Abstract: A plasma etching system having a wafer chuck with a magnet that applies a magnetic field over a wafer to shield the wafer from charged particles. The magnetic field is parallel with the wafer, and is strongest near the wafer surface. The magnetic field may be straight, or circular. In operation, electrons are deflected from the wafer by the Lorentz force, the wafer acquires a positive charge, and ions are deflected by electrostatic repulsion. Neutral species are allowed through the magnetic field, and they collide with the wafer. Neutral species generally provide more isotropic and material-selective etching than charged particles, so the present magnetic field tends to increase etch isotropy and material selectivity. Also, the magnetic field can protect the wafer from seasoning processes designed to clean unwanted films from the chamber surface as seasoning processes typically rely on etching by charged particles.

Abstract: A method of forming a wiring structure for an integrated circuit includes the steps of forming a plurality of features in a layer of dielectric material, and forming spacers on sidewalls of the features. Conductors are then formed in the features, being separated from the sidewalls by the spacers. The spacers are then removed, forming air gaps at the sidewalls so that the conductors are separated from the sidewalls by the air gaps. Dielectric layers above and below the conductors may be low-k dielectrics having a dielectric constant less than that of the dielectric between the conductors. A cross-section of each of the conductors has a bottom in contact with the a low-k dielectric layer, a top in contact with another low-k dielectric, and sides in contact only with the air gaps. The air gaps serve to reduce the intralevel capacitance.

Abstract: A system and method for aligning a wafer in an exposure apparatus includes a holder adapted to hold a wafer (the wafer includes alignment marks), a coarse alignment system, and a fine alignment system having a higher precision than the coarse alignment system. The fine alignment system includes multiple optical detectors. Each of the optical detectors is positioned to detect a corresponding alignment mark on the wafer. An alignment processor is connected to and controls the optical detectors and the holder. The optical detectors are controlled by the alignment processor to simultaneously detect the alignment marks in parallel operations. Further, the alignment processor simultaneously processes signals from the optical detectors in parallel operations.

Abstract: A system and method for aligning a wafer in an exposure apparatus includes a holder adapted to hold a wafer (the wafer includes alignment marks), a coarse alignment system, and a fine alignment system having a higher precision than the coarse alignment system. The fine alignment system includes multiple optical detectors. Each of the optical detectors is positioned to detect a corresponding alignment mark on the wafer. An alignment processor is connected to and controls the optical detectors and the holder. The optical detectors are controlled by the alignment processor to simultaneously detect the alignment marks in parallel operations. Further, the alignment processor simultaneously processes signals from the optical detectors in parallel operations.

Abstract: A pre-loaded plasma-based processing system comprises a pre-reaction plasma processing chamber, a power source disposed in operable communication with the pre-reaction plasma processing chamber, and a wafer plasma processing chamber disposed in fluid communication with the pre-reaction plasma processing chamber. The pre-reaction plasma processing chamber is configured to effect a plasma-based chemical reaction of reactant materials to produce a reactive radical. The wafer plasma processing chamber is configured to react the reactive radical with a species at a surface of a wafer disposed in the wafer plasma processing chamber. Other embodiments include a method of processing a wafer in a plasma environment and preloading of the reactive gas stream to prevent erosion of wafer masking or etch stop layers.

Abstract: Methods and an apparatus for processing a substrate. A first method comprising: reacting a layer formed on the substrate with a plasma to form a reaction product layer; and simultaneously exposing the reaction product layer to resonant radiation to volatilize the reaction product layer. A second method comprising: performing a plasma enhanced chemical vapor deposition to deposit a precursor layer on a substrate; and simultaneously heating the precursor layer by exposure of the precursor layer to resonant radiation to convert the precursor layer to a deposited layer.

Abstract: A plasma etching system having a wafer chuck with a magnet that applies a magnetic field over a wafer to shield the wafer from charged particles. The magnetic field is parallel with the wafer, and is strongest near the wafer surface. The magnetic field may be straight, or circular. In operation, electrons are deflected from the wafer by the Lorentz force, the wafer acquires a positive charge, and ions are deflected by electrostatic repulsion. Neutral species are allowed through the magnetic field, and they collide with the wafer. Neutral species generally provide more isotropic and material-selective etching than charged particles, so the present magnetic field tends to increase etch isotropy and material selectivity. Also, the magnetic field can protect the wafer from seasoning processes designed to clean unwanted films from the chamber surface as seasoning processes typically rely on etching by charged particles.

Abstract: A process for fabrication of both compact memory and high performance logic on the same semiconductor chip. The process comprises forming a memory device in the memory region, forming a spacer nitride layer and a protective layer over both the memory region and the logic region, removing the protective layer over the logic region to expose the substrate, and forming the logic device in the logic region. Cobalt or titanium metal is applied over all horizontal surfaces in the logic region and annealed, forming a salicide where the metal rests over silicon or polysilicon regions, and any unreacted metal is removed. An uppermost nitride layer is then applied over both the memory and logic regions and is then covered with a filler in the logic region. Chip structures resulting from various embodiments of the process are also disclosed.

