A method for processing semiconductor wafer is provided. The method includes loading a semiconductor wafer on a top surface of a wafer chuck. The method also includes supplying a gaseous material between the semiconductor wafer and the top surface of the wafer chuck through a first gas inlet port and a second gas inlet port located underneath a fan-shaped sector of the top surface. The method further includes supplying a fluid medium to a fluid inlet port of the wafer chuck and guiding the fluid medium from the fluid inlet port to flow through a number of arc-shaped channels located underneath the fan-shaped sector of the top surface. In addition, the method includes supplying a plasma gas over the semiconductor wafer.

Methods and systems for forming films on substrates in semiconductor processes are disclosed. The method includes providing different materials each contained in separate ampoules. Material is flowed from each ampoule into a separate portion of a showerhead contained within a process chamber via a heated gas line. From the showerhead, each material is flowed on to a substrate that sits on the surface of a rotating pedestal. Controlling the mass flow rate out of the showerhead and the rotation rate of the pedestal helps result in films with desirable material domain sizes to be deposited on the substrate.

A film forming method includes: rotating a rotary table to revolve a substrate which is placed on the rotary table and has a recess in its surface; supplying a raw material gas to a first region on the rotary table; supplying an ammonia gas to a second region on the rotary table; forming a first SiN film in the recess by supplying the raw material gas to the first region and supplying the ammonia gas to the second region at a first flow rate, while the rotary table rotates at a first rotation speed; and forming a second SiN film in the recess such that the second SiN film is laminated on the first SiN film by supplying the raw material gas to the first region and supplying the ammonia gas to the second region at a second flow rate, while the rotary table rotates at a second rotation speed.

Disclosed a semiconductor deposition method and a semiconductor deposition system. The semiconductor deposition method includes providing a deposition apparatus, the deposition apparatus includes a spraying head for deposition; detecting whether a thickness defect exists in a deposited thin film or not, the thickness defect includes a thickness difference of the deposited thin film; acquiring at least one position where the thickness defect exists; and adjusting a structure of an air outlet panel in the spraying head based on the position of the thickness defect so as to adjust distances between air outlet holes in the air outlet panel and the deposited thin film.

A method of forming a metal oxide layer includes at least the following steps. A substrate is provided in a process chamber of a deposition apparatus, where the substrate has a target layer formed thereon. A first gas and a second gas are introduced into the process chamber through a shower head of the deposition apparatus, so as to form a metal oxide film on the target layer, where the shower head is coated with a hydrophobic film. A patterned photoresist layer is formed on the metal oxide film. The metal oxide film is patterned by using the patterned photoresist layer as a mask, so as to form a patterned metal oxide film. The target layer is patterned by using the patterned metal oxide film as a mask.

Systems and methods for cleaning a showerhead are described. One of the systems includes a support section and a press plate located above the support section to be supported by the support section. The system further includes a cleaning layer located above the press plate. The cleaning layer moves to clean a showerhead. The support section contacts an arm of a spindle assembly for movement with movement of the arm.

A CVD apparatus includes a chamber, a susceptor, an entry/takeout port for a substrate, and a gate valve provided at the entry/takeout port, in which the susceptor has a mounting plate and a support, the entry/takeout port is provided on a part of a side of the chamber, and is provided in a range from an inner bottom surface of the chamber to a position corresponding to the lower surface of the mounting plate when the susceptor is located at an upper end in the vertical direction, and the inner bottom surface of the chamber, the range from the inner bottom surface of the chamber to the position corresponding to the lower surface of the mounting plate when the susceptor is located at the upper end in the vertical direction, the lower surface of the mounting plate, and the outer side surface of the support are coated with ceramic liners.

Gas injector inserts having a wedge-shaped housing, at least one first slot and at least one second slot are described. The housing has a first opening in the back face that is in fluid communication with the first slot in the front face and a second opening in the back face that is in fluid communication with the second slot in the front face. Each of the first slot and the second slot has an elongate axis that extends from the inner peripheral end to the outer peripheral end of the housing. The gas injector insert is configured to provide a flow of gas through the first slots at supersonic velocity. Gas distribution assemblies and processing chambers including the gas injector inserts are described.

Apparatus and methods for providing high velocity gas flow showerheads for deposition chambers are described. The showerhead has a faceplate in contact with a backing plate that has a concave portion to provide a plenum between the backing plate and the faceplate. A plurality of thermal elements is within the concave portion of the backing plate and extends to contact the faceplate.

A method of processing a semiconductor wafer is provided. The method includes installing upper lid. The installation of the upper lid includes placing an inlet manifold on a water box; inserting a jig into a lower gas channel in the water box and inserting into an upper gas channel in the inlet manifold; fastening the water box to the inlet manifold; and removing the jig after the water box engaging with the inlet manifold. The method also includes connecting a shower head on a lower side of the water box; and connecting the upper lid to a housing. The method further includes placing a semiconductor wafer into the housing. In addition, the method includes supplying a process gas over the semiconductor wafer through the upper gas channel, the lower gas channel and the shower head.