The reaction chamber (100) is used for a deposition reactor of layers of semiconductor material on substrates; it comprises a tube (110) made of quartz and having a cylindrical shape and adapted to be positioned in use so that its axis (111) is vertical; the tube (110) has a cylindrical inner interspace (112) which extends along the entire length of the tube (110) and which is adapted to accommodate a flowing liquid; the chamber (100) further comprises an annular closing element (120) made of quartz and fixed to a first lower end of the tube (110) so as to close the interspace (112) preventing the liquid from flowing out of the interspace at the bottom; at the top, the closing element (120) has an annular recess (122) facing the interspace (112) so that the flowing liquid can reach the recess (122) at the bottom; the chamber (100) further comprises a set of internal conduits (130) internal to the interspace (112), wherein said internal conduits (130) extend from the first lower region of the tube (110) till a second upper region of the tube (110) to facilitate circulation of the flowing liquid in the interspace (112).

A CVD reactor may include a susceptor, process chamber and heat dissipation body. In the CVD reactor, one or more layers can be deposited on one or more substrates. The susceptor is heated by a heating device. Heat is transported from the susceptor, through a process chamber towards the process chamber ceiling, through the process chamber ceiling, and from the process chamber ceiling through a gap space to the heat dissipation body. The temperature of the process chamber ceiling is measured at at least two different azimuth angle positions about a central axis of the process chamber. The radial distance of the respective measurement points or zones from the central axis of the process chamber may be equal to one another. The at least two temperature measurement values are used to produce an average value or a difference value.

According to one embodiment, a film formation apparatus and a moisture removing method thereof that can facilitate the removement of moisture in the chamber without the complication of the apparatus are provided. The film formation apparatus according to the present embodiment includes the chamber 10 which an interior thereof can be made vacuum, the exhauster 20 that exhausts the interior of the chamber 10, the carrier 30 that circularly carries the workpiece W by a rotation table 31 provided inside the chamber 10, and the plurality of the plasma processor 40 that performs plasma processing on the workpiece W which is circularly carried, in which the plurality of the plasma processor 40 each has the processing spaces 41 and 42 to perform the plasma processing, at least one of the plurality of the plasma processor 40 is the film formation processor 410 that performs film formation processing by sputtering on the workpiece W which is circularly carried, and at least one of the plurality of the plasma processor 40 is the heater 420 that removes moisture in the chamber 10 by producing plasma and heating the interior of the chamber 10 via the rotation table 31 together with exhaustion by the exhauster 20 and rotation by the rotation table 31 in a condition the film formation process by the film formation processor 410 is not performed.

A chemical vapor deposition apparatus includes a chamber, a susceptor supporting a substrate, a backing plate to which power is applied, a diffuser providing a deposition gas, and a first insulator. The first insulator may include a first portion covering a top surface of the backing plate, and a second portion assembled with the first portion and covering a sidewall of the backing plate.

Methods and apparatus for an upper reflector assembly for use in a process chamber are provided herein. In some embodiments, an upper reflector assembly for use in a process chamber includes a reflector mounting ring; and upper reflector plate coupled to the reflector mounting ring and having an upper surface and lower surface, wherein the lower surface includes a plurality of linear channels extending substantially parallel to each other across the lower surface, and wherein the upper reflector plate includes air cooling slots extending from the upper surface to the lower surface.

Embodiments herein relate to chamber liners with a multi-piece design for use in processing chambers. The multi-piece design can have an inner portion and an outer portion. A portion of the inner surface of the outer portion may be designed to be in contact with the outer surface of the inner portion at a single junction point, creating a thermal barrier between the inner portion and outer portion, thus reducing heat transfer from the inner portion and outer portion. The thermal barrier creates higher temperatures at the chamber liner inner surface and therefore leads to shorter heat up times within the chamber. Additionally, the thermal barrier also creates lower temperatures near the base ring and outer surface of the outer ring, thereby protecting the chamber walls and requiring less thermal regulation/dissipation at the chamber walls.

An epitaxial deposition chamber having an upper cone for controlling air flow above a dome in the chamber, such as a high growth rate epitaxy chamber, is described herein. The upper cone has first and second components separated by two or more gaps in the chamber, each component having a partial cylindrical region having a first concave inner surface, a first convex outer surface, and a fixed radius of curvature of the first concave inner surface, and a partial conical region extending from the partial cylindrical region, the partial conical region having a second concave inner surface, a second convex outer surface, and a varying radius of curvature of the second concave inner surface, wherein the second concave inner surface extends from the partial cylindrical region to a second radius of curvature less than the fixed radius of curvature.

The present disclosure generally relate to a semiconductor processing apparatus. In one embodiment, a processing chamber is disclosed herein. The processing chamber includes a chamber body and lid defining an interior volume, the lid configured to support a housing having a cap, a substrate support disposed in the interior volume, a vaporizer coupled to the cap and having an outlet open to the interior volume of the processing chamber, wherein the vaporizer is configured to deliver a precursor gas to a processing region defined between the vaporizer and the substrate support, and a heater disposed adjacent to the vaporizer, wherein the heater is configured to heat the vaporizer.

A film forming apparatus includes: a film forming gas discharge part; an exhaust port; a rotation mechanism; a heating part configured to heat the interior of a reaction container to a temperature lower than a temperature of a film forming gas discharged from the film forming gas discharge part; first gas discharge holes opened, in the film forming gas discharge part, toward a gas temperature reducing member so that the film forming gas is cooled by colliding with the gas temperature reducing member inside the reaction container before the film forming gas is supplied to substrates; and second gas discharge holes opened, in the film forming gas discharge part, in a direction differing from an opening direction of the first gas discharge holes so that the film forming gas does not collide with the gas temperature reducing member before the film forming gas is supplied to the substrates.

A reaction chamber for vapor deposition apparatus, comprises a susceptor to carry substrates, a ceiling, an upper cavity, and protrusions. The ceiling comprises a front surface faces the substrates and comprises front convex parts and front concave parts with an interlaced arrangement to form a convex-concave surface. The ceiling also comprises a rear surface opposites to the front surface and comprises rear convex parts and rear concave parts corresponded to the front concave parts and the front convex parts respectively. The upper cavity opposites to the rear surface and separated to the rear convex parts to define a first flow channel. The protrusions are disposed in the rear concave parts and separated to a side wall and a bottom wall of the rear concave parts to define a second flow channel which is connected to the first flow channel to introduce a cooling fluid.