Abstract: A trench-type storage device includes a trench in a substrate (100), with bundles of carbon nanotubes (202) lining the trench and a trench conductor (300) filling the trench. A trench dielectric (200) may be formed between the carbon nanotubes and the sidewall of the trench. The bundles of carbon nanotubes form an open cylinder structure lining the trench. The device is formed by providing a carbon nanotube catalyst structure on the substrate and patterning the trench in the substrate; the carbon nanotubes are then grown down into the trench to line the trench with the carbon nanotube bundles, after which the trench is filled with the trench conductor.

Abstract: A method of patterning which provides images substantially smaller than that possible by lithographic techniques is provided. In the method of the invention, a substrate has a memory layer and a sacrificial layer formed thereon. An image is patterned onto the memory layer by protecting an edge during an etching step using chemical oxide removal (COR) processes, for example. Another edge is memorized in the layer. The sacrificial layer is removed to expose another memorized edge, which is used to define a pattern in an underlying layer.

Abstract: The invention relates generally to a method for fabricating oxygen-implanted semiconductors, and more particularly to a method for fabricating oxygen-implanted silicon-on-insulation (“SOI”) type semiconductors by cutting-up regions into device-sized pieces prior to the SOI-oxidation process. The process sequence to make SOI is modified so that the implant dose may be reduced and relatively long and high temperature annealing process steps may be shortened or eliminated. This simplification may be achieved if, after oxygen implant, the wafer structure is sent to pad formation, and masking and etching. After the etching, annealing or oxidation process steps may be performed to create the SOI wafer.

Abstract: A trench-type storage device includes a trench in a substrate (100), with bundles of carbon nanotubes (202) lining the trench and a trench conductor (300) filling the trench. A trench dielectric (200) may be formed between the carbon nanotubes and the sidewall of the trench. The bundles of carbon nanotubes form an open cylinder structure lining the trench. The device is formed by providing a carbon nanotube catalyst structure on the substrate and patterning the trench in the substrate; the carbon nanotubes are then grown down into the trench to line the trench with the carbon nanotube bundles, after which the trench is filled with the trench conductor.

Abstract: Sublithographic contact apertures through a dielectric are formed in a stack of dielectric, hardmask and oxide-containing seed layer. An initial aperture through the seed layer receives a deposition of oxide by liquid phase deposition, which adheres selectively to the exposed vertical walls of the aperture in the seed layer. The sublithographic aperture, reduced in size by the thickness of the added material, defines a reduced aperture in the hardmask. The reduced hardmask then defines the sublithographic aperture through the dielectric.

Abstract: A process for forming a semiconductor device having an oxide beanie structure (an oxide cap overhanging an underlying portion of the device). An oxide layer is first provided covering that portion, with the layer having a top surface and a side surface. The top and side surfaces are then exposed to an oxide deposition bath, thereby causing deposition of oxide on those surfaces. Deposition of oxide on the top surface causes growth of the cap layer in a vertical direction and deposition of oxide on the side surface causes growth of the cap layer in a horizontal direction, thereby forming the beanie structure.

Abstract: A method for forming transistors with mutually-aligned double gates. The method includes the steps of (a) providing a wrap-around-gate transistor structure, wherein the wrap-around-gate transistor structure includes (i) semiconductor region, and (ii) a gate electrode region wrapping around the semiconductor region, wherein the gate electrode region is electrically insulated from the semiconductor region by a gate dielectric film; and (b) removing first and second portions of the wrap-around-gate transistor structure so as to form top and bottom gate electrodes from the gate electrode region, wherein the top and bottom gate electrodes are electrically disconnected from each other.

Abstract: A method (and structure) of forming an interconnect on a semiconductor substrate, includes forming a relatively narrow first structure in a dielectric formed on a semiconductor substrate, forming a relatively wider second structure in the dielectric formed on the semiconductor substrate, forming a liner in the first and second structures such that the first structure is substantially filled and the second structure is substantially unfilled, and forming a metallization over the liner to completely fill the second structure.

Abstract: The invention provides a method of forming a phase shift mask and the resulting phase shift mask. The method forms a non-transparent film on a transparent substrate and patterns an etch stop layer on the non-transparent film. The invention patterns the non-transparent film using the etch stop layer to expose areas of the transparent substrate. Next, the invention forms a mask on the non-transparent film to protect selected areas of the transparent substrate and forms a phase shift oxide on exposed areas of the transparent substrate. Subsequently, the mask is removed and the phase shift oxide is polished down to the etch stop layer, after which the etch stop layer is removed.

Abstract: A method for forming a gas dielectric with support structure on a semiconductor device structure provides low capacitance and adequate support for a conductor of the semiconductor device structure. A conductive structure, such as via or interconnect, is formed in a wing-layer dielectric. A support is then formed that connects to the conductive structure, the support including an area thereunder. The wiring-layer dielectric is then removed from the area to form a gas dielectric.