Abstract: A method for forming a JOI structure which allows for reduction in both source/drain junction leakage and capacitance is provided. In the inventive method, an insulator layer is formed under the source/drain regions, but not under the channel region. The insulator layer is formed in the present invention after forming the gate stack region and recessing the semiconductor surface surrounding the gate stack region, followed by deposition of a conductive material such as polysilicon and, optionally, heavy source/drain diffusion formation.

Abstract: A method for forming a JOI structure which allows for reduction in both source/drain junction leakage and capacitance is provided. In the inventive method, an insulator layer is formed under the source/drain regions, but not under the channel region. The insulator layer is formed in the present invention after forming the gate stack region and recessing the semiconductor surface surrounding the gate stack region, followed by deposition of a conductive material such as polysilicon and, optionally, heavy source/drain diffusion formation.

Abstract: The present invention provides a programmable element that can be programmed using relatively low-voltages (less than about 5 V) for use in one time programmable non-volatile memory storage or other high-density application. The low-voltage programmable element is a field effect transistor (FET) device that includes source and drain elements, which are separated by a channel region, and a gate region, present atop a portion of the channel region. The source and drain elements are not located beneath the gate region and the FET includes no extension implant regions present therein.

Abstract: A method and structure for a EEPROM memory device integrated with high performance logic or NVRAM. The EEPROM device includes a floating gate and program gate self-aligned with one another. During programming, electron tunneling occurs between the floating gate and the program gate.

Abstract: A method for forming a thermally stable ohmic contact structure that includes a region of monocrystalline semiconductor and a region of polycrystalline semiconductor. At least one region of dielectric material is formed between at least a portion of the region of monocrystalline semiconductor and the region of polycrystalline semiconductor, thereby controlling grain growth of the polycrystalline semiconductor.

Abstract: A patterned buried insulator is formed beneath the source and drain by forming a mask over the body area and implanting a dose of n or p type ions in the areas where the source and drains will be formed, then etching the STI and etching out the implanted area. A light oxidation is followed by a conformal oxide deposition in the STI and also in the etched area, thereby forming the buried oxide only where desired.

Abstract: A method for forming a thermally stable ohmic contact structure that includes a region of monocrystalline semiconductor and a region of polycrystalline semiconductor. At least one region of dielectric material is formed between at least a portion of the region of monocrystalline semiconductor and the region of polycrystalline semiconductor, thereby controlling grain growth of the polycrystalline semiconductor.

Abstract: A patterned buried insulator is formed beneath the source and drain by forming a mask over the body area and implanting a dose of n or p type ions in the areas where the source and drains will be formed, then etching the STI and etching out the implanted area. A light oxidation is followed by a conformal oxide deposition in the STI and also in the etched area, thereby forming the buried oxide only where desired.

Abstract: A process for fabrication of both compact memory and high performance logic on the same semiconductor chip. The process comprises forming a memory device in the memory region, forming a spacer nitride layer and a protective layer over both the memory region and the logic region, removing the protective layer over the logic region to expose the substrate, and forming the logic device in the logic region. Cobalt or titanium metal is applied over all horizontal surfaces in the logic region and annealed, forming a salicide where the metal rests over silicon or polysilicon regions, and any unreacted metal is removed. An uppermost nitride layer is then applied over both the memory and logic regions and is then covered with a filler in the logic region. Chip structures resulting from various embodiments of the process are also disclosed.

Abstract: Shallow trench isolation is combined with optional deep trenches that are self-aligned with the shallow trenches, at the corners of the shallow trenches, and have a deep trench width that is controlled by the thickness of a temporary sidewall deposited in the interior of the shallow trench and is limited by the sidewall deposition thickness of the deep trench fill.

Abstract: A pair of transistors sharing a common electrodes e.g. a bitline in a DRAM array, has a self-aligned contact to the bitline in which the transistor gate stack has only a poly layer with a nitride cover; the aperture for the bitline contact is time-etched to penetrate only between the gates and not reach the silicon substrate; exposed nitride shoulders of the gate are etched to expose the poly; the remainder of the interlayer dielectric is removed by a selective etch; the exposed poly is re-oxidized to protect the gates; and the aperture bottom is cleaned; so that the thick gate stack of a DRAM is dispensed with in order to improve uniformity of line width across the chip beyond what the DRAM technique can deliver.

Abstract: A process for fabrication of both compact memory and high performance logic on the same semiconductor chip. The process comprises forming a memory device in the memory region, forming a spacer nitride layer and a protective layer over both the memory region and the logic region, removing the protective layer over the logic region to expose the substrate, and forming the logic device in the logic region. Cobalt or titanium metal is applied over all horizontal surfaces in the logic region and annealed, forming a salicide where the metal rests over silicon or polysilicon regions, and any unreacted metal is removed. An uppermost nitride layer is then applied over both the memory and logic regions and is then covered with a filler in the logic region. Chip structures resulting from various embodiments of the process are also disclosed.