Abstract: Disclosed is a method of increasing the capacitance of a trench capacitor by increasing sidewall area, comprising: forming a trench in a silicon substrate, the trench having a sidewall; forming islands on the sidewall of the trench; and etching pits into the sidewall using the islands as a mask. The capacitor is completed by forming a node insulator on said on the pits and the sidewall; and filling said trench with a trench conductor.

Abstract: A vertical transistor particularly suitable for high density integration includes potentially independent gate structures on opposite sides of a semiconductor pillar formed by etching or epitaxial growth in a trench. The gate structure is surrounded by insulating material which is selectively etchable to isolation material surrounding the transistor. A contact is made to the lower end of the pillar (e.g. the transistor drain) by selectively etching the isolation material selective to the insulating material. The upper end of the pillar is covered by a cap and sidewalls of selectively etchable materials so that gate and source connection openings can also be made by selective etching with good registration tolerance. A dimension of the pillar in a direction parallel to the chip surface is defined by a distance between isolation regions and selective etching and height of the pillar is defined by thickness of a sacrificial layer.

Abstract: A method for forming a gate conductor cap in a transistor comprises the steps of: a) forming a polysilicon gate conductor; b) doping the polysilicon gate; c) doping diffusion areas; and d) capping the gate conductor by a nitridation method chosen from among selective nitride deposition and selective surface nitridation. The resulting transistor may comprise a capped gate conductor and borderless diffusion contacts, wherein the capping occurred by a nitridation method chosen from among selective nitride deposition and selective surface nitridation and wherein a portion of the gate conductor is masked during the nitridation method to leave open a contact area for a local interconnect or a gate contact.

Abstract: Methods are provided that use disposable and permanent films to dope underlying layers through diffusion. Additionally, methods are provided that use disposable films during implantation doping and that provide a surface from which to dope underlying materials. Some of these disposable films can be created from a traditionally non-disposable film and made disposable. In this manner, solvents may be used that do not etch underlying layers of silicon-based materials. Preferably, deep implantation is performed to form source/drain regions, then an anneal step is performed to activate the dopants. A conformal layer is deposited and implanted with dopants. One or more anneal steps are performed to create very shallow extensions in the source/drain regions.

Abstract: Described is a method of increasing the capacitance of semiconductor capacitors by providing a first solid-state electrode pattern on a semiconductor medium, etching topographic features on said first electrode pattern in a manner effective in increasing the surface area of said first electrode pattern, depositing a dielectric layer upon said electrode pattern that substantially conforms to said topographic features, and depositing a second solid-state electrode pattern upon said dielectric layer and sufficiently insulated from said first solid-state electrode pattern so as to create a capacitance with said first solid-state electrode pattern.

Abstract: An assist feature is formed on a lithographic reticle or mask using a hybrid resist and an exposure dose such that only an annular area is effectively exposed having a width that is potentially less than the minimum feature size that can be resolved by the mask exposure tool to simultaneously or sequentially form both a feature of interest and an assist feature for enhancing imaging of the feature of interest when the feature is printed to a wafer. Since the assist feature can be imaged simultaneously with the feature of interest or multiple assist features imaged concurrently, possibly between closely spaced features, data volume and mask writing time are greatly reduced. The invention is particularly applicable to the scaling of contact holes for connections to active devices in extremely high density integrated circuits.

Abstract: Methods are provided that use disposable and permanent films to dope underlying layers through diffusion. Additionally, methods are provided that use disposable films during implantation doping and that provide a surface from which to dope underlying materials. Some of these disposable films can be created from a traditionally non-disposable film and made disposable. In this manner, solvents may be used that do not etch underlying layers of silicon-based materials. Preferably, deep implantation is performed to form source/drain regions, then an anneal step is performed to activate the dopants. A conformal layer is deposited and implanted with dopants. One or more anneal steps are performed to create very shallow extensions in the source/drain regions.

Abstract: The present invention features double- or dual-gate logic devices that contain gate conductors that are consistently self-aligned and that have channels that are of constant width. The inventive process also provides a method of selectively etching germanium-containing gate conductor materials without significantly etching the adjacent silicon channel material. In this manner, the gate conductor can be encased in a dielectric shell without changing the length of the silicon channel. A single-crystal silicon wafer is utilized as the channel material. Pillars or stacks of self aligned dual gate MOSFETs are generated by etching, via the juxtaposition of overlapping germanium-containing gate conductor regions. Vertically etching through regions of both gate conducting material and dielectric insulating material provides an essentially perfect, self-aligned dual gate stack. A process is described wherein the gate conductor material can be selectively etched without etching the channel material.

Abstract: The present invention relates to a method of forming a very shallow source-drain (S/D) extension while simultaneously highly doping a very narrow polysilicon gate through to the gate dielectric interface. The invention also relates to the resulting semiconductor.

Abstract: Methods for forming a patterned SOI region in a Si-containing substrate is provided which has geometries of about 0.25 &mgr;m or less. Specifically, one method includes the steps of: forming a patterned dielectric mask on a surface of a Si-containing substrate, wherein the patterned dielectric mask includes vertical edges that define boundaries for at least one opening which exposes a portion of the Si-containing substrate; implanting oxygen ions through the at least one opening removing the mask and forming a Si layer on at least the exposed surfaces of the Si-containing substrate; and annealing at a temperature of about 1250° C. or above and in an oxidizing ambient so as to form at least one discrete buried oxide region in the Si-containing substrate. In one embodiment, the mask is not removed until after the annealing step; and in another embodiment, the Si-containing layer is formed after annealing and mask removal.

