A semiconductor wafer to be treated is heated at a first preheating temperature ranging from 100 to 200° C. while a pressure in a chamber housing the semiconductor wafer is reduced to a pressure lower than an atmospheric pressure. After the semiconductor wafer is preheated to increase the temperature into a second preheating temperature ranging from 500 to 700° C. while the pressure in the chamber is restored to a pressure higher than the reduced pressure, a flash lamp emits a flashlight to a surface of the semiconductor wafer. Heating the semiconductor wafer at the first preheating temperature that is a relatively low temperature enables, for example, the moisture absorbed on the surface of the semiconductor wafer in trace amounts to be desorbed from the surface, and also enables the flash heating treatment to be performed with oxygen derived from such absorption removed as much as possible.

A substrate treating method, liquid and apparatus are provided which can reduce the amount of sublimable substance used for the drying of a substrate while reducing the collapse of pattern. The substrate treating method includes a step of supplying a liquid to the pattern-formed surface of the substrate, a step of solidifying the liquid on the pattern-formed surface to form a solidified body and a step of subliming the solidified body so as to remove it from the pattern-formed surface. The substrate treating liquid includes a molten sublimable substance and a solvent, the freezing point of the sublimable substance being higher than the freezing point of the solvent. When the sublimable substance and the solvent are separated, the sublimable substance is settled and in the solidification step, the settled sublimable substance is solidified to have a height equal to or higher than the height of a pattern.

Disposing a DUT between a cold plate and an active thermal interposer device of the thermal management head. The DUT includes a plurality of modules and the active thermal interposer device includes a plurality of zones, each zone of the plurality of zones corresponding to a respective module of the plurality of modules and operable to be selectively heated. Receiving a respective set of inputs corresponding to each zone of the plurality of zones. Performing thermal management of the plurality of modules of the DUT by separately controlling temperature of each zone of the plurality of zones by controlling a supply of coolant to a cold plate, and individually controlling heating of each zone of the plurality of zones.

A technique for connecting a nozzle to a reaction tube while preventing the nozzle from collapsing includes a substrate processing apparatus including: a gas introduction structure comprising a non-metallic material penetrating a side wall of a process vessel and integrated with the side wall as a single structure, wherein a front end thereof protrudes into the process vessel; a nozzle made of a non-metallic material and including: a first straight portion inserted into the gas introduction structure and fluidically communicating with the gas introduction structure; and a second straight portion fluidically communicating with the first straight portion and extending along an inner wall of the process vessel; and a fixing block provided at an inner side of the process vessel and above the gas introduction structure, wherein the fixing block has a groove where the nozzle can be moved in a radial direction of the process vessel.

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.

There is provided a technique that includes: an exhauster including a casing in which a rotating body is installed; a gas supplier configured to supply an inert gas to the exhauster without passing through a process chamber; and a controller configured to be capable of controlling the gas supplier to supply the inert gas into the casing based on a temperature drop of the rotating body expected in advance in a state where a processing object is not being processed in the process chamber such that a temperature of the rotating body becomes equal to or higher than a target temperature.

Aspects generally relate to substrate support apparatus and systems having elevated surfaces for heat transfer between the elevated surfaces and a substrate, and the methods of using the same. In one aspect, the elevated surfaces are disposed between a recessed surface and a plurality of support surfaces of a plurality of support protrusions that extend from the recessed surface. In one aspect, the elevated surfaces are disposed between a base surface and a plurality of support surfaces of a plurality of support protrusions that extend from the base surface. During a substrate processing operation, heat is transferred to the substrate through a plurality of cavities disposed between the elevated surfaces and a backside surface of the substrate.

A process condition sensing apparatus is disclosed. The apparatus includes a substrate and an electronic enclosure including one or more electronic components. The apparatus includes a floating connection assembly configured to mechanically couple the electronic enclosure to the substrate, the floating connection assembly includes a leg and a foot. The leg or foot are arranged to mitigate thermal stress between one or more interfaces. The one or more interfaces include a leg-enclosure interface or a foot-substrate interface.

A window assembly for a thermal processing chamber applicable for thermal processing of a semiconductor substrate is provided. The window assembly includes an upper window, a lower window, and a plurality of linear reflectors disposed between the upper window and the lower window. The plurality of linear reflectors extend lengthwise parallel to each other and parallel to a plane of the window assembly. The window assembly includes a pressure control region defined between the upper window, the lower window, and side surfaces of each linear reflector.

A bonding device measures a position deviation amount of the chip with respect to the substrate in a state where the chip and the substrate are in contact, and corrects and moves the chip relatively to the substrate in such a way as to reduce the position deviation amount, based on the measured position deviation amount. Then, the bonding device fixes the chip to the substrate by irradiating a resin portion of the chip with an ultraviolet ray and curing the resin portion when the position deviation amount of the chip with respect to the substrate is equal to or less than a position deviation amount threshold value.