A device to ensure planarity of a semiconductor wafer during growth at an increased temperature in a growth chamber arranged in a reactor housing where the device includes a growth chamber having a port to allow the deposition of at least one wafer on a rotating susceptor in the growth chamber and the withdrawal of the wafer. The growth chamber has an inlet channel for a supply of process gases and an outlet channel for a discharge of not consumed process gases to create a process gas flow between said channels. Separate heaters are adjacent to the growth chamber to heat the rotating wafer with individually controlled heating zones both above and under the wafer. An instrument measures the bending of the wafer, and an automatic control circuit uses data from temperature sensors or measured data of power supplied to the heaters and the instrument measuring bending of the wafer to change the temperature in said temperature zones so that bending of the wafer is minimized.

A system, method, and apparatus for heating and cooling a component in chamber enclosing a chamber volume. Vacuum and purge gas ports are in fluid communication with the chamber volume. A heater apparatus selectively heats the heated apparatus to a process temperature. A vacuum valve provides selective fluid communication between a vacuum source and the vacuum port. A purge gas valve provides selective fluid communication between a purge gas source for a purge gas and the purge gas port. A controller controls the heater apparatus, vacuum and purge gas valves and to selectively flow the purge gas to the chamber volume when an equipment-safe temperature is reached. When an operator-safe temperature is reached, access to the chamber volume through an access port by an operator is permitted.

A gas introduction structure for supplying a processing gas into a vertically-elongated processing container, includes a processing gas supply pipe extending along a longitudinal direction of the processing container in the processing container and having a plurality of gas discharge holes formed along the longitudinal direction, the processing gas supply pipe configured so that the processing gas is introduced from one end toward the other end thereof, wherein a dilution gas is supplied to a portion of the processing gas supply pipe that is closer to the other end than the one end of the processing gas supply pipe.

A wafer cleaning apparatus is provided. The wafer cleaning apparatus includes comprising a chamber configured to be loaded with a wafer, a nozzle on the wafer and configured to provide liquid chemicals on an upper surface of the wafer, a housing under the wafer, a laser module configured to irradiate laser on the wafer, a transparent window disposed between the wafer and the laser module, and a controller configured to control on/off of the laser module, wherein the controller is configured to control repetition of turning the laser module on and off, and retain temperature of the wafer within a temperature range, and a ratio of time when the laser module is on in one cycle including on/off of the laser module is 30% to 50%.

The present disclosure provides a semiconductor fabrication apparatus. The semiconductor apparatus includes a processing chamber for etching; a substrate stage integrated in the processing chamber and being configured to secure a semiconductor wafer; a reflective mirror configured inside the processing chamber to reflect thermal energy from the heating mechanism toward the semiconductor wafer; and a heating mechanism embedded in the process chamber and is operable to perform a baking process to remove a by-product generated during the etching. The heating mechanism is integrated between the reflective mirror and a gas distribution plate of the processing chamber.

A developing treatment method performs a developing treatment on a resist film on a substrate. The method includes: a pattern forming step of forming a resist pattern by supplying a developing solution to the substrate and developing the resist film on the substrate; a coating step of coating the developed substrate with an aqueous solution of a water-soluble polymer; and a rinse step of cleaning the substrate by supplying a rinse solution to the substrate coated with the aqueous solution of the water-soluble polymer.

A laser structure may include a substrate, an active region arranged on the substrate, and a waveguide arranged on the active region. The waveguide may include a first surface and a second surface that join to form a first angle relative to the active region. A material may be deposited on the first surface and the second surface of the waveguide.

A deposition method includes: forming a seed layer on a substrate; and forming a carbon film on the seed layer. The forming the seed layer includes: supplying an aminosilane-based gas to the substrate to form a Si—H bond on a surface of the substrate; and supplying a boron-containing gas to the substrate to form a B—H bond on the surface on which the Si—H bond is formed.

A method for processing a workpiece is provided. The method can include placing a workpiece on a susceptor disposed within a processing chamber. The method can include performing a multi-cycle thermal treatment process on the workpiece in the processing chamber. The multi-cycle thermal treatment process can include at least two thermal cycles. Each thermal cycle of the at least two thermal cycles can include performing a first treatment on the workpiece at a first temperature; heating a device side surface of the workpiece to a second temperature in less than one second; performing a second treatment on the workpiece at approximately the second temperature; and cooling the workpiece subsequent to performing the second treatment.

Disclosed is a chip packaging apparatus. The chip packaging apparatus comprises: at least one chip supplying device; at least one chip processing device configured to process a chip supplied by a corresponding chip supplying device; and at least one chip transferring device, wherein each chip transferring device has a plurality of bonding heads, and each of the bonding heads is used to transfer one chip processed by a corresponding chip processing device. Each chip processing device comprises at least two pick-up platforms, each of the pick-up platforms is configured such that multiple chips can be simultaneously provided thereon, and the plurality of bonding heads on a corresponding chip transferring device is configured to simultaneously pick up multiple chips from each pick-up platform in one operation. A method for packaging chips is also disclosed.