Abstract: A semiconductor processing method of forming an oxynitride film on a silicon substrate comprises placing a substrate in a reactor, the substrate having an exposed silicon surface, and combining nitrogen, oxygen, and fluorine in gaseous form in the reactor under temperature and pressure conditions effective to grow an oxynitride film on the exposed silicon surface. According to a preferred aspect, the nitrogen and the oxygen are provided in the reactor from decomposition of a compound containing atomic nitrogen and oxygen. A semiconductor processing method of forming a dielectric composite film on a silicon substrate is also described.

Abstract: A microelectronic device includes a field oxide isolation pad which extends from a trench formed in a microelectronic substrate by a height which is less than approximately two times the height of a gate structure formed on the microelectronic substrate. Spacers are formed around the gate structures, although little or no spacer forms around the isolation pad.

Abstract: Processes are disclosed which facilitate improved high density memory circuitry, most preferably dynamic random access memory (DRAM) circuitry. In accordance with aspects of the invention, considerably greater numbers of die sites per wafer are achieved for 6 inch, 8 inch and 12 inch wafers for 4M, 16M, 64M and 256M integration levels. Further, a semiconductor memory device includes, i) a plurality of functional and operably addressable memory cells arranged in multiple memory arrays formed on a semiconductor die; and ii) circuitry formed on the semiconductor die permitting data to be written to and read from one or more of the memory cells, at least one of the memory arrays containing at least 100 square microns of continuous die surface area having at least 170 of the functional and operably addressable memory cells.

Abstract: A method of forming a thin film transistor relative to a substrate includes, a) providing a thin film transistor layer of polycrystalline material on a substrate, the polycrystalline material comprising grain boundaries; b) providing a fluorine containing layer adjacent the polycrystalline thin film layer; c) annealing the fluorine containing layer at a temperature and for a time period which in combination are effective to drive fluorine from the fluorine containing layer into the polycrystalline thin film layer and incorporate fluorine within the grain boundaries to passivate said grain boundaries; and d) providing a transistor gate operatively adjacent the thin film transistor layer. The thin film transistor can be fabricated to be bottom gated or top gated. A buffering layer can be provided intermediate the thin film transistor layer and the fluorine containing layer, with the buffering layer being transmissive of fluorine from the fluorine containing layer during the annealing.

Abstract: This invention is a process for forming an effective titanium nitride barrier layer between the upper surface of a polysilicon plug formed in a thick dielectric layer and a platinum lower capacitor plate in a dynamic random access memory which is being fabricated on a silicon wafer.

Abstract: A method of forming a thin film transistor relative to a substrate includes, a) providing a thin film transistor layer of polycrystalline material on a substrate, the polycrystalline material comprising grain boundaries; b) providing a fluorine containing layer adjacent the polycrystalline thin film layer; c) annealing the fluorine containing layer at a temperature and for a time period which in combination are effective to drive fluorine from the fluorine containing layer into the polycrystalline thin film layer and incorporate fluorine within the grain boundaries to passivate said grain boundaries; and d) providing a transistor gate operatively adjacent the thin film transistor layer. The thin film transistor can be fabricated to be bottom gated or top gated. A buffering layer can be provided intermediate the thin film transistor layer and the fluorine containing layer, with the buffering layer being transmissive of fluorine from the fluorine containing layer during the annealing.

Abstract: This invention is a process for forming an effective titanium nitride barrier layer between the upper surface of a polysilicon plug formed in a thick dielectric layer and a platinum lower capacitor plate in a dynamic random access memory which is being fabricated on a silicon wafer.

Abstract: A method of forming a capacitor includes, a) providing a node to which electrical connection to a first capacitor plate is to be made; b) then, providing a finned lower capacitor plate in ohmic electrical connection with the node using no more than one photomasking step; and c) providing a capacitor dielectric layer and a conductive second capacitor plate layer over the conductive layer.

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: Processes are disclosed which facilitate improved high density memory circuitry, most preferably dynamic random access memory (DRAM) circuitry. In accordance with aspects of the invention, considerably greater numbers of die sites per wafer are achieved for 6 inch, 8 inch and 12 inch wafers for 4 M, 16 M, 64 M and 256 M integration levels. Further, a semiconductor memory device includes, i) a plurality of functional and operably addressable memory cells arranged in multiple memory arrays formed on a semiconductor die; and ii) circuitry formed on the semiconductor die permitting data to be written to and read from one or more of the memory cells, at least one of the memory arrays containing at least 100 square microns of continuous die surface area having at least 170 of the functional and operably addressable memory cells.

