion barrier regions prevent cross diffusion of the p-type and the n-type impurities within the polysilicon layer, while also being of sufficient dimensions to permit normal p/n operations.

Abstract: A stacked surrounding wall capacitor (SSWC) using a modified stacked capacitor storage cell fabrication process. The SSWC is made up of polysilicon structure, having an elongated v-shaped cross-section, located at a buried contact and extending to an adjacent storage node overlaid by polysilicon with a dielectric sandwiched in between. The addition of the polysilicon structure increases storage capability 50% without enlarging the surface area defined for a normal buried digit line stacked capacitor cell.

Abstract: A stacked comb spacer capacitor (SCSC) using a modified stacked capacitor storage cell fabrication process. The SCSC is made up of polysilicon structure, having a spiked v-shaped (or comb-shaped) cross-section, located at a buried contact and extending to an adjacent storage node overlaid by polysilicon with a dielectric sandwiched in between. The creation of the spiked polysilicon structure increases storage capability 50% without enlarging the surface area defined for a normal buried digit line stacked capacitor cell. Removing the dielectric residing under the backside of the storage node cell plate and filling that area with polysilicon increases storage capacity by an additional 50% or more.

Abstract: A semiconductor processing method of forming a resistor device includes, a) providing a layer of conductively doped polysilicon atop a substrate to a selected thickness, the layer of polysilicon having an upper surface and a base, the layer of polysilicon having grain boundaries therewithin which extend from the upper surface to the base and define polysilicon grains; b) oxidizing the polysilicon layer at a temperature from about 850.degree. C. to about 1050.degree. C. for a selected period of time to form SiO.sub.x within the polysilicon layer along the grain boundaries and down to the base to separate individual grains of polysilicon within the layer; and c) patterning the oxidized polysilicon layer to form a resistor device within an integrated circuit.

Abstract: A DRAM cell having a doped monocrystalline silicon substrate for the cell's lower capacitor plate whose surface has been texturized multiple times to enhance cell capacitance. After texturization, a thin silicon nitride layer is deposited on top of the texturized substrate, followed by the deposition of a poly layer, which functions as the cell's upper, or field, capacitor plate. The nitride layer, conformal and thin compared to the surface texture of the mono substrate, transfers the texture of the substrate to the cell plate layer. The effective capacitor plate area is substantially augmented, resulting in a cell capacitance increase of at least approximately fifty percent compared to a conventional planar cell utilizing identical wafer area.

Abstract: A stacked multi-fingered cell (SMFC) capacitor using a modified stacked capacitor storage cell fabrication process. The (SMFC) is made up of polysilicon structure, having a multi-fingered cross-section, located at a buried contact and extending to an adjacent storage node overlaid by polysilicon with a dielectric sandwiched in between. The addition of the polysilicon structure increases storage capability 120% without enlarging the surface area defined for a normal stacked capacitor cell.

Abstract: A process for fabricating, on the more or less vertical edge of a silicon mesa, a MOS field-effect transistor which has a spacer-shaped gate and a right-angled channel path. The process involves the following steps: creating a raised region (the mesa) on a planar silicon substrate; creation of a gate oxide layer on the substrate and vertical sidewalls of the mesa; blanket deposition of a gate layer (typically polysilicon); anisotropically etching the gate layer to expose the upper surface of the mesa and leave a stringer gate around the circumference thereof; and doping the upper surface of the mesa and regions of the substrate peripheral to the circumferential polysilicon stringer to create source and drain regions. The standard process provides device density approximately double that of standard FET fabrication processes. Density can be increased even further by increasing the number of silicon mesas with a minimum pitch distance.

Abstract: A method of fabricating a semiconductor wafer comprises providing an electrically conductive area on a semiconductor wafer. Multiple alternating layers of first and second materials are provided atop the wafer. The first and second materials need be selectively etchable relative to one another. The multiple layers are etched and the electrically conductive area upwardly exposed to define exposed edges of the multiple layers projecting upwardly from the electrically conductive area. One of the first or second materials is selectively isotropically etched relative to the other to produce indentations which extend generally laterally into the exposed edges of the multiple layers. A layer of electrically conductive material is applied atop the wafer and electrically conductive area, and fills the exposed edge indentations.

Abstract: A stacked v-cell (SVC) capacitor using a modified stacked capacitor storage cell fabrication process. The SVC capacitor is made up of a polysilicon structure, having a v-shaped cross-section, located at a buried contact and extending to an adjacent storage node overlaid by polysilicon with a dielectric sandwiched in between. The addition of the polysilicon structure increases storage capability 70% without enlarging the surface area defined for a normal stacked capacitor cell.

Abstract: A double dynamic random access memory (DRAM) cell comprising two vertically stacked access transistors and storage capacitors. A first access transistor is formed on a silicon substrate. A seed contact to the first access transistor is then utilized for growing an intermediate silicon substrate by Confined Lateral Selective Epitaxial Overgrowth (CLSEG). A second access transistor is formed upon the intermediate silicon substrate. A storage capacitor for the first access transistor may be formed as a trench capacitor in the silicon substrate. A storage capacitor for the second access transistor may be stacked on the second access transistor. A common buried bit line connects the two access transistors.

Abstract: A mushroom double stacked capacitor (mushroom cell) using a modified stacked capacitor storage cell fabrication process. The mushroom cell is made up of polysilicon structure, having a mushroom extended V-shaped cross-section. The storage node plate of the mushroom cell is overlaid by polysilicon with a dielectric sandwiched in between and connects to an access device's active area via a buried contact. The plate extends to an adjacent storage node but is isolated from the adjacent node by less than the critical resolution dimension of a given lithographic technology. The shape of the polysilicon structure increases storage capability 200% or more without enlarging the surface area defined for a normal buried digit line stacked capacitor cell.