A high-pressure processing system for processing a layer on a substrate includes a first chamber, a support to hold the substrate in the first chamber, a second chamber adjacent the first chamber, a foreline to remove gas from the second chamber, a vacuum processing system configured to lower a pressure within the second chamber to near vacuum, a valve assembly between the first chamber and the second chamber to isolate the pressure within the first chamber from the pressure within the second chamber, a gas delivery system configured to increase the pressure within the first chamber to at least 10 atmospheres while the first chamber is isolated from the second chamber, an exhaust system comprising an exhaust line to remove gas from the first chamber, and a common housing surrounding both the first gas delivery module and the second gas delivery module.

A cleaning method is provided. In the cleaning method, residues of elements of a group for a common semiconductor material in a chamber are removed with plasma of a halogen-containing gas. Residues of metal elements of groups 12 and 13 and groups 14 and 15 in the chamber are removed with plasma of a hydrocarbon-containing gas. A C-containing material in the chamber is removed with plasma of an O-containing gas. Further, the removing with the plasma of the halogen-containing gas, the removing with the plasma of the hydrocarbon-containing gas, and the removing with the plasma of the O-containing gas are performed in that order or the removing with the plasma of the hydrocarbon-containing gas, the removing with the plasma of the O-containing gas, and the removing with the plasma of the halogen-containing gas are performed in that order X times where X≥1.

In a method of controlling a plasma beam of a plasma etcher a flow rate controller of the plasma etcher is set to generate one or more flow rates of an etching gas corresponding to one or more plasma beams of the plasma etcher. The emitted light generated by plasma discharge corresponding to the one or more plasma beams of the plasma etcher is monitored. The flow rate controller is calibrated based on the one or more flow rates and a corresponding emitted light of the plasma discharge.

A plasma processing apparatus includes a plasma processing chamber, a source power coupling element configured to generate plasma in an interior of the plasma processing chamber by coupling source power to the plasma processing chamber, a DC pulse generator configured to generate a DC pulse train at a DC pulse frequency, a substrate holder disposed in the interior of the plasma processing chamber, a DC coupling element coupled to the DC pulse generator, a DC current path including the DC coupling element, the plasma, and a reference potential node in a series configuration, the DC coupling element being configured to bias the substrate holder relative to the reference potential node using the DC pulse train, and a capacitive pre-coat layer disposed between the DC coupling element and the plasma. The capacitive pre-coat layer increases the RC time constant of the DC current path according to the DC pulse frequency.

In a plasma processing method, a substrate is loaded onto a lower electrode within a chamber. A plasma power is applied to form plasma within the chamber. A voltage function of a nonsinusoidal wave having a DC pulse portion and a ramp portion is generated. Generating the voltage function may include setting a slope of the ramp portion and setting a duration ratio of the ramp portion to a cycle of the voltage function in order to control an ion energy distribution generated at a surface of the substrate. A bias power of the nonsinusoidal wave is applied to the lower electrode.

A substrate fixing device includes a base plate including therein a gas supply section, and an electrostatic chuck provided on the base plate. The electrostatic chuck includes a base having a mounting surface on which a target to be held by electrostatic attraction is mounted, an insertion hole, penetrating the base, having an inner surface that defines the insertion hole and is threaded to form a female thread, and a screw member, having an outer surface that is threaded to form a male thread, and inserted into the insertion hole to assume a mated state in which the male thread mates with the female thread. A gas from the gas supply section is supplied to the mounting surface via the screw member.

A measuring device is provided. The measuring device includes a base substrate, sensor electrodes, a temperature sensor, a high frequency oscillator, C/V conversion circuits for generating voltage signals corresponding to electrostatic capacitances of the sensor electrodes, an A/D converter for converting the voltage signals to digital values, a calculation unit for calculating measurement values indicating the electrostatic capacitances based on the digital values, and phase control circuits connected between the sensor electrodes and the high-frequency oscillator. Each of the conversion circuits includes an operational amplifier, and the high-frequency oscillator is connected to a non-inverting input terminal of the amplifier and is connected to an inverting input terminal thereof through a corresponding phase control circuit. The calculation unit stores parameters for setting admittances of the phase control circuits in association with temperatures and adjusts the admittances of the phase control circuits using a parameter associated with a detected temperature.

In one embodiment, a method of matching an impedance is disclosed. An impedance matching network is coupled between a radio frequency (RF) source and a plasma chamber. The matching network includes a variable reactance element (VRE) having different positions for providing different reactances. The RF source has an RF source control circuit carrying out a power control scheme to control a power delivered to the matching network. Based on a determined parameter, a new position for the VRE is determined to reduce a reflected power at the RF input of the matching network. The matching network provides a notice signal to the RF source indicating the VRE will be altered. In response to the notice signal, the RF source control circuit alters the power control scheme. While the power control scheme is altered, the VRE is altered to the new position.

The present disclosure relates to a ceramic component including a boron carbide, wherein a difference of a first residual stress measured at a first spot on a surface of the ceramic component and a second residual stress measured at a second spot on the surface having different distance from a center of the surface than the first spot is −600 to +600 MPa.

A wafer fabricating system includes a wafer chuck, a gas inlet port, a fluid inlet port, first and second arc-shaped channels, a gas source, and a fluid containing source. The wafer chuck has a top surface, and orifices are formed on the top surface. The gas inlet port is formed in the wafer chuck and located underneath a fan-shaped sector of the top surface, wherein the gas inlet port is fluidly communicated with the orifices. The fluid inlet port is formed in the wafer chuck. The first and second arc-shaped channels are fluidly communicated with the fluid inlet port and located underneath the fan-shaped sector of the top surface and located at opposite sides of the gas inlet port from a top view. The gas source fluidly is connected to the gas inlet port. The fluid containing source fluidly is connected to the fluid inlet port.