Abstract: A method of forming a thin film transistor relative to a substrate includes, a) providing a thin film transistor layer of polycrystalline material on a substrate, the polycrystalline material comprising grain boundaries; b) providing a fluorine containing layer adjacent the polycrystalline thin film layer; c) annealing the fluorine containing layer at a temperature and for a time period which in combination are effective to drive fluorine from the fluorine containing layer into the polycrystalline thin film layer and incorporate fluorine within the grain boundaries to passivate said grain boundaries; and d) providing a transistor gate operatively adjacent the thin film transistor layer. The thin film transistor can be fabricated to be bottom gated or top gated. A buffering layer can be provided intermediate the thin film transistor layer and the fluorine containing layer, with the buffering layer being transmissive of fluorine from the fluorine containing layer during the annealing.

Abstract: A method of forming a capacitor includes, a) providing a node to which electrical connection to a first capacitor plate is to be made; b) then, providing a finned lower capacitor plate in ohmic electrical connection with the node using no more than one photomasking step; and c) providing a capacitor dielectric layer and a conductive second capacitor plate layer over the conductive layer.

Abstract: A capacitor for high density DRAM applications comprises a high-∈ capacitor dielectric such as BST or PZT in an arrangement which obviates the need for barrier layers during fabrication. The fabrication process allows for electrode placement by simple sputter deposition and further provides for the possibility of capacitor spacing below that of conventional lithographic techniques.

Abstract: A semiconductor processing method of forming an electrically conductive contact plug relative to a wafer includes, a) providing a substrate to which electrical connection is to be made; b) depositing a layer of first material atop the substrate to a selected thickness; c) pattern masking the first material layer for formation of a desired contact opening therethrough; d) etching through the first material layer to form a contact opening therethrough for making electrical connection with the substrate, the contact opening having an outermost region; e) after etching to form the contact opening, removing the masking from the first material layer; f) after removing the masking from the first material layer, facet sputter etching into the first material layer relative to the contact opening to provide outwardly angled sidewalls which effectively widen the contact opening outermost region, the outwardly angled sidewalls having an inner base where they join with the original contact opening; g) depositing a layer o

Abstract: A capacitor construction includes, a) first and second electrically conductive capacitor plates separated by an intervening capacitor dielectric layer, the first capacitor plate comprising first and second container members, the second container member being received inside of the first container member, the first and second container members comprising a respective ring portion and a respective base portion; and b) a pedestal disk positioned elevationally intermediate the first container member base and the second container member base to space and support the second container member relative to the first container member. The structure is preferably produced by using a series of alternating first and second layers of semiconductive material provided over a molding layer within a container contact opening therein.

Abstract: A method of forming a thin film transistor relative to a substrate includes, a) providing a thin film transistor layer of polycrystalline material on a substrate, the polycrystalline material comprising grain boundaries; b) providing a fluorine containing layer adjacent the polycrystalline thin film layer; c) annealing the fluorine containing layer at a temperature and for a time period which in combination are effective to drive fluorine from the fluorine containing layer into the polycrystalline thin film layer and incorporate fluorine within the grain boundaries to passivate said grain boundaries; and d) providing a transistor gate operatively adjacent the thin film transistor layer. The thin film transistor can be fabricated to be bottom gated or top gated. A buffering layer can be provided intermediate the thin film transistor layer and the fluorine containing layer, with the buffering layer being transmissive of fluorine from the fluorine containing layer during the annealing.

Abstract: A method of forming a capacitor includes, a) providing a node to which electrical connection to a first capacitor plate is to be made; b) then, providing a finned lower capacitor plate in ohmic electrical connection with the node using no more than one photomasking step; and c) providing a capacitor dielectric layer and a conductive second capacitor plate layer over the conductive layer.

Abstract: A method of forming a capacitor includes, a) providing a node to which electrical connection to a first capacitor plate is to be made; b) then, providing a finned lower capacitor plate in ohmic electrical connection with the node using no more than one photomasking step; and c) providing a capacitor dielectric layer and a conductive second capacitor plate layer over the conductive layer.

Abstract: A method of forming a dielectric layer includes, a) chemical vapor depositing a dielectric layer of Ta2O5 atop a substrate; and b) providing a predominately amorphous diffusion barrier layer over the Ta2O5 dielectric layer. A method of forming a capacitor includes, a) providing a node to which electrical connection to a capacitor is to be made; b) providing a first electrically conductive capacitor plate over the node; c) chemical vapor depositing a capacitor dielectric layer of Ta2O5 over the first electrically conductive capacitor plate; and d) providing a predominately amorphous diffusion barrier layer over the Ta2O5 dielectric layer. A capacitor construction is also disclosed. The preferred amorphous diffusion barrier layer is electrically conductive and constitutes a metal organic chemical vapor deposited TiCxNy Dz, where “x” is in the range of from 0.01 to 0.5, and “y” is in the range of from 0.99 to 0.5, and “z” is in the range of from 0 to 0.

Abstract: A capacitor for high density DRAM applications comprises a high-.di-elect cons. capacitor dielectric such as BST or PZT in an arrangement which obviates the need for barrier layers during fabrication. The fabrication process allows for electrode placement by simple sputter deposition and further provides for the possibility of capacitor spacing below that of conventional lithographic techniques.