A substrate support assembly suitable for use in a reactor including a common processing and substrate transfer region is disclosed. The substrate support assembly includes a susceptor and one or more lift pins that can be used to lower a substrate onto a surface of the susceptor and raise the substrate from the surface, to allow transfer of the substrate from the processing region, without raising or lowering the susceptor.

A substrate support assembly suitable for use in a reactor including a common processing and substrate transfer region is disclosed. The substrate support assembly includes a susceptor and one or more lift pins that can be used to lower a substrate onto a surface of the susceptor and raise the substrate from the surface, to allow transfer of the substrate from the processing region, without raising or lowering the susceptor.

The present disclosure generally relates to a process chamber for processing of semiconductor substrates. The process chamber includes an upper lamp assembly, a lower lamp assembly, a substrate support, an upper window disposed between the substrate support and the upper lamp assembly, a lower window disposed between the lower lamp assembly and the substrate support, an inject ring, and a base ring. Each of the upper lamp assembly and the lower lamp assembly include vertically oriented lamp apertures for the placement of heating lamps therein. The inject ring includes gas injectors disposed therethrough and the base ring includes a substrate transfer passage, a lower chamber exhaust passage, and one or more upper chamber exhaust passages. The gas injectors are disposed over the substrate transfer passage and across from the lower chamber exhaust passage and the one or more upper chamber exhaust passages.

The present disclosure generally relates to a process chamber for processing of semiconductor substrates. The process chamber includes an upper lamp assembly, a lower lamp assembly, a substrate support, an upper window disposed between the substrate support and the upper lamp assembly, a lower window disposed between the lower lamp assembly and the substrate support, an inject ring, and a base ring. Each of the upper lamp assembly and the lower lamp assembly include vertically oriented lamp apertures for the placement of heating lamps therein. The inject ring includes gas injectors disposed therethrough and the base ring includes a substrate transfer passage, a lower chamber exhaust passage, and one or more upper chamber exhaust passages. The gas injectors are disposed over the substrate transfer passage and across from the lower chamber exhaust passage and the one or more upper chamber exhaust passages.

This disclosure provides a vapor-liquid reaction device including a vapor-liquid reaction chamber and a projecting member. The vapor-liquid reaction chamber holds a molten metal in a lower portion of an internal space of the vapor-liquid reaction chamber.

This disclosure provides a vapor-liquid reaction device including a vapor-liquid reaction chamber and a projecting member. The vapor-liquid reaction chamber holds a molten metal in a lower portion of an internal space of the vapor-liquid reaction chamber.

The present disclosure provides an epitaxial device and a gas intake structure configured for the epitaxial device. The epitaxial device includes a chamber, a submount, a gas intake structure, and an exhaust structure. The gas intake structure includes: a plurality of first gas intake passages configured to provide a first process gas containing a gas for an epitaxial reaction to a to-be-processed surface along a first direction, the first direction being parallel to the to-be-processed surface; and two second gas intake passages that are arranged at intervals along a second direction, and correspond to two adjustment areas adjacent to edges on both sides of the to-be-processed surface respectively, where at least one first gas intake passage is disposed between the two second gas intake passages, each second gas intake passage provides a second process gas to the corresponding adjustment area along the first direction, and the second process gas is configured to adjust a concentration of the gas for the epitaxial reaction flowing through the adjustment areas. The epitaxial device and the gas intake structure provided by the embodiments of the present disclosure improve uniformity of thickness distribution of an epitaxial layer formed on the entire to-be-processed surface.

The present disclosure provides an epitaxial device and a gas intake structure configured for the epitaxial device. The epitaxial device includes a chamber, a submount, a gas intake structure, and an exhaust structure. The gas intake structure includes: a plurality of first gas intake passages configured to provide a first process gas containing a gas for an epitaxial reaction to a to-be-processed surface along a first direction, the first direction being parallel to the to-be-processed surface; and two second gas intake passages that are arranged at intervals along a second direction, and correspond to two adjustment areas adjacent to edges on both sides of the to-be-processed surface respectively, where at least one first gas intake passage is disposed between the two second gas intake passages, each second gas intake passage provides a second process gas to the corresponding adjustment area along the first direction, and the second process gas is configured to adjust a concentration of the gas for the epitaxial reaction flowing through the adjustment areas. The epitaxial device and the gas intake structure provided by the embodiments of the present disclosure improve uniformity of thickness distribution of an epitaxial layer formed on the entire to-be-processed surface.

A substrate processing apparatus, includes a reaction chamber, an outer chamber at least partly surrounding the reaction chamber wherein an intermediate space is formed between the reaction chamber and the outer chamber, at least one heater element, at least one heat distributor in the intermediate space, and at least one heater element feedthrough in the outer chamber allowing at least a part of the at least one heater element to pass through into the intermediate space and to couple with the at least one heat distributor.

A method for making a transition metal dichalcogenide crystal having a chemical formula represented as MX.sub.2 is provided, wherein M represents a central transition metal element, and X represents a chalcogen element. The method includes providing a MX.sub.2 polycrystalline powder, a MX.sub.2 seed crystal, and a transport medium. The MX.sub.2 polycrystalline powder and the transport medium are placed in a first reaction chamber. The first reaction chamber and the MX.sub.2 seed crystal are placed in a second reaction chamber having a source end and a deposition end opposite to the source end. The first reaction chamber is placed at the source end, and the MX.sub.2 seed crystal is placed at the deposition end.