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.

The disclosure relates to an electron-optical module of an electron-optical apparatus. The electron-optical module comprises a vacuum chamber, a high voltage shielding arrangement located within the vacuum chamber, and an aperture array configured to form a plurality of beamlets from an electron beam and located within the high voltage shielding arrangement. Wherein the electron-optical module can be configured to be removable from the electron-optical apparatus.

In one example, a workpiece support structure of a plasma treatment chamber has upper and lower ends, and first and second support members that extend between the upper and lower ends. The support members are electrically isolated from one another and offset from one another along a horizontal direction so as to define a cavity therebetween. The first and second support members support electrodes within the cavity such that (1) the electrodes are offset from one another along the vertical direction, (2) the electrodes extend between the first and second support members along the first horizontal direction, (3) a first set of the electrodes are electrically coupled to the first support member and electrically isolated from the second support member, and (4) a second set of the electrodes, different from the first set, are electrically coupled to the second support member and electrically isolated from the first support member.

An ion implantation system including an ion implanter, a dopant source gas supply system and a monitoring system is provided. The ion implanter is inside a housing and includes an ion source unit. The dopant source gas supply system includes a first and a second dopant source gas storage cylinder in a gas cabinet outside of the housing and configured to supply a dopant source gas to the ion source unit, and a first and a second dopant source gas supply pipe coupled to respective first and second dopant source gas storage cylinders. Each of the first and second dopant source gas supply pipes includes an inner pipe and an outer pipe enclosing the inner pipe. The monitoring system is coupled to the outer pipe of each of the first and the second dopant source gas supply pipes.

An electron beam source including a cathode, an anode, a means for deflecting an electron beam over a target surface and at least one vacuum pump, the electron beam source further including a contraction area arranged between the anode and the means for deflecting the electron beam where a hole in the contraction area is aligned with a hole in the anode with respect to the cathode, a first vacuum pump is arranged between the contraction area and the anode and a second vacuum pump is arranged above the anode, a gas inlet is provided between the contraction area and the means for deflecting the electron beam, wherein a first crossover of the electron beam is arranged between the cathode and the anode and a second crossover is arranged at or in close proximity to the contraction area.

A processing method includes: disposing a workpiece in a processing container of a processing apparatus, and maintaining an inside of the processing container in a vacuum state; providing a cluster nozzle in the processing container; supplying a cluster generating gas to the cluster nozzle and adiabatically expanding the cluster generating gas in the cluster nozzle, thereby generating gas clusters; generating plasma in the cluster nozzle to ionize the gas clusters and injecting the ionized gas clusters onto the workpiece; supplying a reactive gas to the cluster nozzle and exposing the reactive gas to the plasma such that the reactive gas becomes monomer ions or radicals; and supplying the monomer ions or radicals to the processing container, thereby exerting a chemical reaction on a substance present on a surface of the workpiece.

There is provided a decompression processing method for a substrate processing apparatus including a chamber for processing a substrate in an inside thereof, a decompression unit that decompresses the inside of the chamber, and a gas supply that supplies a gas into the inside of the chamber, the method including supplying an additional substance mixable with moisture in a liquid or solid state by the gas supply to the inside of the chamber, forming the moisture into a mixture of the additional substance, and decompressing the inside of the chamber by the decompression unit to remove as a gas the mixture from the inside of the chamber.

The invention provides an electron beam apparatus that reduces a time required for an electron gun chamber to which a sputter ion pump and a non-evaporable getter pump are connected to reach an extreme high vacuum state. The electron beam apparatus includes an electron gun configured to emit an electron beam and the electron gun chamber to which the sputter ion pump and the non-evaporable getter pump are connected. The electron beam apparatus further includes a gas supply unit configured to supply at least one of hydrogen, oxygen, carbon monoxide, and carbon dioxide to the electron gun chamber.