A substrate processing apparatus includes a heat storage part on which a substrate is mounted, a tray including the heat storage part, a substrate transfer part including a rotary shaft and a rotating plate supported by the rotary shaft and being configured such that the tray can be mounted on the rotating plate, a plurality of bases arranged circumferentially around the rotary shaft; and a heater provided for each of the bases.

Systems and methods related to temperature zone control systems can include a reactant source cabinet that is configured to be at least partially evacuated, a vessel base that is configured to hold solid source chemical reactant therein, and a lid that is coupled to a distal portion of the vessel base. The lid may include one or more lid valves. The system may further include a plurality of gas panel valves that are configured to deliver gas from a gas source to the vessel. The system may include a heating element that is configured to heat the one or more lid valves. The system may include a heat shield, a first portion of which is disposed between the one or more lid valves and the vessel base. A second portion of the heat shield may be disposed between the first heating element and the plurality of gas panel valves.

A method and apparatus for depositing a carbon compound on a substrate includes using an inductively coupled plasma (ICP) chamber with a chamber body, a lid, an interior volume, a pumping apparatus, and a gas delivery system and a pedestal for supporting a substrate disposed within the interior volume of the ICP chamber, the pedestal has an upper portion formed from aluminum nitride with an upper surface that is configured to support and heat a substrate with embedded heating elements and a lower portion with a tube-like structure formed from aluminum nitride that is configured to support the upper portion and house electrodes for supplying power to the embedded heating elements of the upper portion, and the pedestal is configured to heat the substrate during deposition of a carbon compound film.

Methods of processing a semiconductor substrate and apparatus to process semiconductor substrates are described. The methods and apparatus described enable the repetitive cyclic low temperature application of a chemistry and high temperature treatment step to a substrate.

A substrate processing apparatus includes an inner wall formed of a heat conductive material, a quartz liner that covers the inner wall, and a cooling unit that cools the inner wall. A gap is formed between the inner wall and the quartz liner, and a sealing member is provided in the gap to seal the gap. The gap is filled with a heat conductive medium.

Described herein is a technique capable of improving a film uniformity on a surface of a substrate and a film uniformity among a plurality of substrates including the substrate. According to one aspect thereof, there is provided a substrate processing apparatus including: a substrate retainer including: a product wafer support region, an upper dummy wafer support region and a lower dummy wafer support region; a process chamber in which the substrate retainer is accommodated; a first, a second and a third gas supplier; and an exhaust system. Each of the first gas and the third gas supplier includes a vertically extending nozzle with holes, wherein an upper of an uppermost hole and a lower end of a lowermost hole are arranged corresponding to an uppermost and a lowermost dummy wafer, respectively. The second gas supplier includes a nozzle with holes or a slit.

Embodiments described herein generally relate to a susceptor support for supporting a susceptor in a deposition process. The susceptor support includes a shaft, a plate with a first major surface coupled to the shaft, and a support element extending from a second major surface of the plate. The plate may be made of a material that is optically transparent to the radiation energy from a plurality of energy sources disposed below the plate. The plate may have a thickness that is small enough to minimize radiation transmission loss and large enough to be thermally and mechanically stable to support the susceptor during processing. The thickness of the plate may range from about 2 mm to about 20 mm.

A method of fabricating a semiconductor device includes providing a system that includes a susceptor configured to retain a semiconductor substrate, a heating element, and a reflector integrated with the heating element, where the reflector includes a surface defined by a plurality of circumferential ridges having a separation distance that varies from a top portion of the reflector to a bottom portion of the reflector. The method further includes heating the semiconductor substrate and forming an epitaxial layer on the heated semiconductor substrate, where the heating includes emitting thermal energy from the heating element and reflecting the thermal energy from the surface of the reflector onto the semiconductor substrate, where an amount of the thermal energy received by an edge of the semiconductor substrate is more than an amount of the thermal energy received by a center of the semiconductor substrate.

The disclosed methods and apparatus improve the fabrication of solid fibers and microstructures. In many embodiments, the fabrication is from gaseous, solid, semi-solid, liquid, critical, and supercritical mixtures using one or more low molar mass precursor(s), in combination with one or more high molar mass precursor(s). The methods and systems generally employ the thermal diffusion/Soret effect to concentrate the low molar mass precursor at a reaction zone, where the presence of the high molar mass precursor contributes to this concentration, and may also contribute to the reaction and insulate the reaction zone, thereby achieving higher fiber growth rates and/or reduced energy/heat expenditures together with reduced homogeneous nucleation. In some embodiments, the invention also relates to the permanent or semi-permanent recording and/or reading of information on or within fabricated fibers and microstructures. In some embodiments, the invention also relates to the fabrication of certain functionally-shaped fibers and microstructures. In some embodiments, the invention may also utilize laser beam profiling to enhance fiber and microstructure fabrication.

A radiation shield and an assembly and a reactor including the radiation shield are disclosed. The radiation shield can be used to control heat flux from a susceptor heater assembly and thereby enable better control of temperatures across a surface of a substrate placed on a surface of the susceptor heater assembly.