A processing chamber such as a plasma etch chamber can perform deposition and etch operations, where byproducts of the deposition and etch operations can build up in a vacuum pump system fluidly coupled to the processing chamber. A vacuum pump system may have multiple roughing pumps so that etch gases can be diverted a roughing pump and deposition precursors can be diverted to another roughing pump. A divert line may route unused deposition precursors through a separate roughing pump. Deposition byproducts can be prevented from forming by incorporating one or more gas ejectors or venturi pumps at an outlet of a primary pump in a vacuum pump system. Cleaning operations, such as waferless automated cleaning operations, using certain clean chemistries may remove deposition byproducts before or after etch operations.

A plasma processing apparatus includes a microwave output unit, a wave guide tube, a tuner, a demodulation unit, and a calculation unit. The microwave output unit outputs a microwave having power corresponding to setting power while frequency-modulating the microwave in a setting frequency range. The wave guide tube guides the microwave to an antenna of a chamber main body. The tuner is provided in the wave guide tube and adjusts a position of a movable plate. The demodulation unit is provided in the wave guide tube, and acquires travelling wave power and reflected wave power for each frequency. The calculation unit calculates a frequency at which a reflection coefficient, which is calculated on the basis of the travelling wave power and the reflected wave power, for each frequency becomes a minimum point as an absorption frequency.

A method for removing residue deposits from a reaction chamber includes supplying a cleaning gas into the reaction chamber via direct delivery from a remote plasma source (RPS). The cleaning gas forms a plurality of gas flow streamlines within the reaction chamber. Each of the streamlines originates at an injection point for receiving the cleaning gas and terminates at a chamber pump port coupled to a fore line for evacuating the cleaning gas. A flow characteristic of the cleaning gas is modified to redirect at least a portion of the gas flow streamlines to circulate in proximity to an inner perimeter of the reaction chamber to remove the residue deposits or to enhance the diffusion of cleaning species to surfaces to be cleaned. The inner perimeter is disposed along one or more vertical surfaces of the reaction chamber that are orthogonal to a horizontal surface including the injection point.

A semiconductor machine system comprises a plurality of working chambers, wherein the working chambers process materials separately; a control host coupled to the plurality of working chambers, comprising: a main control module coupled to the plurality of working chambers; an analog control module coupled to the plurality of working chambers, and the analog control module is detachably coupled to one or more external devices by serial interface coupling; a digital control module coupled to the plurality of working chambers, and the main control module, the analog control module and the digital control module are coupled to each other; and a plurality of operating units coupled to at least one of the main control module, the analog control module and the digital control module, respectively, to control the plurality of working chambers for processing the materials by the main control module, the analog control module and the digital control module.

An embodiment provides a deposition apparatus, including: a process chamber; a residual gas analyzer connected to the process chamber; a cleansing gas supplier connected to the process chamber; and a driver that is connected to the residual gas analyzer and the cleansing gas supplier and controls the residual gas analyzer and the cleansing gas supplier.

According to one aspect of the technique of the present disclosure, there is provided a substrate processing apparatus including: a process vessel in which a substrate is processed; an outer vessel configured to cover an outer circumference of the process vessel; a gas flow path provided between the outer vessel and the outer circumference of the process vessel; an exhaust path in communication with the gas flow path; an adjusting valve configured to be capable of adjusting a conductance of the exhaust path; a first exhaust apparatus provided on the exhaust path downstream of the adjusting valve; a pressure sensor configured to measure an inner pressure of the outer vessel; and a controller configured to be capable of adjusting an exhaust volume flow rate of the first exhaust apparatus by controlling the first exhaust apparatus based on a pressure measured by the pressure sensor.

A processing method of a workpiece in which the workpiece with a plate shape is processed by using a vacuum chamber is provided. In the processing method of a workpiece, a negative pressure is caused to act on a holding surface from a suction path, and suction holding of the workpiece is executed by a chuck table. Then, the gas pressure in the vacuum chamber is reduced to at least 50 Pa and at most 5000 Pa. Then, while the suction holding of the workpiece is executed, an inert gas in a plasma state is supplied to the workpiece, and voltages are applied to electrodes disposed in the chuck table to execute electrostatic adhesion of the workpiece by the chuck table. Then, a processing gas in a plasma state is supplied, and dry etching of the workpiece is executed.

A gas supply system includes first and second gas supply lines, first and second valves, and a controller. The first gas supply line is connected between a process gas source and a substrate processing chamber and has an intermediate node. The second gas supply line is connected between a purge gas source and the intermediate node. The first valve is disposed upstream of the intermediate node on the first gas supply line. The second valve is disposed upstream of the first valve on the first gas supply line. A controller controls the first and second valves to open the first and second valves in a first mode for supplying a process gas from the process gas source to the substrate processing chamber, and close the first and second valves in a second mode for supplying a purge gas from the purge gas source to the substrate processing chamber.

The invention relates to a high-frequency grounding device (40) for use with a vacuum valve for closing and opening a valve opening of a vacuum chamber system, having a grounding band (42) made of a conductive material for discharging electrical charges occurring on the vacuum valve, wherein the grounding band has a first end (41) and a second end (43) and, for grounding the vacuum valve, is designed to be connected at the first end to a valve closure of the vacuum valve, and to be connected at the second end to a component of the vacuum chamber system, wherein the high-frequency grounding device has a correction impedance, wherein the grounding band is coupled to the correction impedance so that a resonant circuit results, which comprises the grounding band and the correction impedance, and the correction impedance has a first element for shifting a resonant frequency of the resonant circuit and/or a second element for reducing a quality of the resonant circuit. The invention additionally relates to a vacuum valve and a vacuum chamber system having such a high-frequency grounding device.

A plasma processing device includes: a plurality of processing chambers; a junction exhaust pipe into which a plurality of exhaust flow paths for evacuating interiors of the plurality of processing chambers joins; and a plurality of branch exhaust pipes disposed between the plurality of exhaust flow paths and the junction exhaust pipe and connecting the junction exhaust pipe to the plurality of exhaust flow paths, respectively, wherein each of the plurality of branch exhaust pipes includes a mechanism, which is disposed in a flow path of the branch exhaust pipe, to deactivate energy of hot electrons flowing through the flow path.