Abstract: Silicon substrate isolation by epitaxial growth of silicon through windows in a mask made of silicon nitride (202) on silicon oxide (201) with the silicon oxide etched to undercut the silicon nitride; the mask is on a silicon substrate.

Abstract: A method of forming a plurality of shallow junction transistors, the method comprising the steps of providing a substrate (10) having a first region (13) and a second region (15). The first region (13) and the second region (15) include a first channel region (14) and a second channel region (16), respectively. A first gate (22) is formed proximate the first channel region (14) and is separated from the substrate (10) by a portion of a primary insulation layer (20). A second gate (24) is formed proximate the second channel region (16) and is separated from the substrate by a portion of the primary insulation layer (20). A dopant layer (34) is then formed outwardly of the substrate (10) proximate the first region (13) and the second region (15). The dopant layer (34) proximate the first region (13) is implanted with a first dopant (40). The dopant layer (34) proximate the second region (15) is implanted with a second dopant (48).

Abstract: An embodiment of the instant invention is a method of forming a dielectric layer, the method comprising the steps of: providing a semiconductor substrate (substrate 12), the substrate having a surface; forming an oxygen-containing layer (layer 14) on the semiconductor substrate; and subjecting the oxygen-containing layer to a nitrogen containing plasma (plasma 16) so that the nitrogen is either incorporated into the oxygen-containing layer (see regions 18, 19, and 20) or forms a nitride layer at the surface of the substrate (region 22). Using this embodiment of the instant invention, the dielectric layer can be substantially free of hydrogen. Preferably, the oxygen-containing layer is an SiO.sub.2 layer or it is comprised of oxygen and nitrogen (preferably an oxynitride layer). The plasma is, preferably, a high-density plasma. Preferably, a source of nitrogen is introduced to the plasma to form the nitrogen containing plasma. The source of nitrogen is preferably comprised of a material consisting of: N.sub.

Abstract: A method for forming an integrated circuit having multiple gate oxide thicknesses is disclosed herein. The circuit (10) is processed up to gate oxide formation. A pattern (36) is then formed exposing areas of the circuit where a thinner gate oxide (20) is desired. These areas are then implanted with a halogen species such as fluorine or chlorine, to retard oxidation. The pattern (36) is then removed and an oxidation step is performed. Oxidation is selectively retarded in areas (14) previously doped with the halogen species but not in the remaining areas (12). Thus, a single oxidation step may be used to form gate oxides (20,22) of different thicknesses.

Abstract: A gate electrode of a MOS transistor wherein gate oxide 12 is placed over substrate 10. Boron-doped polysilicon gate electrode 14 is placed over gate oxide 12. Optionally, drain extender implants may be added to substrate 10. Low-temperature-deposited nitride layer 18 is placed over gate electrode 14 and gate oxide 12. The structure then undergoes a sidewall spacer etch to form sidewall spacers 20.

Abstract: A method for forming an integrated circuit having multiple gate oxide thicknesses is disclosed herein. The circuit (10) is processed up to gate oxide formation. A first gate dielectric (20) is formed. Next, a disposable layer (22) is formed over the first gate dielectric (20). The disposable layer (22) comprises a material that may be removed selectively with respect to silicon and the gate dielectric, such as germanium. If desired, a second dielectric layer (24) may be formed over the disposable layer (22). A pattern (26) is then formed exposing areas (14) of the circuit where a thinner gate dielectric is desired. The second dielectric layer (24), if it is present, and the disposable layer (22) are removed from the exposed areas. The pattern (26) is then removed. Following pre-gate cleaning, the second gate dielectric (30) is formed. The remaining portions of the disposable layer (22) may be removed either prior to, during, or after the second gate dielectric formation (30).

Abstract: An embodiment of the instant invention is a method of fabricating a semiconductor device which includes a dielectric layer situated between a conductive structure and a semiconductor substrate, the method comprising the steps of: forming the dielectric layer (layer 14) on the semiconductor substrate (substrate 12); forming the conductive structure (structure 18) on the dielectric layer; doping the conductive structure with boron; and doping the conductive structure with a dopant which inhibits the diffusion of boron. The semiconductor device may be a PMOS transistor or a capacitor. Preferably, the conductive structure is a gate structure. The dielectric layer is, preferably, comprised of a material selected from the group consisting of: an oxide, an oxide/oxide stack, an oxide/nitride stack, and an oxynitride. Preferably, the dopant which inhibits the diffusion of boron comprises at least one group III or group IV element.

