Abstract: A method for preparing a grounding substrate for a semiconductor device, the method including: 1) polishing the surface of a matrix of a grounding substrate to remove a carbon layer therefrom, and washing the surface of the matrix with anhydrous ethanol; 2) providing a cold spray system including a spraying device, a spray chamber, and a special fixture disposed in the spray chamber; and disposing the matrix on the special fixture; 3) using the cold spray system to spray a compressed gas carrying aluminum powder on the surface of the matrix at the supersonic speed to form an aluminum coating, thus obtaining the grounding substrate; 4) disposing the grounding substrate in a heat treatment furnace, raising the temperature therein to between 100 and 500° C., and maintaining the temperature for between 1 and 5 hrs; and 5) wet polishing the grounding substrate.

Abstract: A bonded multi-layer RF window may include an external layer of dielectric material having desired thermal properties, an internal layer of dielectric material exposed to plasma inside a reaction chamber, and an intermediate layer of bonding material between the external layer and the internal layer. Heat produced by the chemical reaction inside the chamber and by the transmission of RF energy through the window may be conducted from the internal layer to the external layer, which may be cooled during a semiconductor wafer manufacturing process. A bonded multi-layer RF window may include cooling conduits for circulating coolant to facilitate cooling of the internal layer; additionally or alternatively, gas distribution conduits and gas injection apertures may be included for delivering one or more process gases into a reaction chamber. A system including a plasma reaction chamber may employ the inventive bonded multi-layer RF window.

Abstract: A substrate processing chamber component capable of being exposed to an energized gas in a process chamber has a component structure, and a surface on the structure with first and second spiral grooves, which can oppose one another. Process residues adhere to the surface during processing of a substrate in an energized gas to reduce contamination of the substrate.

Abstract: The present disclosure pertains to our discovery of a particularly efficient method for etching a multi-part cavity in a substrate. The method provides for first etching a shaped opening, depositing a protective layer over at least a portion of the inner surface of the shaped opening, and then etching a shaped cavity directly beneath and in continuous communication with the shaped opening. The protective layer protects the etch profile of the shaped opening during etching of the shaped cavity, so that the shaped opening and the shaped cavity can be etched to have different shapes, if desired. In particular embodiments of the method of the invention, lateral etch barrier layers and/or implanted etch stops are also used to direct the etching process. The method of the invention can be applied to any application where it is necessary or desirable to provide a shaped opening and an underlying shaped cavity having varying shapes.

Abstract: The present disclosure pertains to our discovery of a particularly efficient method for etching a multi-part cavity in a substrate. The method provides for first etching a shaped opening, depositing a protective layer over at least a portion of the inner surface of the shaped opening, and then etching a shaped cavity directly beneath and in continuous communication with the shaped opening. The protective layer protects the etch profile of the shaped opening during etching of the shaped cavity, so that the shaped opening and the shaped cavity can be etched to have different shapes, if desired. In particular embodiments of the method of the invention, lateral etch barrier layers and/or implanted etch stops are also used to direct the etching process. The method of the invention can be applied to any application where it is necessary or desirable to provide a shaped opening and an underlying shaped cavity having varying shapes.

Abstract: The invention provides a system and a method for dynamic RF inductive and capacitive coupling control to improve plasma substrate processing, as well as for achieving contamination and defect reduction. A plasma reactor includes a substrate support disposed in a chamber. An RF coil is disposed adjacent the chamber for inductively coupling RF energy into the chamber. An electrode is disposed adjacent the chamber and has a voltage for capacitively coupling energy into the chamber. The electrode is spaced from the substrate support and the RF coil. An electrode adjusting member is coupled with the electrode for dynamically adjusting the voltage in the electrode to vary the capacitive coupling for improved plasma ignition and plasma stability. A Faraday shield may be placed between the RF coil and the plasma process region in the chamber to suppress capacitive coupling of the RF coil.

Abstract: A method and an apparatus that provides efficient heating of a dielectric structure without compromising the dielectric properties of the structure. A heating assembly is adapted to fit a circularly shaped dielectric lid of a plasma processing vacuum chamber. The heating assembly is placed between the RF coil and the atmospheric side of the dielectric lid. Although the active heating structure portion (a resistive heating wire or a thermal working fluid or both, per alternate embodiments) of the heating assembly is transparent to the electromagnetic fields produced by the coil, the conductive portion of the heating assembly takes on the role of shaping the electric field. The result of this averaging is the minimization of detrimental effects of electromagnetic potentials that are too high (e.g., sputtering of the dielectric by the plasma) and of electromagnetic potentials that are too low (e.g., heavy by-product depositions on the dielectric lid).

Abstract: The present invention pertains to an etch chemistry and method useful for the etching of silicon surfaces. The method is particularly useful in the deep trench etching of silicon where profile control is important. In the case of deep trench etching, at least a portion of the substrate toward the bottom of the trench is etched using a combination of reactive gases including a fluorine-containing compound which does not contain silicon (FC); a silicon-containing compound (SC) which does not contain fluorine; and oxygen (O2).

Abstract: High aspect ratio openings can be etched in silicon having straight walls and rounded bottoms using as an etch gas a mixture including SF6, HBr and O2in a plasma chamber wherein the chamber is connected to an RF power source and the substrate is mounted on a support connected to a bias power source.

Abstract: A multistep etch process for forming high aspect ratio trenches in silicon having a silicon oxide and/or silicon nitride hardmask. In a first step, an etch composition of HBr and oxygen is used, depositing a passivation layer on the sidewalls and producing slightly tapered openings. In the second step, an etch composition of a fluorine-containing gas such as SF.sub.6, HBr and oxygen is used, producing more vertical openings at a high etch rate. The taper of the openings during the second step can be controlled by adjusting the relative amount of HBr or SF.sub.6 employed. This process is a clean process that does not require cleaning of the etch chamber between etch steps.