A gas generation system for an ion implantation system has a hydrogen generator configured to generate hydrogen gas within an enclosure. A chuck, such as an electrostatic chuck, supports a workpiece in an end station of the ion implantation system, and a delivery system provides the hydrogen gas to the chuck. The hydrogen gas can be provided through the chuck to a backside of the workpiece. Sensors can detect a presence of the hydrogen gas within the enclosure. A controller can control the hydrogen generator. An exhaust system can pass air through the enclosure to prevent a build-up of the hydrogen gas within the enclosure. A purge gas system provides a dilutant gas to the enclosure. An interlock system can control the hydrogen generator, delivery system, purge gas system, and exhaust system to mitigate hydrogen release based on a signal from the one or more sensors.

Apparatus include a plurality of electrode arrangements spaced apart from each other opposite an ion propagation axis and defining an ion transfer channel that extends along the ion propagation axis that tapers between an input end that is situated to receive ions and an output end that is situated to couple the received ions to an input end of an ion guide. Methods include positioning a plurality of electrode arrangements at oblique angles opposite an ion propagation axis so as to form a ion transfer channel that tapers between an input end and an output end, and coupling the output end of the ion transfer channel to an input end of an ion optical element so as to direct ions in the ion transfer channel into the ion optical element. Related systems are also disclosed.

A bottom ring is configured to support a moveable edge ring. The edge ring is configured to be raised and lowered relative to a substrate support. The bottom ring includes an upper surface that is stepped, an annular inner diameter, an annular outer diameter, a lower surface, and a plurality of vertical guide channels provided through the bottom ring from the lower surface to the upper surface of the bottom ring. Each of the guide channels includes a first region having a smaller diameter than the guide channel, and the guide channels are configured to receive respective lift pins for raising and lowering the edge ring.

A plasma processing apparatus includes a process chamber having an inner space, an electrostatic chuck in the process chamber and to which a substrate is mounted, a gas injection unit to inject a process gas into the process chamber at a side of the process chamber, a plasma applying unit to transform the process gas injected into the process chamber into plasma, and a plasma adjusting unit disposed around the electrostatic chuck and operative to adjust the density of the plasma across the substrate.

Systems and methods for implementing charged particle flooding in a charged particle beam apparatus are disclosed. According to certain embodiments, a charged particle beam system includes a charged particle source and a controller which controls the charged particle beam system to emit a charged particle beam in a first mode where the beam is defocused and a second mode where the beam is focused on a surface of a sample.

In a processing chamber, a processing target substrate is placed and a substrate processing is performed. A holder is configured to store therein an ionic liquid as some or all of components to be consumed or degraded by the substrate processing within the processing chamber.

A height detection apparatus is configured to project a pattern on a sample arranged at any of a plurality of reference positions and configured to detect a height of the sample. The apparatus includes: a projection optical system that generates a plurality of spatially separated light beams each having the pattern and projects the generated spatially separated light beams onto the sample; an imaging element that images the pattern reflected from the sample; a detection optical system that guides the pattern reflected from the sample to the imaging element; and at least one optical path length correction member disposed on an optical path different from an optical path having a shortest optical path length among a plurality of optical paths corresponding to the plurality of light beams at a position where the plurality of light beams is spatially separated.

Provided herein are approaches for in-situ plasma cleaning of ion beam optics. In one approach, a system includes a component (e.g., a beam-line component) of an ion implanter processing chamber. The system further includes a power supply for supplying a first voltage and first current to the component during a processing mode and a second voltage and second current to the component during a cleaning mode. The second voltage and current are applied to one or more conductive beam optics of the component, individually, to selectively generate plasma around one or more of the one or more conductive beam optics. The system may further include a flow controller for adjusting an injection rate of an etchant gas supplied to the beam-line component, and a vacuum pump for adjusting pressure of an environment of the beam-line component.

Provided herein are approaches for in-situ plasma cleaning of one or more components of an ion implantation system. In one approach, the component may include a beam-line component having one or more conductive beam optics. The system further includes a power supply for supplying a first voltage and first current to the component during a processing mode and a second voltage and second current to the component during a cleaning mode. The second voltage and current may be applied to the conductive beam optics of the component, in parallel, to selectively (e.g., individually) generate plasma around one or more of the one or more conductive beam optics. The system may further include a flow controller for adjusting an injection rate of an etchant gas supplied to the component, and a vacuum pump for adjusting pressure of an environment of the component.

Systems and methods for implementing charged particle flooding in a charged particle beam apparatus are disclosed. According to certain embodiments, a charged particle beam system includes a charged particle source and a controller which controls the charged particle beam system to emit a charged particle beam in a first mode where the beam is defocused and a second mode where the beam is focused on a surface of a sample.