A rapid thermal processing method and a rapid thermal processing device are provided. The rapid thermal processing method includes the following operations. A wafer is provided. A first heating operation is performed on the wafer to heat the wafer to a first temperature. The wafer is controlled to start rotating. The first temperature is maintained for a first predetermined time. A second heating operation is performed on the wafer to heat the wafer from the first temperature to a second temperature, and the second temperature is maintained for a second predetermined time. A third heating operation is performed on the wafer to heat the wafer from the second temperature to a third temperature, and the third temperature is maintained for a third predetermined time.

Examples disclosed herein relate to a to a pitch gradient in a lamp filament, and a method of making. In one implementation, a lamp has a bulb filled with a gas. A filament is disposed within the bulb. The filament has a plurality of coils that include a first coil having a first point. The plurality of coils includes a second coil having a second point, and a third coil having a third point. The pitch gradient is defined by a first pitch between the second point and the first point, and a second pitch between the third point and the second point. The second pitch is greater than the first pitch. The second point is 360 degrees away from the first point. The third point is 360 degrees from the second point. A terminal coil is electrically coupled to at least the first coil, the second coil, and the third coil.

The present disclosure discloses a heating apparatus for a semiconductor device. The heating apparatus includes a carrier including a first abutting part, a heat collecting plate at least including a working surface, and a heat radiation source disposed on a side of the heat collecting plate opposite to the working surface and separated from the heat collecting plate by a predetermined distance. The heat collecting plate is disposed on the carrier, and the first abutting part abuts against an edge of the heat collecting plate on the side opposite to the working surface. The heat radiation source is and configured to emit heat radiation during working and to heat the heat collecting plate in a non-contact manner. The heat collecting plate receives the heat radiation and the emitted heat and heats a heated object disposed on the working surface in a contact manner.

A method and apparatus for improving film growth uniformity on a semiconductor substrate. The film growth uniformity is improved by adjusting the amount of power provided to the substrate by spot heaters as the substrate is rotated. Therefore, the amount of power provided to the substrate by the spot heaters changes as the portion of the substrate being heated by spot heater changes. The change in power provided by the spot heater is dependent on a temperature correction factor applied by the controller.

An apparatus 1 for processing a plurality of substrates 3 is provided. The apparatus may have a process tube 5 creating a process chamber 7; a heater 9 surrounding the process tube 5; a flange 11 for supporting the process tube; and a door 15 configured to support a wafer boat 17 with a plurality of substrates 3 in the process chamber and to seal the process chamber 7. An exhaust operably connected to the process chamber 7 may be provided to remove gas from the process chamber via a first exhaust duct 19. The apparatus may be provided with an extractor chamber 21 surrounding the first exhaust duct where it connects to the process chamber and connected to a second exhaust duct 23 to remove gas from the extractor chamber.

A substrate processing apparatus includes a bake chamber, a chamber door that opens and closes an opening of the bake chamber, a first support plate in the bake chamber, a first partition wall, which partitions a space provided on the first support plate into first heat treatment spaces spaced apart from each other in a first horizontal direction, and extends in a second horizontal direction and a vertical direction, first heat treatment modules arranged in the first heat treatment spaces, a first exhaust duct extending in the first horizontal direction across the first heat treatment spaces, a first sealing bracket coupled to the first exhaust duct, a first horizontal packing configured to seal a gap between the first sealing bracket and the chamber door, and a first vertical packing configured to seal a gap between the first partition wall and the chamber door.

Methods and apparatus to control zone temperatures in a solar cell production system are disclosed. An example furnace to fire photovoltaic cells includes: a plurality of zones comprising firing elements configured to fire a metallization layer of photovoltaic cells by heating the photovoltaic cells in the zones; one or more belts configured to transport photovoltaic cells through a sequence of the plurality of zones; a user interface comprising one or more input devices; and control circuitry configured to: control the firing elements for the plurality of zones; and modify a configuration of two or more of the plurality of zones based on input received via the input device.

Methods and apparatus to control zone temperatures in a solar cell production system are disclosed. An example furnace to fire photovoltaic cells includes: a plurality of zones comprising firing elements configured to fire a metallization layer of photovoltaic cells by heating the photovoltaic cells in the zones; one or more belts configured to transport photovoltaic cells through a sequence of the plurality of zones; a user interface comprising one or more input devices; and control circuitry configured to: control the firing elements for the plurality of zones; and modify a configuration of two or more of the plurality of zones based on input received via the input device.

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.

A flameless combustion oven arranges gas and air jets to directly impinge on the product being heated to substantially promote transfer of heat to the product by impingement transfer rather than by conventional radiation and thermally induced convection. In one embodiment, a set of spaced air and gas nozzles are uniformly distributed on a wall of the oven opposite the product to provide substantially uniform impingement over a surface of the product.