Abstract: Holes in semiconductor processing reactor parts are sized to facilitate deposition of protective coatings, such chemical vapor deposition at atmospheric pressure. In some embodiments, the holes each have a flow constriction that narrows the holes in one part and that also divides the holes into one or more other portions. In some embodiments, the aspect ratios of the one or more other portions are about 15:1 or less, or about 7:1 or less, and have a cylindrical or conical cross-sectional shape. The holes are coated with a protective coating, such as a silicon carbide coating, by chemical vapor deposition, including chemical vapor deposition at atmospheric pressure.

Abstract: Inserts are used to line openings in parts that form a semiconductor processing reactor. In some embodiments, the reactor parts delimit a reaction chamber. The reactor parts may be formed of graphite. A layer of silicon carbide is deposited on surfaces of the openings in the reactor parts and the inserts are placed in the openings. The inserts are provided with a hole, which can accept another reactor part such as a thermocouple. The insert protects the walls of the opening from abrasion caused by insertion of the other reactor part into the opening.

Abstract: A reactor for heat treatment of a substrate having a process chamber within a substrate enclosing structure, and a support structure configured to position a substrate at a predetermined spacing between the upper part and the bottom part within the process chamber during processing. Streams of gas may lift the substrate from the support structure so that the substrate floats. A plurality of heating elements is associated with at least one of the upper part and the bottom part and are arranged to define heating zones. A controller controls the heating elements individually so that each heating zone is configured to have a predetermined temperature determined by the controller. The heating zones provide for a non-uniform heating laterally across the substrate.

Abstract: A method of self-aligned silicidation involves interruption of the silicidation process prior to complete reaction of the blanket material (e.g., metal) in regions directly overlying patterned and exposed other material (e.g., silicon). Diffusion of excess blanket material from over other regions (e.g., overlying insulators) is thus prevented. Control and uniformity are insured by use of conductive rapid thermal annealing in hot wall reactors, with massive heated plates closely spaced from the substrate surfaces. Interruption is particularly facilitated by forced cooling, preferably also by conductive thermal exchange with closely spaced, massive plates.

Abstract: A method of self-aligned silicidation involves interruption of the silicidation process prior to complete reaction of the blanket material (e.g., metal) in regions directly overlying patterned and exposed other material (e.g., silicon). Diffusion of excess blanket material from over other regions (e.g., overlying insulators) is thus prevented. Control and uniformity are insured by use of conductive rapid thermal annealing in hot wall reactors, with massive heated plates closely spaced from the substrate surfaces. Interruption is particularly facilitated by forced cooling, preferably also by conductive thermal exchange with closely spaced, massive plates.

Abstract: An electromagnetic radiation attenuating material or coating consistent with certain embodiments of the present invention uses a binding matrix with an operative quantity of electromagnetic radiation attenuating nano-particles suspended in the binding matrix, wherein, the electromagnetic radiation attenuating nano-particles comprise onion-like-carbon (OLC) particles. In other embodiments, freestanding structures, aerosols and powders or suspensions contained within an enclosure provide EM or Radar absorption, particularly in the range of about 500 MHz to about 30 THz. This abstract is not to be considered limiting, since other embodiments may deviate from the features described in this abstract.

Abstract: A substrate undergoes a semiconductor fabrication process at different temperatures in a reactor without changing the temperature of the reactor. The substrate is held suspended by flowing gas between two heated surfaces of the reactor. Moving the two heated surfaces in close proximity with the substrate for a particular time duration heats the substrate to a desired temperature. The desired temperature is then maintained by distancing the heated surfaces from the substrate and holding the heated surface at the increased distance to minimize further substrate heating.

Abstract: A substrate undergoes a semiconductor fabrication process at different temperatures in a reactor without changing the temperature of the reactor. The substrate is held suspended by flowing gas between two heated surfaces of the reactor. Moving the two heated surfaces in close proximity with the substrate for a particular time duration heats the substrate to a desired temperature. The desired temperature is then maintained by distancing the heated surfaces from the substrate and holding the heated surface at the increased distance to minimize further substrate heating.

Abstract: Method and device for rotating a wafer which is arranged floating in a reactor. The wafer is treated in a reactor of this nature, and it is important for this treatment to be carried out as uniformly as possible. For this purpose, it is proposed to rotate the wafer by allowing the gas flow to emerge perpendicular to the surface of the wafer and then to impart to this gas a component which is tangential with respect to the wafer, thus generating rotation. This tangential component may be generated by the provision of grooves, which may be of spiral or circular design.

Abstract: A method of self-aligned silicidation involves interruption of the silicidation process prior to complete reaction of the blanket material (e.g., metal) in regions directly overlying patterned and exposed other material (e.g., silicon). Diffusion of excess blanket material from over other regions (e.g., overlying insulators) is thus prevented. Control and uniformity are insured by use of conductive rapid thermal annealing in hot wall reactors, with massive heated plates closely spaced from the substrate surfaces. Interruption is particularly facilitated by forced cooling, preferably also by conductive thermal exchange with closely spaced, massive plates.

Abstract: A reactor for heat treatment of a substrate having a process chamber within a substrate enclosing structure, and a support structure configured to position a substrate at a predetermined spacing between the upper part and the bottom part within the process chamber during processing. Streams of gas may lift the substrate from the support structure so that the substrate floats. A plurality of heating elements is associated with at least one of the upper part and the bottom part and are arranged to define heating zones. A controller controls the heating elements individually so that each heating zone is configured to have a predetermined temperature determined by the controller. The heating zones provide for a non-uniform heating laterally across the substrate.

Abstract: A reactor for heat treatment of a substrate includes a process chamber within a substrate enclosing structure, and a support structure configured to position a substrate at a predetermined spacing between the upper part and the bottom part within the process chamber during processing. Streams of gas may lift the substrate from the support structure so that the substrate floats. A plurality of heating elements is associated with at least one of the upper part and the bottom part and are arranged to define heating zones. A controller controls the heating elements individually so that each heating zone is configured to have a predetermined temperature determined by the controller. The heating zones provide for a non-uniform heating laterally across the upper part and/or lower part adjacent the substrate.

Abstract: The invention relates to polyaldimines of formula [1] and their use within moisture curable one part polyurea compositions. wherein j is an integer of 3 to 30 and R2 is unsubstituted homocyclic or heterocyclic aryl radical or alkyl, alkoxy, alkylthio or halogen substituted homocyclic or heterocyclic aryl radical.

Abstract: An apparatus for internal flash removal is intended for use in pipe manufacture and comprises a hollow supporting bar inserted into a pipe being welded and carrying an oxygen duct with a main nozzle and a cooled ferrite-holder. An additional nozzle having an oxygen conduit common with the main nozzle is arranged downstream of the main nozzle in the direction of welding. The main and the additional nozzles have oval outlets of different clear openings and are arranged at different acute angles to the weld in the same plane passing through the pipe axis and the weld. The apparatus ensures a quality weld surface finish inside the pipe.

Abstract: The roller comprises a core and a shell secured to said core. The shell is made up of two coaxial pipes, i.e. an inner pipe secured to the core in the middle and an outer pipe fastened to the inner pipe in the middle and at the ends. This allows the shell to be made of small-diameter thin-walled pipes thus reducing the roller deflection and decreasing considerably the weight both of the roller proper and of the equipment utilizing said roller.