Abstract: An exemplary implementation of the invention is a process for forming passivation protection on a semiconductor assembly by the steps of: forming a layer of oxide over patterned metal lines having sidewalls; forming a first passivation layer of silicon nitride over the layer of oxide such that the first passivation layer of silicon nitride resides along the sidewalls of metal lines and pinches off a gap between the metal lines; performing a facet etch to remove material from the edges of the first passivation layer of silicon nitride and re-deposits some of removed material across a pinch-off junction; forming a second passivation layer of silicon nitride on the first passivation layer of silicon nitride.

Abstract: A method of forming electrical contacts includes the step of implanting ions into a contact hole at an angle to create an enlarged plug enhancement region at the bottom of a contact hole. Thus, even if the contact hole is misaligned, over-sized, or over-etched, the enlarged plug enhancement region contains subsequently formed barrier layers and other conductive materials to reduce current leakage into the underlying substrate or into adjacent circuit elements.

Abstract: A method used during the manufacture of a semiconductor device comprises providing at least first, second, and third spaced conductive structures, where the second conductive structure is interposed between the first and third conductive structures. A first dielectric is formed over these conductive structures, then a portion of the first dielectric layer is removed which forms a hole in the dielectric layer to expose the second conductive structure. Subsequently, the second conductive structure is removed to leave a void or tunnel in the dielectric layer where the second conductive structure had previously existed. Finally, a second dielectric layer is provided to fill the hole but to leave the void or tunnel in the dielectric layer subsequent to the formation of the second dielectric layer. An inventive structure resulting from the inventive method is also described.

Abstract: A fill pattern for a semiconductor device such as a memory cell. The memory cell includes a plurality of first topographic structures comprising conductive lead lines deposited on a semiconductor substrate, and a plurality of second topographic structures comprising fill patterns such that the top surfaces of the second topographic structures are generally coplanar with the top surfaces of the plurality of first topographic structures. The plurality of first and second topographic structures are arranged in a generally repeating array on the substrate. A planarization layer is deposited on top of the substrate such that it fills the space between the plurality of first and second topographic structures, with its top surface generally coplanar with that of the top surfaces of the first and second topographic structures.

Abstract: A method for fabricating an integrated circuit using a photo-lithographic process includes the steps of placing at least two anti-reflective coating layers between a reflective surface and another material. The indices of refraction, absorptions, and thicknesses of the at least two anti-reflective coating layers are chosen such that the amplitudes and phase differences of radiation reflected from the anti-reflective coating layers, as well as any other reflective surfaces below the anti-reflective coating layers, mutually cancel when combined. The invention may be practiced using more than two layers of anti-reflective coating. Multiple layers of anti-reflective coating may be used below an inter-level dielectric, in which case they may serve the additional purpose of functioning as an etch-stop.

Abstract: An integrated circuit having at least one electrical interconnect for connecting at least two components and a process for forming the same are disclosed. The integrated circuit comprises: a substrate, a plurality of adjacent conductive strips, a layer of dielectric material, and a conductive material. The substrate has a surface and the plurality of adjacent conductive strips is disposed on the substrate surface with each adjacent conductive strip having a length. The layer of dielectric material is deposited over the substrate surface and over and around the plurality of adjacent conductive strips to form at least two opposing, contoured, merging dielectric surfaces, each of which overhangs the substrate surface located between at least two of the plurality of adjacent conductive strips. The at least two opposing, contoured, merging dielectric surfaces define at least one elongated passageway which has at least one opening and is substantially encased therein and which extends along the length.

Abstract: A method used during the manufacture of a semiconductor device comprises providing at least first, second, and third spaced conductive structures, where the second conductive structure is interposed between the first and third conductive structures. A first dielectric is formed over these conductive structures, then a portion of the first dielectric layer is removed which forms a hole in the dielectric layer to expose the second conductive structure. Subsequently, the second conductive structure is removed to leave a void or tunnel in the dielectric layer where the second conductive structure had previously existed. Finally, a second dielectric layer is provided to fill the hole but to leave the void or tunnel in the dielectric layer subsequent to the formation of the second dielectric layer. An inventive structure resulting from the inventive method is also described.

Abstract: The invention includes a method of forming a conductive interconnect. An electrical node location is defined to be supported by a silicon-containing substrate. A silicide is formed in contact with the electrical node location. The silicide is formed by exposing the substrate to hydrogen, TiCl4 and plasma conditions to cause Ti from the TiCl4 to combine with silicon of the substrate to form TiSix. Conductively doped silicon material is formed over the silicide. The conductively doped silicon material is exposed to one or more temperatures of at least about 800° C. The silicide is also exposed to the temperatures of at least about 800° C.

Abstract: An exemplary implementation of the invention is a process for forming passivation protection on a semiconductor assembly by the steps of: forming a layer of oxide over patterned metal lines having sidewalls; forming a first passivation layer of silicon nitride over the layer of oxide such that the first passivation layer of silicon nitride resides along the sidewalls of metal lines and pinches off a gap between the metal lines; performing a facet etch to remove material from the edges of the first passivation layer of silicon nitride and re-deposits some of removed material across a pinch-off junction; forming a second passivation layer of silicon nitride on the first passivation layer of silicon nitride.

Abstract: The invention includes a method of forming a conductive interconnect. An electrical node location is defined to be supported by a silicon-containing substrate. A silicide is formed in contact with the electrical node location. The silicide is formed by exposing the substrate to hydrogen, TiCl4 and plasma conditions to cause Ti from the TiCl4 to combine with silicon of the substrate to form TiSix. Conductively doped silicon material is formed over the silicide. The conductively doped silicon material is exposed to one or more temperatures of at least about 800° C. The silicide is also exposed to the temperatures of at least about 800° C.

