According to various embodiments, the temperature control roller may comprise: a cylindrical roller shell, which has a multiplicity of gas outlet openings; a temperature control device, which is configured to supply and/or extract thermal energy to or from the cylindrical roller shell; multiple gas lines made to extend along the axis of rotation; a gas distributing structure, which couples the multiple gas lines and the multiplicity of gas outlet openings to one another in a gas-conducting manner, the gas distributing structure having a lower structure density than the multiplicity of gas outlet openings.

A heating device includes a heating assembly. The heating assembly includes a ventilation structure configured to blow gas to an edge of a to-be-processed workpiece carried by the heating device. The heating device further includes a base arranged on a side of the heating assembly away from a heating surface of the heating assembly. A mounting space is formed between the base and the heating assembly. The heating device also includes a cooling mechanism arranged in the mounting space, located at a position corresponding to an edge area of the heating surface, and configured to cool the heating assembly.

A substrate processing apparatus, includes a reaction furnace, a preparatory chamber provided below the reaction furnace, an elevating mechanism configured to raise/lower a substrate holder between the reaction furnace and the preparatory chamber, a fluid circulation mechanism including a suction part for sucking a fluid within the preparatory chamber, a pipe part constituting a flow path through which the fluid flows from the suction part to a supply part, and a cooling mechanism, provided in the flow path, for cooling the fluid, and a control part for controlling the fluid circulation mechanism and the elevating mechanism to circulate the fluid sucked from the suction part through the flow path, and supply the fluid from the supply part to the preparatory chamber. The cooling mechanism is disposed adjacent to the suction part to cool the fluid introduced from the suction part before circulating the fluid through the flow path.

An electrostatic chuck is described that has radio frequency coupling suitable for use in high power plasma environments. In some examples, the chuck includes a base plate, a top plate, a first electrode in the top plate proximate the top surface of the top plate to electrostatically grip a workpiece, and a second electrode in the top plate spaced apart from the first electrode, the first and second electrodes being coupled to a power supply to electrostatically charge the first electrode.

A substrate fixing device includes a base plate including therein a gas supply section, and an electrostatic chuck provided on the base plate. The electrostatic chuck includes a base having a mounting surface on which a target to be held by electrostatic attraction is mounted, an insertion hole, penetrating the base, having an inner surface that defines the insertion hole and is threaded to form a female thread, and a screw member, having an outer surface that is threaded to form a male thread, and inserted into the insertion hole to assume a mated state in which the male thread mates with the female thread. A gas from the gas supply section is supplied to the mounting surface via the screw member.

A wafer fabricating system includes a wafer chuck, a gas inlet port, a fluid inlet port, first and second arc-shaped channels, a gas source, and a fluid containing source. The wafer chuck has a top surface, and orifices are formed on the top surface. The gas inlet port is formed in the wafer chuck and located underneath a fan-shaped sector of the top surface, wherein the gas inlet port is fluidly communicated with the orifices. The fluid inlet port is formed in the wafer chuck. The first and second arc-shaped channels are fluidly communicated with the fluid inlet port and located underneath the fan-shaped sector of the top surface and located at opposite sides of the gas inlet port from a top view. The gas source fluidly is connected to the gas inlet port. The fluid containing source fluidly is connected to the fluid inlet port.

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.

A roller for transporting a flexible substrate is described. The roller includes a main body having a plurality of gas supply slits provided in an outer surface of the main body. The plurality of gas supply slits extends in a direction of a central rotation axis of the roller. Further, the roller includes a sleeve provided circumferentially around and in contact with the main body. The sleeve has a plurality of gas outlets being provided above the plurality of gas supply slits. Further, the sleeve includes a metal layer embedded within isolating material.

In some embodiments, the present disclosure relates to a process tool that includes a chamber housing defined by a processing chamber, and a wafer chuck structure arranged within the processing chamber. The wafer chuck structure is configured to hold a wafer during a fabrication process. The wafer chuck includes a lower portion and an upper portion arranged over the lower portion. The lower portion includes trenches extending from a topmost surface towards a bottommost surface of the lower portion. The upper portion includes openings that are holes, extend completely through the upper portion, and directly overlie the trenches of the lower portion. Multiple of the openings directly overlie each trench. Further, cooling gas piping is coupled to the trenches of the lower portion of the wafer chuck structure, and a cooling gas source is coupled to the cooling gas piping.

There is provided a film-forming apparatus including: a processing container, wherein a reaction gas is supplied into the processing container; a stage disposed inside the processing container and provided with a substrate heating part, the stage being configured to place a substrate thereon; a support member configured to support the stage from a rear surface of the stage, wherein the rear surface faces a placement surface on which the substrate is placed; a temperature control member disposed on the rear surface of the stage and including a hollow portion formed to cover the support member, the temperature control member configured to have a controllable temperature; a heat-insulating member disposed between the stage and the temperature control member; and a purge gas supply part configured to supply a purge gas to a first gap formed between the support member and the temperature control member.