An upper radiation thermometer is provided obliquely above a semiconductor wafer to be measured. The upper radiation thermometer includes a photovoltaic detector that produces an electromotive force when receiving light. The photovoltaic detector has both high-speed responsivity and good noise properties in a low-frequency range. The upper radiation thermometer does not require a mechanism for cooling because the photovoltaic detector is capable of obtaining sufficient sensitivity at room temperature without being cooled. There is no need to provide a light chopper and a differentiating circuit in the upper radiation thermometer. This allows the upper radiation thermometer to measure the front surface temperature of the semiconductor wafer with a simple configuration both during preheating by means of halogen lamps and during flash irradiation.

There is provided a configuration that includes at least one port that is provided in a process container in which a substrate is accommodated and heat-treated, the port providing an optical path that penetrates an interior of the process container and an exterior of the process container; an optical window that is mounted to the port and transmits light while maintaining the port airtight; a purge gas supplier that is disposed inside the process container and provides a purge gas to an inner surface of the optical window; and a partition that guides the purge gas from the purge gas supplier to the optical window.

An electrostatic chuck assembly includes a puck and a cooling plate. The puck includes an electrically insulative upper puck plate comprising one or more heating elements and one or more electrodes to electrostatically secure a substrate and further includes a lower puck plate bonded to the upper puck plate by a metal bond, the lower puck plate comprising a plurality of features distributed over a bottom side of the lower puck plate at a plurality of different distances from a center of the lower puck plate, wherein each of the plurality of features accommodates one of a plurality of fasteners. The cooling plate is coupled to the puck by the plurality of fasteners, wherein the plurality of fasteners each apply an approximately equal fastening force to couple the cooling plate to the puck.

A substrate process station includes a housing including a transport region and process region. The process station further includes a magnetic levitation assembly disposed in the transport region configured to levitate and propel a substrate carrier. The magnetic levitation assembly includes a first track segment including first rails disposed in the transport region and below the process region, wherein the first rails each include a first plurality of magnets. The process station further includes a pedestal assembly comprising a pedestal disposed within the housing. The pedestal is moveable between a pedestal transfer position and a process position, wherein the pedestal is disposed between the first rails in the pedestal transfer position to receive a substrate from the substrate carrier, and wherein the pedestal is moveable between the first rails to position the received substrate in the process region in the process position.

A substrate fixing device includes a base plate having a first surface in which a plurality of first bottomed holes are formed, an electrostatic chuck mounted on the first surface of the base plate and having a second surface facing the first surface, the second surface being formed therein with a plurality of second bottomed holes each connected to each of the first bottomed holes, and a plurality of fixing members each fit into one first bottomed hole and one second bottomed hole.

In a substrate holder, a gas supply part sends out a gas to the space between the lower surface of a substrate and a base surface of a base part to form a radially outward airflow. A division plate is arranged radially outward of the outer peripheral edge of the substrate on the base surface of the base part to surround the substrate. The inner peripheral edge of the division plate and the outer peripheral edge of the substrate face each other in the radial direction with a space in between. The upper surface of the division plate is located below or at the same position in the up-down direction as the upper surface of the substrate. An annular passage is provided between the lower surface of the division plate and the base surface of the base part.

An electrostatic chuck device comprising: a plate-shaped electrostatic chuck part which has an electrostatic adsorption electrode provided therein and has a mounting surface on which a plate-shaped sample is mounted; and a base part which supports the electrostatic chuck part on a support surface thereof from an opposite side of the mounting surface, wherein the base part has a disk shape which has a central axis at a center thereof, and a coolant channel extending along the support surface is provided inside the base part, wherein the coolant channel includes an outer peripheral channel which overlaps an outer edge of the plate-shaped sample when viewed from an axial direction of the central axis, and an inner peripheral channel which is disposed on an inner side in a radical direction than the outer peripheral channel, wherein at least a portion of the inner peripheral channel extends spirally around the central axis, and a channel cross-sectional area of the inner peripheral channel decreases as a distance from the central axis increases.

A substrate process station includes a housing including a transport region and process region. The process station further includes a magnetic levitation assembly disposed in the transport region configured to levitate and propel a substrate carrier. The magnetic levitation assembly includes a first track segment including first rails disposed in the transport region and below the process region, wherein the first rails each include a first plurality of magnets. The process station further includes a pedestal assembly comprising a pedestal disposed within the housing. The pedestal is moveable between a pedestal transfer position and a process position, wherein the pedestal is disposed between the first rails in the pedestal transfer position to receive a substrate from the substrate carrier, and wherein the pedestal is moveable between the first rails to position the received substrate in the process region in the process position.

A susceptor in a vapor phase growth apparatus and configured to allow a wafer to be mounted thereon. The susceptor has a support surface configured to support a downward facing surface of the wafer from below. The support surface has a susceptor engagement portion configured to be engaged with a wafer engagement portion of the wafer.

A circuit tuning radio frequency (RF) power. The circuit includes a low to mid frequency (LF/HF) tuning circuit including a variable LF/MF capacitor coupled in series with an LF/MF inductor. The LF/MF tuning circuit is coupled between ground and a common node configured to receive an RF input. The circuit includes a high frequency (HF) tuning circuit coupled in parallel to the LF/MF tuning circuit between ground and the common node. The HF tuning circuit includes a variable HF capacitor coupled in series with an HF inductor. Cross parallel isolation occurs between the LF/MF inductor of the LF/MF tuning circuit and the HF inductor of the HF tuning circuit when adjusting the variable LF/MF capacitor or variable HF capacitor.