Abstract: A method (and structure) of forming an interconnect on a semiconductor substrate, includes forming a relatively narrow first structure in a dielectric formed on a semiconductor substrate, forming a relatively wider second structure in the dielectric formed on the semiconductor substrate, forming a liner in the first and second structures such that the first structure is substantially filled and the second structure is substantially unfilled, and forming a metallization over the liner to completely fill the second structure.

Abstract: A bitline contact and method of forming bitline contact for a vertical DRAM array using a bitline contact mask. In the method, gate conductor lines are formed. An oxide layer is deposited over the gate conductor lines, and a bitline contact mask is formed over portions of the oxide layer. The bitline contact mask is etched, and a silicon layer is deposited on the substrate. A bitline layer is deposited on the silicon layer. A masking and etching operation is performed on the bitline layer. A M0 metal is deposited over the silicon layer and on sides of non etched portions of the bitline (M0) layer to form left and right bitlines.

Abstract: A method (and structure) of forming an interconnect on a semiconductor substrate, includes forming a relatively narrow first structure in a dielectric formed on a semiconductor substrate, forming a relatively wider second structure in the dielectric formed on the semiconductor substrate, forming a liner in the first and second structures such that the first structure is substantially filled and the second structure is substantially unfilled, and forming a metallization over the liner to completely fill the second structure.

Abstract: A bitline contact and method of forming bitline contact for a vertical DRAM array using a bitline contact mask. In the method, gate conductor lines are formed. An oxide layer is deposited over the gate conductor lines, and a bitline contact mask is formed over portions of the oxide layer. The bitline contact mask is etched, and a silicon layer is deposited on the substrate. A bitline layer is deposited on the silicon layer. A masking and etching operation is performed on the bitline layer. A M0 metal is deposited over the silicon layer and on sides of non etched portions of the bitline (M0) layer to form left and right bitlines.

Abstract: A bitline contact and method of forming bitline contact for a vertical DRAM array using a bitline contact mask. In the method, gate conductor lines are formed. An oxide layer is deposited over the gate conductor lines, and a bitline contact mask is formed over portions of the oxide layer. The bitline contact mask is etched, and a silicon layer is deposited on the substrate. A bitline layer is deposited on the silicon layer. A masking and etching operation is performed on the bitline layer. A M0 metal is deposited over the silicon layer and on sides of non etched portions of the bitline (M0) layer to form left and right bitlines.

Abstract: A method (and structure) of forming an interconnect on a semiconductor substrate, includes forming a relatively narrow first structure in a dielectric formed on a semiconductor substrate, forming a relatively wider second structure in the dielectric formed on the semiconductor substrate, forming a liner in the first and second structures such that the first structure is substantially filled and the second structure is substantially unfilled, and forming a metallization over the liner to completely fill the second structure.

Abstract: A bitline contact and method of forming bitline contact for a vertical DRAM array using a bitline contact mask. In the method, gate conductor lines are formed. An oxide layer is deposited over the gate conductor lines, and a bitline contact mask is formed over portions of the oxide layer. The bitline contact mask is etched, and a silicon layer is deposited on the substrate. A bitline layer is deposited on the silicon layer. A masking and etching operation is performed on the bitline layer. A M0 metal is deposited over the silicon layer and on sides of non etched portions of the bitline (M0) layer to form left and right bitlines.

Abstract: A method of forming relatively thin uniform insulating collar in the storage trench of a storage trench DRAM cell. A DRAM trench is first formed in a silicon substrate. Then, a nitride liner is deposited on the silicon trench walls. The nitride liner may be deposited directly on the silicon walls or on an underlying oxide layer. A layer of amorphous silicon is then deposited over the nitride liner. A silicon nitride layer is deposited on the oxidized surface of the amorphous silicon. A resist is formed in the lower portion of the trench, and the exposed silicon nitride layer on top of the amorphous silicon is removed, leaving the upper portion of the amorphous silicon layer exposed. The upper portion of the layer of amorphous silicon is then oxidized so as to form a relatively thin, uniform collar along the entire circumference of the trench.

Abstract: A number of methods to prevent divot formation, and the resulting enhanced electric field associated therewith, are disclosed. In a first embodiment of the present invention, spacers having a low etch rate in hydrofluoric acid solution, and that can be etched selectively to silicon dioxide are used to protect the silicon nitride liner from forming the divot. In a second embodiment of the present invention, a silicon dioxide spacer is used prior to the etching of the trenches, to allow the formation of the divots above the level of the silicon wafer, where they are not problematic. In a third embodiment of the present invention, a multi layer polish stop is used to prevent the formation of the divot.

Abstract: A method of forming interlevel studs of at least two different materials in an insulating layer on a semiconductor wafer. After forming an insulating layer of BPSG on a Front End of the Line (FEOL) structure, the BPSG layer is chem-mech polished. Vias are formed through the BPSG layer in array areas. A thin doped poly layer is deposited on the surface of the BPSG layer. The structure is annealed and vias are formed in support areas. Dopants are implanted into support areas through the vias. After annealing to diffuse implanted dopant, a metal layer is formed on the poly layer. Then, the structure is chem-mech polished back to the poly layer. A final chem-mech polish step removes the poly layer, leaving metal studs in the support areas and poly-lined metal cored studs in the array areas.