Abstract: An integrated circuit having at least one electrical interconnect for connecting at least two components and a process for forming the same are disclosed. The integrated circuit comprises: a substrate, a plurality of adjacent conductive strips, a layer of dielectric material, and a conductive material. The substrate has a surface and the plurality of adjacent conductive strips is disposed on the substrate surface with each adjacent conductive strip having a length. The layer of dielectric material is deposited over the substrate surface and over and around the plurality of adjacent conductive strips to form at least two opposing, contoured, merging dielectric surfaces, each of which overhangs the substrate surface located between at least two of the plurality of adjacent conductive strips. The at least two opposing, contoured, merging dielectric surfaces define at least one elongated passageway which has at least one opening and is substantially encased therein and which extends along the length.

Abstract: An integrated circuit having at least one electrical interconnect for connecting at least two components and a process for forming the same are disclosed.

Abstract: An integrated circuit having at least one electrical interconnect for connecting at least two components and a process for forming the same are disclosed.

Abstract: Titanium-containing films exhibiting excellent uniformity and step coverage are deposited on semiconductor wafers in a cold wall reactor which has been modified to discharge plasma into the reaction chamber. Titanium tetrabromide, titanium tetraiodide, or titanium tetrachloride, along with hydrogen, enter the reaction chamber and come in contact with a heated semiconductor wafer, thereby depositing a thin titanium-containing film on the wafer's surface. Step coverage and deposition rate are enhanced by the presence of the plasma. The use of titanium tetrabromide or titanium tetraiodide instead of titanium tetrachloride also increases the deposition rate and allows for a lower reaction temperature. Titanium silicide and titanium nitride can also be deposited by this method by varying the gas incorporated with the titanium precursors.

Abstract: Titanium-containing films exhibiting excellent uniformity and step coverage are deposited on semiconductor wafers in a cold wall reactor which has been modified to discharge plasma into the reaction chamber. Titanium tetrabromide, titanium tetraiodide, or titanium tetrachloride, along with hydrogen, enter the reaction chamber and come in contact with a heated semiconductor wafer, thereby depositing a thin titanium-containing film on the wafer's surface. Step coverage and deposition rate are enhanced by the presence of the plasma. The use of titanium tetrabromide or titanium tetraiodide instead of titanium tetrachloride also increases the deposition rate and allows for a lower reaction temperature. Titanium silicide and titanium nitride can also be deposited by this method by varying the gas incorporated with the titanium precursors.

Abstract: A method of forming a contact to a semiconductor memory device feature comprises the steps of forming a first oxide layer over a feature such as a semiconductor substrate or a conductive line or plate, then forming a hard mask over the first oxide layer. A first patterned resist layer is formed on the hard mask, then the hard mask is patterned using the first resist layer as a pattern. The first resist layer is removed and a second oxide layer is formed over the hard mask. A second patterned resist layer is formed over the second oxide layer and the second oxide layer is etched using the second resist layer as a pattern while, during a single etch step, the first oxide layer is etched using the hard mask as a pattern, the hard mask functioning as an etch stop.

Abstract: A method and structure is disclosed that are advantageous for aligning a contact plug within a bit line contact corridor (BLCC) to an active area of a DRAM that utilizes a insulated sleeve structure. A lower bulk insulator layer, a capacitor dielectric layer, a cell plate conductor layer, and an upper bulk insulator layer are formed upon a semiconductor substrate. An etch removes the cell plate conductor layer, the capacitor dielectric layer, and the lower bulk insulator layer so as to form an opening terminating within the lower bulk insulator layer. A sleeve insulator layer is deposited upon the upper bulk insulator layer and within the opening. Another etch removes the sleeve insulator layer from the bottom surface within the lower bulk insulator layer. A still further etch creates a contact hole that expose a contact. The contact can be upon a transistor gate, a capacitor storage node, or an active region on the semiconductor substrate.

Abstract: Integrated circuitry capacitors and methods of forming the same are described. In accordance with one implementation, a capacitor plate is formed and a conductive layer of material is formed thereover. Preferably, the conductive layer of material is more conductive than the material from which the capacitor plate is formed. In a preferred implementation, the conductive layer of material comprises a titanium or titanium-containing layer. In another preferred implementation, the capacitor plate comprises an inner capacitor plate having an outer surface with a generally roughened surface area. In one aspect of this implementation, the roughened surface area comprises hemispherical grain polysilicon. Capacitors formed in accordance with the invention are particularly well suited for use in dynamic random access memory (DRAM) circuitry.

Abstract: An exemplary implementation of the invention is a process for forming passivation protection on a semiconductor assembly by the steps of: forming a layer of oxide over patterned metal lines having sidewalls; forming a first passivation layer of silicon nitride over the layer of oxide such that the first passivation layer of silicon nitride resides along the sidewalls of metal lines and pinches off a gap between the metal lines; performing a facet etch to remove material from the edges of the first passivation layer of silicon nitride and re-deposits some of removed material across a pinch-off junction; forming a second passivation layer of silicon nitride on the first passivation layer of silicon nitride.

Abstract: A method for fabricating an integrated circuit using a photo-lithographic process includes the steps of placing at least two anti-reflective coating layers between a reflective surface and another material. The indices of refraction, absorptions, and thicknesses of the at least two anti-reflective coating layers are chosen such that the amplitudes and phase differences of radiation reflected from the anti-reflective coating layers, as well as any other reflective surfaces below the anti-reflective coating layers, mutually cancel when combined. The invention may be practiced using more than two layers of anti-reflective coating. Multiple layers of anti-reflective coating may be used below an inter-level dielectric, in which case they may serve the additional purpose of functioning as an etch-stop.