A method for operating a substrate processing system includes delivering precursor gas to a chamber using a showerhead that includes a head portion and a stem portion. The head portion includes an upper surface, a sidewall, a lower planar surface, and a cylindrical cavity and extends radially outwardly from one end of the stem portion towards sidewalls of the chamber. The showerhead is connected, using a collar, to an upper surface of the chamber. The collar is arranged around the stem portion. Process gas is flowed into the cylindrical cavity via the stem portion and through a plurality of holes in the lower planar surface to distribute the process gas into the chamber. A purge gas is supplied through slots of the collar into a cavity defined between the head portion and an upper surface of the chamber.

A vapor phase growth apparatus of an embodiment includes: a reactor; a first gas chamber provided above the reactor, a first process gas being introduced into the first gas chamber; a plurality of first gas conduits for supplying the first process gas from the first gas chamber to the reactor, each of the first gas conduits having a predetermined length; and a first adjustment conduit inserted to an upper side of one of the plurality of first gas conduits. The first adjustment conduit has as annular protrusion provided on an outer periphery of an upper end portion and is removable from the first gas conduit.

A method for making a monocrystalline structure is disclosed. The method includes depositing a first volume of a material on a substrate to create a first crystal seed and depositing a second volume of the material towards the substrate to nucleate with the first crystal seed to create a first initial epitaxial structure.

A plasma processing apparatus includes a baffle structure between a mounting table and a processing chamber. The baffle structure has a first member and a second member. The first member has a first cylindrical part extending between the mounting cable and the processing chamber, and a plurality of through-holes elongated in the vertical direction is formed in an array in the circumferential direction in the first cylindrical part. The second member has a second cylindrical part having an inner diameter greater than the outer diameter of the cylindrical part for the first member. The second member moves up and down in a region that includes the space between the first member and the processing chamber.

High pressure spatial chemical vapor deposition apparatuses and related process are disclosed for forming thin films on a substrate. An enclosure includes plural process chambers fluidly isolated from each other by radial separating barriers. Each chamber contains a different source gas comprising one or more volatile reactive species. The substrate is supported beneath the chambers on a rotating heated susceptor. Rotation of the susceptor carries the substrate in a path which consecutively exposes the substrate to the volatile reactive species in each process chamber. The gases first mix in the gaseous boundary layer formed adjacent the substrate. A thin film gradually grows in thickness on the substrate with each successive pass and exposure to the volatile reactive species in each of the individual process chambers. The film may be grown at high pressures exceeding 1 atmosphere in some implementations. A modular design includes an outer shell and different interchangeable process inserts.

A reaction apparatus includes an upper dome, a lower dome, an upper liner, a lower liner, and a preheat ring. The upper dome and the lower dome define a reaction chamber. The preheat ring is positioned within the reaction chamber for heating the process gas prior to contacting the semiconductor wafer. The preheating ring is attached to an inner circumference of the lower liner. The preheat ring includes an annular disk and an edge bar. The annular disk has an inner edge, an outer edge, a first side, and a second side opposite the first side. The inner edge and the outer edge define a radial distance therebetween. The edge bar positioned on the first side and extending from the outer edge toward the inner edge an edge bar radial thickness. The radial distance is greater than the edge bar radial thickness.

Apparatuses and a method for gas phase deposition of high aspect ratio molecular structures, HARM-structures, are presented. The first aspect relates to an apparatus configured for oriented gas phase deposition of HARM-structures on a filter. The second aspect relates to an apparatus configured for oriented gas phase deposition of HARM-structures on a substrate. A system comprising multiple apparatuses according to the second aspect is also presented. Elements of the apparatuses are arranged to create a laminar flow of gas comprising HARM-structures in the deposition area, and to direct this flow at least partially parallel to the deposition area. Another aspect of the invention is a method for oriented deposition of HARM-structures, suitable for deposition both on a filter and a substrate.

A batch processing oven comprising a processing chamber and a rack configured to be positioned in the processing chamber. The rack is configured to support a plurality of substrates and a plurality of panels in a stacked manner such that one or more substrates of the plurality of substrates are positioned between at least one pair of adjacent panels of the plurality panels. Vertical gaps separate each substrate of the one or more substrates from an adjacent substrate or panel on either side of the substrate.

Exemplary semiconductor processing systems may include an output manifold that defines at least one plasma outlet. The systems may include a gasbox disposed beneath the output manifold. The gasbox may include an inlet side facing the output manifold and an outlet side opposite the inlet side. The gasbox may include an inner wall that defines a central fluid lumen. The inner wall may taper outward from the inlet side to the outlet side. The systems may include an annular spacer disposed below the gasbox. An inner diameter of the annular spacer may be greater than a largest inner diameter of the central fluid lumen. The systems may include a faceplate disposed beneath the annular spacer. The faceplate may define a plurality of apertures extending through a thickness of the faceplate.

An apparatus for manufacturing a semiconductor device includes a chamber including a lower housing and an upper housing, heater chucks in the lower housing, shower heads on the heater chucks, the shower heads being between the lower housing and the upper housing, power supplies connected to the shower heads to provide radio-frequency powers to the shower heads, power straps in the upper housing to connect the shower heads to the power supplies, and shielding members in the upper housing, the shielding members enclosing the power straps and the shower heads, respectively, the shielding members to prevent electromagnetic interference of the radio-frequency powers between the power straps and between the shower heads.