A measurement system for a plasma processing system includes a detector and an ion current meter coupled to the ion current collector and configured to provide a signal based on the measurements from the ion current collector. The detector includes an insulating substrate including a cavity, an ion angle selection grid configured to be exposed to a bulk plasma disposed in an upper portion of the cavity, and an ion current collector disposed within the cavity at an opposite side of the cavity below the ion angle selection grid. The ion angle selection grid includes an ion angle selection substrate and a plurality of through openings extending through the ion angle selection substrate, where each of the plurality of through openings has a depth into the ion angle selection substrate and a width orthogonal to the depth, where a ratio of the depth to the width is greater than or equal to 40.

Systems and methods for improving doping and/or deposition uniformity using a tunable electromagnetic field generation device are provided. In an exemplary embodiment, the system includes a chamber configured to contain a semiconductor wafer, a plasma generator, and a gas inlet, and an exhaust gas outlet. The gas inlet permits a controlled flow of a gas into the chamber through a wall of the chamber and the exhaust gas outlet permits exhausting of gas from the chamber. The system further includes a wafer support structure configured to support the semiconductor wafer during a doping or deposition process and an electromagnetic structure positioned within the chamber and at least partially surrounding an upper surface of the wafer support structure.

A processing apparatus may include a plasma chamber to house a plasma and having a main body portion comprising an electrical insulator; an extraction plate disposed along an extraction side of the plasma chamber, the extraction plate being electrically conductive and having an extraction aperture; a substrate stage disposed outside of the plasma chamber and adjacent the extraction aperture, the substrate stage being at ground potential; and an RF generator electrically coupled to the extraction plate, the RF generator establishing a positive dc self-bias voltage at the extraction plate with respect to ground potential when the plasma is present in the plasma chamber.

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.

Methods of decreasing the dose per pulse implanted into a workpiece disposed in a process chamber are disclosed. According to one embodiment, the plasma is generated by a RF power supply. This RF power supply may have two different modes, a first, referred to as continuous wave mode, where the RF power supply is continuously outputting a voltage. This mode allows creation of the plasma within the process chamber. During the second mode, referred to as pulsed plasma mode, the RF power supply outputs two different power levels. The platen bias voltage may be a more negative value when the lower RF power level is being applied. This pulsed (or multi-setpoint) plasma also assists in reducing dopant deposition on the wafer during the time when CW plasma is on but the bias voltage pulse is in the off-state. In a further embodiment, a delay is introduced between the transition to the pulsed plasma mode and the initiation of the implanting process. In yet another embodiment the plasma is generated at a location in the chamber more judicious to reducing the dose impinging on the wafer, thereby increasing the process time to allow adequate control of the process.

A magnetic media disk is fabricated by depositing magnetic layers over the disk, then depositing protective later over the magnetic layer, and then performing ion implant process to implant ions into the protective coating. A system for performing the ion implant of the magnetic media disk includes two ion implant chambers. During operation one chamber performs ion implant and one chamber performs chamber cleaning by maintaining inside a plasma of cleaning gas without a disk present inside the chamber.

An ion implantation system having a grid assembly. The system includes a plasma source configured to provide plasma in a plasma region; a first grid plate having a plurality of apertures configured to allow ions from the plasma region to pass therethrough, wherein the first grid plate is configured to be biased by a power supply; a second grid plate having a plurality of apertures configured to allow the ions to pass therethrough subsequent to the ions passing through the first grid plate, wherein the second grid plate is configured to be biased by a power supply; and a substrate holder configured to support a substrate in a position where the substrate is implanted with the ions subsequent to the ions passing through the second grid plate.

Embodiments of the present disclosure generally relate to techniques for deposition of high-density films for patterning applications. In one embodiment, a method of processing a substrate is provided. The method includes depositing a carbon hardmask over a film stack formed on a substrate, wherein the substrate is positioned on an electrostatic chuck disposed in a process chamber, implanting ions into the carbon hardmask, wherein depositing the carbon hardmask and implanting ions into the carbon hardmask are performed in the same process chamber, and repeating depositing the carbon hardmask and implanting ions into the carbon hardmask in a cyclic fashion until a pre-determined thickness of the carbon hardmask is reached.

An insulator for an ion implantation source may provide electrical insulation between high voltage components and relatively lower voltage components of the ion implantation source. To reduce the likelihood of and/or prevent a leakage path forming along the insulator, the insulator may include an internal cavity having a back and forth pattern. The back and forth pattern of the internal cavity increases the mean free path of gas molecules in the ion implantation source and increases the surface area of the insulator that is not directly or outwardly exposed to the gas molecules. This results in a continuous film or coating being more difficult and/or less likely to form along the insulator, which extends the working time of the ion implantation source.

Provided is a gas barrier laminate that can be produced inexpensively as compared with the case of using an inorganic film without requiring a complex production process, and exhibits an excellent gas barrier capability and excellent flexibility, and also provided are a method for producing the gas barrier laminate, an electronic device member that includes the gas barrier laminate, and an electronic device that includes the electronic device member. A gas barrier laminate including a base and a gas barrier layer, the gas barrier layer being provided on the base, the gas barrier layer being obtained by implanting ions into an organosilicon compound thin film formed by a CVD method that utilizes an organosilicon compound as a deposition raw material, a method for producing the gas barrier laminate, an electronic device member that includes the gas barrier laminate, and an electronic device that includes the electronic device member are provided.