Abstract: A method of forming a thin silicon layer upon which semiconductor devices may be constructed. An epitaxial layer is grown on a silicon substrate, and oxygen or nitrogen ions are implanted into the epitaxial layer in order to form a buried etch-stop layer therein. An oxide layer is grown on the epitaxial layer, and is used to form a bond to a mechanical support wafer. The silicon substrate is removed using grinding and/or HNA, the upper portions of the epitaxy are removed using EDP, EPP or KOH, and the etch-stop is removed using a non-selective etch. The remaining portions of the epitaxy forms the thin silicon layer. Due to the uniformity of the implanted ions, the thin silicon layer has a very uniform thickness.

Abstract: A process for making a CMOS dual-well semiconductor structure with field isolation doping, wherein only a single lithographic masking step is required for providing self-alignment both of the wells to each other and also of the field isolation doping regions to the wells. The lithographic masking step forms a well mask and defines an oxidation barrier which acts as: an implant mask (absorber) during the ion-implantation of a field dopant of one type; an oxidation barrier over one well during the oxidation of the opposite-type well to form over the one well a sacrificial oxide layer which forms the alignment marks for subsequent formation of the field-doping regions; and a dopant-transmitter during the ion-implantation of an opposite-type field dopant which is simultaneously absorbed by the sacrificial oxide. As a result, there are formed field-doped oxide layers self-aligned to the wells so that, with a subsequent masking step, oxide field isolations are defined over the doped oxide layers.

Abstract: A method is provided for manufacturing semiconductor structures having dielectrically isolated silicon regions on one side of a silicon body. This is accomplished by forming in the silicon body a set of buried regions and a set of surface regions having characteristics which make them anodically etch slower than the remaining portion of the silicon body. These two sets of regions define portions in the silicon body which are anodically etched to form porous silicon regions which are oxidized to form an isolation structure that isolates the silicon surface regions from each other and the remaining portion of the silicon body. Typically in a P-type silicon body the buried and surface regions are N-type regions formed through ion implantation.

Abstract: An improved method of fabricating a silicide structure includes depositing a metal, e.g., molybdenum or tungsten, directly onto a thin insulating layer of silicon dioxide and/or silicon nitride formed on a semiconductor substrate, co-depositing the metal and silicon onto the metal layer and then depositing silicon onto the co-deposited metal-silicon layer. This structure is annealed at a temperature sufficient to form a metal silicide between the thin insulating layer and the layer of silicon. The silicon layer serves as a source of silicon for the metal layer which is consumed during the annealing step to form, along with the co-deposited metal-silicon layer, a relatively thick metal silicide layer directly on the thin silicon dioxide layer. A sufficiently thick silicon layer is initially provided on the co-deposited metal-silicon layer so that a portion of the initial silicon layer remains after the annealing step has been completed.

Abstract: A method of providing self-passivating interconnection electrodes for semiconductor devices which provides low resistivity composite polysiliconsilicide electrodes. In the method the formation of oxidation induced voids in polysilicon underlying the silicide is eliminated by deposition of polysilicon and stoichiometric proportions of silicon and a silicide-forming metal. These steps are followed by deposition of a silicon layer having a thickness determined to provide between 30 and 100 percent of the silicon required to form a silicon dioxide passivation layer. Subsequent thermal oxidation of the layered electrode structure provides a self-passivated structure useful for fabrication of silicon gate MOSFET devices as well as other integrated circuit structures.