Abstract: A method, and resulting product, are disclosed for selectively forming polycrystalline silicon over exposed portions of a single crystal silicon substrate. The method includes inhibiting the formation of such polycrystalline silicon over adjacent silicon oxide surfaces; and the resulting product of such a process. The polycrystalline silicon is selectively deposited over the single crystal silicon substrate by first forming a thin layer of a lattice mismatched material over the single crystal silicon surface, and then depositing a layer of polycrystalline silicon over the lattice mismatched material. Preferably, the thin lattice mismatched layer comprises a silicon/germanium (SiGe) alloy.

Abstract: A process and resulting product are described for controlling the channeling and/or diffusion of a boron dopant in a P- region forming the lightly doped drain (LDD) region of a PMOS device in a single crystal semiconductor substrate, such as a silicon substrate. The channeling and/or diffusion of the boron dopant is controlled by implanting the region, prior to implantation with a boron dopant, with noble gas ions, such as argon ions, at a dosage at least equal to the subsequent dosage of the implanted boron dopant, but not exceeding an amount equivalent to the implantation of about 3.times.10.sup.14 argon ions/cm.sup.2 into a silicon substrate, whereby channeling and diffusion of the subsequently implanted boron dopant is inhibited without, however, amorphizing the semiconductor substrate.

Abstract: A method, and resulting product, are disclosed for selectively forming polycrystalline silicon over exposed portions of a single crystal silicon substrate. The method includes inhibiting the formation of such polycrystalline silicon over adjacent silicon oxide surfaces; and the resulting product of such a process. The polycrystalline silicon is selectively deposited over the single crystal silicon substrate by first forming a thin layer of a lattice mismatched material over the single crystal silicon surface, and then depositing a layer of polycrystalline silicon over the lattice mismatched material. Preferably, the thin lattice mismatched layer comprises a silicon/germanium (SiGe) alloy.

Abstract: A process and resulting product are described for controlling the channeling and/or diffusion of a boron dopant in a P- region forming the lightly doped drain (LDD) region of a PMOS device in a single crystal semiconductor substrate, such as a silicon substrate. The channeling and/or diffusion of the boron dopant is controlled by implanting the region, prior to implantation with a boron dopant,, with noble gas ions, such as argon ions, at a dosage at least equal to the subsequent dosage of the implanted boron dopant, but not exceeding an amount equivalent to the implantation of about 3.times.10.sup.13 argon ions/cm.sup.2 into a silicon substrate, whereby channeling and diffusion of the subsequently implanted boron dopant is inhibited without, however, amorphizing the semiconductor substrate.

Abstract: Doped silicon-germanium alloy is selectively deposited on a semiconductor substrate, and the semiconductor substrate is then heated to diffuse at least some of the dopant from the silicon-germanium alloy into the semiconductor substrate to form a doped region at the face of the semiconductor substrate. The doped silicon-germanium alloy acts as a diffusion source for the dopant, so that shallow doped, regions may be formed at the face of the semiconductor substrate without ion implantation. A high performance contact to the doped region is also provided by forming a metal layer on the doped silicon-germanium alloy layer and heating to react at least part of the silicon-germanium alloy layer with at least part of the metal layer to form a layer of germanosilicide alloy over the doped regions. The method of the present invention is particularly suitable for forming shallow source and drain regions for a field effect transistor, and self-aligned source and drain contacts therefor.

Abstract: Doped silicon-germanium alloy is selectively deposited on a semiconductor substrate, and the semiconductor substrate is then heated to diffuse at least some of the dopant from the silicon-germanium alloy into the semiconductor substrate to form a doped region at the face of the semiconductor substrate. The doped silicon-germanium alloy acts as a diffusion source for the dopant, so that shallow doped, regions may be formed at the face of the semiconductor substrate without ion implantation. A high performance contact to the doped region is also provided by forming a metal layer on the doped silicon-germanium alloy layer and heating to react at least part of the silicon-germanium alloy layer with at least part of the metal layer to form a layer of germanosilicide alloy over the doped regions. The method of the present invention is particularly suitable for forming shallow source and drain regions for a field effect transistor, and self-aligned source and drain contacts therefor.