Provided is a charged particle beam apparatus including a focused ion beam column, a sample holder, a stage supporting the sample holder, a securing member rotating unit, a stage driving unit, and a control device. The sample holder includes a securing member fixing a sample. The securing member rotating unit rotates the securing member around a first rotational axis and a second rotational axis. The stage driving unit translates the stage in three dimensions and rotates the stage around a third rotational axis. The control device acquires a correction value for correcting a change in a position of a center of rotation for rotation around at least one among a first rotational axis, a second rotational axis, and a third rotational axis. The control device translates the stage according to the correction value.

The invention relates to a device and a method for producing layers whose layer thickness distribution can be adjusted in coating systems with horizontally rotating substrate. A very homogeneous or a specific non-homogeneous distribution can be adjusted. The particle loading is also significantly reduced. The service life is significantly higher compared to other methods. Forming of parasitic coatings is reduced.

A film-forming apparatus comprises: a processing chamber defining a processing space, a first sputter-particle emitter and a second sputter-particle emitter having targets, respectively, from which sputter-particles are emitted in different oblique directions in the processing space, a sputter-particle blocking plate having a passage hole through which the sputter particles emitted from the first sputter-particle emitter and the second sputter-particle emitter pass, a substrate support configured to support a substrate and provided at a side opposite the first sputter-particle emitter and the second sputter-particle emitter with respect to the sputter-particle blocking plate in the processing space, a substrate moving mechanism configured to linearly move the substrate supported on the substrate support, and a controller configured to control the emission of sputter-particles from the first sputter-particle emitter and the second sputter-particle emitter while controlling the substrate moving mechanism to move the substrate linearly.

A substrate holding mechanism for holding a substrate placed on a stage which is rotatable with respect to a turntable, includes a substrate holding member, provided at a peripheral portion of the stage, fixed to a rotating shaft disposed below a surface on which the substrate is placed, and contactable to a side surface of the substrate placed on the stage, a biasing member having a first end fixed to the substrate holding member at a position closer to a center of the stage than the rotating shaft, and a second end fixed at a position separated from the substrate holding member toward the center of the stage and below the rotating shaft, and a pressing member configured to press upwardly a portion of the substrate holding member where the first end of the biasing member is fixed.

Described herein is a technique capable of cleaning a surrounding structure of a substrate placing surface in an apparatus. According to one aspect of the technique, there is provided a substrate processing apparatus including: a process chamber in which a substrate is processed; a substrate mounting plate provided with a substrate non-placing surface and a plurality of substrate placing surfaces; a rotator configured to rotate the substrate mounting plate; a plasma generator configured to generate plasma such that a plasma density over the substrate non-placing surface is higher than a plasma density over the plurality of the substrate placing surfaces; a process gas supplier configured to supply a process gas into the process chamber; a cleaning gas supplier configured to supply a cleaning gas into the process chamber; and a heater placed below the substrate mounting plate.

A substrate processing apparatus includes: a disk including a plurality of electrostatic chucks periodically disposed at a constant radius from a central axis; a disk support supporting the disk; a DC line electrically connected to the plurality of electrostatic chucks through the disk support; and a power supply configured to supply power to the DC line. The DC line includes: a first DC line penetrating through the disk support from the power supply; a power distribution unit configured to distribute the first DC line to connect the first DC line to each of the plurality of electrostatic chucks; and a plurality of second DC lines respectively connected to the plurality of electrostatic chucks in the power distribution unit.

In one embodiment, an electron beam inspection apparatus includes an optical system irradiating a substrate with primary electron beams, a beam separator separating, from the primary electron beams, secondary electron beams emitted as a result of irradiating the substrate with the primary electron beams, a detector detecting the secondary electron beams separated, a movable stage on which the substrate is placed, a support base supporting the substrate on the stage, and an applying unit applying a first voltage to the substrate. The support base includes a plurality of support pins that support the substrate from below. The support pins each include a columnar insulator and a metal film disposed in the insulator. A second voltage is applied to the metal film.

A plasma processing apparatus for performing plasma processing on a substrate includes: a plasma generator configured to generate plasma in a processing container; a support structure configured to mount the substrate on a tilted mounting surface in the processing container and rotatably support the substrate; a first slit plate made of quartz and provided between the plasma generator and the support structure, the first slit plate having first slits formed in the first slit plate; and a second slit plate made of quartz and provided between the plasma generator and the support structure and below the first slit plate, the second slit plate having second slits formed in the second slit plate, wherein the first slits are staggered from adjacent ones of the second slits in a reverse direction of a tilting direction of the mounting surface.

Exemplary methods of semiconductor processing may include providing a silicon-containing precursor and a carbon-containing precursor to a processing region of a semiconductor processing chamber. The carbon-containing precursor may be characterized by a carbon-carbon double bond or a carbon-carbon triple bond. A substrate may be disposed within the processing region of the semiconductor processing chamber. The methods may include providing a boron-containing precursor to the processing region of the semiconductor processing chamber. The methods may include thermally reacting the silicon-containing precursor, the carbon-containing precursor, and the boron-containing precursor at a temperature above about 250° C. The methods may include forming a silicon-and-carbon-containing layer on the substrate.

Disclosed herein is a module for supporting a device configured to manipulate charged particle paths in a charged particle apparatus, the module comprising: a support arrangement configured to support the device, wherein the device is configured to manipulate a charged particle path within the charged particle apparatus; and a support positioning system configured to move the support arrangement within the module; wherein the module is arranged to be field replaceable in the charged particle apparatus.