A plasma processing chamber optical temperature sensor is disclosed. The plasma processing chamber optical temperature sensor includes a light source, a light detector, and a means for transmitting light through a wall of a plasma processing chamber. An optical temperature sensing element is thermally coupled to a plasma processing chamber component within the plasma processing chamber. The optical temperature sensing element includes a monolithic crystalline phosphor element configured to be excited by light from the light source and to emit light back to the light detector indicative of a temperature of the monolithic crystalline phosphor element.

A substrate processing technology including: transferring a substrate to a process chamber and mounting the substrate on a substrate holder; heating the substrate with a heating device to perform predetermined substrate processing; determining the number of times of the predetermined substrate processing that has been performed that the predetermined substrate processing has been performed a preset number of times or more, determining whether it is necessary to adjust a mounting position at which the substrate is mounted on the substrate holder; and when it is determined that a mounting position adjustment is necessary, determining the mounting position by comparing the substrate temperature measured at the performing the predetermined substrate processing with a premeasured temperature of the substrate which corresponds to the mounting position and is stored in a memory.

A substrate processing apparatus includes a base with a process-side surface and a substrate support arranged on the process-side surface and designed to carry a substrate at its periphery. The periphery, more specifically the plane defined by the periphery, is spaced apart from the process-side surface. The substrate processing apparatus also includes a radiation sensor adapted to measure electromagnetic radiation arranged on a side of a back-side surface of the base. A radiation channel is arranged between the radiation sensor and the periphery of the substrate support, more specifically between the radiation sensor and the plane defined by the periphery, wherein the radiation channel is at least partially permeable to electromagnetic radiation.

An apparatus may provide a component, such as a showerhead, a pipe, a valve manifold, or a vessel, having a printed heater affixed to an outer surface of the component. In addition, a printed temperature sensor may be affixed to the outer surface of the component. The apparatus may further provide a controller to control the power to the printed heater according to data output from the printed temperature sensor.

A substrate processing apparatus includes a rotation driving device configured to rotate a rotary table holding a substrate; a processing liquid nozzle configured to supply a processing liquid onto a top surface of the substrate; an electric heater provided at a top plate and configured to heat the substrate through the top plate; an electronic component configured to perform a power feed to the electric heater and transmission/reception of a control signal for the electric heater; and a periphery cover body connected to a peripheral portion of the top plate to be rotated along with the top plate. An accommodation space in which the electronic component is accommodated is formed under the top plate. The accommodation space is surrounded by a surrounding structure including the top plate and the periphery cover body. A gap between the peripheral portion of the top plate and the periphery cover body is sealed.

A substrate processing apparatus includes a nozzle unit including a nozzle tip discharging liquid to a substrate; and a liquid supply line supplying the liquid to the nozzle unit, wherein the liquid supply line includes a liquid supply pipe connected to the nozzle tip; a supply valve installed in the liquid supply pipe; and a heater disposed between the nozzle tip and the supply valve in the liquid supply pipe.

The inventive concepts provide a temperature controller for performing a comparative measurement process and a sensing calibration process without separating a temperature sensor and an input channel, if a comparative measurement process and a sensing calibration process of a temperature sensor for controlling a temperature of a semiconductor manufacturing facility are performed.

A semiconductor wafer is preheated with a halogen lamp, and then is heated by irradiation with a flash of light emitted from a flash lamp. The preheating with the halogen lamp is continued for a short time even after the flash lamp turns off. A radiation thermometer measures a front surface temperature and a back surface temperature of the semiconductor wafer. A temperature integrated value is calculated by integration of temperatures of the semiconductor wafer measured during a period from a start of the flash irradiation to an end of the heating of the semiconductor wafer. It is determined that the semiconductor wafer is cracked at the time of flash irradiation when the calculated temperature integrated value deviates from a preset range between an upper limit value and a lower limit value.

A method for controlling a temperature of a substrate support assembly is provided. A first direct current (DC) power is supplied to a heating element embedded in a zone of the substrate support assembly included in a processing chamber. A voltage is measured across the heating element. Similarly, a current is measured through the heating element. A temperature of the zone of the substrate support assembly is determined based on the voltage across the heating element and the current through the heating element. A temperature difference between the determined temperature of the zone and a target temperature for the zone is determined. A second DC power to deliver to the heating element is determined to achieve the target temperature based at least in part on the temperature difference. The second DC power is supplied to the heating element to cause the temperature of the zone to be modified to the target temperature.

An apparatus includes an electrostatic chuck and located within a vacuum enclosure. A plurality of conductive plates can be embedded in the electrostatic chuck, and a plurality of plate bias circuits can be configured to independently electrically bias a respective one of the plurality of conductive plates. Alternatively or additionally, a plurality of spot lamp zones including a respective set of spot lamps can be provided between a bottom portion of the vacuum enclosure and a backside surface of the electrostatic chuck. The plurality of conductive plates and/or the plurality of spot lamp zones can be employed to locally modify chucking force and to provide local temperature control.