A method of controlling temperature of a heater including a resistive heating element includes measuring a voltage count and a current count based on data from an analog-digital converter (ADC) circuit of a sensor circuit, where the sensor circuit is electrically coupled to the heater. The method includes selecting one or more dynamic gain levels of the ADC from among a plurality of dynamic gain levels based on a shift gain correlation, determining a resistance of the resistive heating element based on the voltage count, the current count, and the one or more dynamic gain levels, and controlling power to the heater based on the resistance.

Implementations described herein provide a method for processing a substrate on a substrate support assembly which enables both lateral and azimuthal tuning of the heat transfer between an electrostatic chuck and a substrate. The method includes processing a first substrate using a first temperature profile on a substrate support assembly having primary heaters and spatially tunable heaters. A deviation profile is determined from a result of processing the first substrate. The spatially tunable heaters are controlled in response to the deviation profile to enable discrete lateral and azimuthal tuning of local hot or cold spots on the substrate support assembly in forming a second temperature profile. A second substrate is then processed using the second temperature profile.

Embodiments described herein relate to gas line systems with a multichannel splitter spool. In these embodiments, the gas line systems will include a first gas line that is configured to supply a first gas. The first gas line is coupled to a multichannel splitter spool with a plurality of second gas lines into which the first gas flows. Each gas line of the plurality of second gas lines will have a smaller volume than the volume of the first gas line. The smaller second gas lines will be wrapped by a heater jacket. Due to the smaller volume of the second gas lines, when the first gas is flowed through the second gas lines, the heater jacket will sufficiently heat the first gas, eliminating the condensation induced particle defects that occur in conventional gas line systems when the first gas meets with a second gas in the gas line system.

An apparatus for transferring a substrate to a substrate processing chamber is provided. The apparatus comprises: a substrate transfer chamber having a floor provided with a first magnet and a sidewall connected to the substrate processing chamber and having an opening through which a substrate is loaded into and unloaded from the substrate processing chamber; a substrate transfer module including a substrate holder configured to hold the substrate and a second magnet having a repulsive force against the first magnet, and configured to move in the substrate transfer chamber by magnetic levitation using the repulsive force; and a heating device configured to heat the substrate transfer module to release contaminants adhered to a surface of the substrate transfer module.

A Faraday shielding apparatus includes a Faraday shielding plate and a heating circuit; the Faraday shielding plate includes a conductive ring and a plurality of conductive petal-shaped members radially symmetrically connected to the outer periphery of the conductive ring; when the heating circuit is used in the etching process, the Faraday shielding plate is heated by electricity. During the etching process, the heating circuit is conductively connected to the Faraday shielding plate, increasing the temperature of the Faraday shielding plate when it is energized, heating a medium window and reducing the amount of product deposits. During the cleaning process, the heating circuit and the Faraday shield are turned off, and the Faraday shielding plate is connected to a shielding power supply to clean the dielectric window. The output terminal of the heating power supply is filtered by way of a filter circuit unit, then connected to the Faraday shielding plate.

A Faraday shielding apparatus includes a Faraday shielding plate and a resistance wire attached to the lower end of the Faraday shielding plate; the Faraday shielding plate includes a conductive ring and a plurality of conductive petal-shaped members radially symmetrically connected to the outer periphery of the conductive ring; and an insulating and thermally conductivity layer is on the outer surface of the resistance wire. During the etching process, the heating circuit and the resistance wire are conductively connected, increasing the temperature of the resistance wire when it is energized. The Faraday shielding plate is between a radio frequency coil and the resistance wire to form a shield. The output terminal of the heating power supply is filtered by way of a filter circuit unit, then is connected to the resistance wire, preventing coupling between the radio frequency coil and the resistance wire.

Disclosed is a substrate processing system including a substrate processing apparatus; and a control device that controls the substrate processing apparatus. The substrate processing apparatus includes: a chamber; a placing table provided within the chamber; and heaters embedded in the placing table corresponding to division regions, respectively. The control device includes: a holding unit that holds a table for each of the division regions; a measuring unit that measures the resistance value of each of the heaters embedded in the placing table for each of the division regions; and a controller that estimates a temperature of each of the division regions corresponding to the resistance value of each of the heaters measured by the measuring unit with reference to the table for each of the division regions, and controls an electric power to be supplied to each of the heaters so that the estimated temperature becomes a target temperature.

Methods and systems of heating a substrate in a vacuum deposition process include a resistive heater having a resistive heating element. Radiative heat emitted from the resistive heating element has a wavelength in a mid-infrared band from 5 μm to 40 μm that corresponds to a phonon absorption band of the substrate. The substrate comprises a wide bandgap semiconducting material and has an uncoated surface and a deposition surface opposite the uncoated surface. The resistive heater and the substrate are positioned in a vacuum deposition chamber. The uncoated surface of the substrate is spaced apart from and faces the resistive heater. The uncoated surface of the substrate is directly heated by absorbing the radiative heat.

A heating device and a heating chamber are provided, comprising a base plate (21), at least three supporting columns (22) and a heating assembly, where the at least three supporting columns are arranged vertically on the base plate and are distributed at intervals along a circumferential direction of the base plate Top ends of the at least three supporting columns form a bearing surface for supporting a to-be-heated member (23). The heating assembly includes a heating light tube (24) and a thermal radiation shielding assembly, where the heating light tube is disposed above the base plate and below the bearing surface. A projection of an effective heating area formed by uniform distribution of the heating light tube on the base plate covers a projection of the bearing surface on the base plate. The thermal radiation shielding assembly shields heat radiated by the heating light tube towards surroundings and bottom.

The present disclosure generally describes a system that includes a heater, a power converter including a power switch, and a controller. The power converter is in communication with the heater and is operable to apply an adjustable voltage to the heater. The controller is in communication with the power switch to control the voltage output of the power converter based on at least one of a load current and a detected voltage at the heater. The controller operates the power switch to adjust the voltage output of the power converter.