Abstract: A multi-chip module is constructed by aligning prewired chips on a support wafer and depositing a nonconductive thermally conductive and electrically nonconductive material having a coefficient of thermal expansion that approximate that of the chips (e.g. silicon, silicon carbide, silicon germanium, germanium or SiCGe) to surround chips. After removal of the support wafer, processing of multi-chip module is finished with wiring on a shared surface of multi-chip module and chip surface.

Abstract: A semi-conductor device includes a silicon substrate. A gate oxide dielectric layer is on the silicon substrate. A gate conductor includes a relatively thin layer of germanium on the dielectric layer. A relatively thick layer of gate conductor material is provided on the layer of germanium. Incorporating germanium at the gate conductor interface with the gate oxide stabilizes the gate oxide by providing a means of drawing charge trapping sites away from the oxide.

Abstract: Features of two or more distinct sizes designed to optimize performance of an integrated circuit device are formed by transferring a pattern from a resist patterned with features of a single minimum feature size for which a resist exposure tool is optimized to a layer of preferably soluble material such as germanium oxide. Portions of this pattern are then enlarged using a block-out mask and the resulting pattern transferred to a further underlying layer preferably using an anisotropic reactive ion etch. The soluble material can then be removed leaving a robust mask with differing feature sizes for further processing. Preferably, Damascene conductive lines and vias are formed by providing an insulator as the further underlying material and filling the openings with metal or other conductive material.

Abstract: A densely packed array of vertical semiconductor devices having pillars and methods of making thereof are disclosed. The array has rows of wordlines and columns of bitlines. The array has vertical pillars, each having two wordlines, one active and the other passing for each, cell. Two wordlines are formed per pillar on opposite pillar sidewalls which are along the row direction. The threshold voltage of the pillar device is raised on the side of the pillar touching the passing wordline, thereby permanently shutting off the pillar device during the cell operation and isolating the pillar from the voltage variations on the passing wordline. The isolated wordlines allow individual cells to be addressed and written via direct tunneling, in both volatile and non-volatile memory cell configurations. For Gbit DRAM application, stack or trench capacitors may be formed on the pillars, or in trenches surrounding the pillars, respectively.

Abstract: A semi-conductor device includes a silicon substrate. A gate oxide dielectric layer is on the silicon substrate. A gate conductor includes a relatively thin layer of germanium on the dielectric layer. A relatively thick layer of gate conductor material is provided on the layer of germanium. Incorporating germanium at the gate conductor interface with the gate oxide stabilizes the gate oxide by providing a means of drawing charge trapping sites away from the oxide.

Abstract: A photoresist having both positive and negative tone components resulting in a lower “k” factor than the single tone photoresist is disclosed. The hybrid resist may either have the negative tone resist or the positive tone resist as the major portion, while the other tone is a relatively minor portion. For examples, a positive tone resist may include a minor portion of a negative tone cross-linker or a negative tone resist may include positively acting functional groups. The hybrid resist of the present invention allows for wider exposure dosage windows, therefore increasing the yield or performance and line density.

Abstract: A technique for fabricating precision aligned macros (PAMs) with reduced risk of electrostatic discharge damage and thermal damage. An electrical and thermal contact is provided through the back of the individual chips to a supporting silicon substrate. A conductive seed layer for electroplating is formed on a support substrate. A dielectric (preferably, a thermid) layer is formed on the seed layer. Vias are formed in the thermid layer and metal contacts are formed in the vias. The front faces of two or more chips are bonded onto the top surface of an alignment substrate, and the chips are aligned to the alignment substrate. The back faces of the chips are bonded to the metal contacts and thermid layer with heat and pressure. The alignment substrate is removed. The front faces of the chips are planarized. Finally, interconnect wiring is formed over the chips and thermid layer.

Abstract: A technique for fabricating precision aligned macros (PAMs) with reduced risk of electrostatic discharge damage and thermal damage. An electrical and thermal contact is provided through the back of the individual chips to a supporting silicon substrate. A conductive seed layer for electroplating is formed on a support substrate. A dielectric (preferably, a thermid) layer is formed on the seed layer. Vias are formed in the thermid layer and metal contacts are formed in the vias. The front faces of two or more chips are bonded onto the top surface of an alignment substrate, and the chips are aligned to the alignment substrate. The back faces of the chips are bonded to the metal contacts and thermid layer with heat and pressure. The alignment substrate is removed. The front faces of the chips are planarized. Finally, interconnect wiring is formed over the chips and thermid layer.

Abstract: The preferred embodiment of the present invention provides a transistor structure and method for fabricating the same that overcomes the disadvantages of the prior art. In particular, the preferred structure and method results in lower leakage and junction capacitance by using raised source and drains which are partially isolated from the substrate by a dielectric layer. The raised source and drains are preferably fabricated from the same material layer used to form the transistor gate. The preferred method for fabricating the transistor uses hybrid resist to accurately pattern the gate material layer into regions for the gate, the source and the drain. The source and drain regions are then connected to the substrate by growing silicon. The preferred method thus results in an improved transistor structure while not requiring excessive fabrication steps.

Abstract: A high capacitance storage node structure is created in a substrate by patterning a hybrid resist (12) to produce both negative tone (16) and positive tone (18) areas in the exposed region (14). After removal of the positive tone areas (18), the substrate (12) is etched using the unexposed hybrid resist (12) and negative tone area (16) as a mask. This produces a trench (22) in the substrate (12) with a centrally located, upwardly projecting protrusion (24). The capacitor (26) is then created by coating the sidewalls of the trench (22) and protrusion (24) with dielectric (28) and filling the trench with conductive material (30) such as polysilicon.