A vapor reduction device for a semiconductor wafer has a plurality of heat plates which are spaced arranged longitudinally for receiving a plurality of wafers, the heat plates are integrated into a heating frame which is further placed into a casing. The movements of the heat plates within the casing causes that the wafers can be heated rapidly and uniformly so as to evaporated vapor effectively. The heat plates are separable from the heating frame and thus a number of the heat plates is selectable as desired. The heating temperature for the heat plates is controllable independently so that the temperatures of the wafers are controllable so that the temperature differences of the wafers are controllable to be uniformly distributed.

In one embodiment, a semiconductor manufacturing apparatus includes a container to contain wafers, and supporting tables provided in the container so as to be stacked on one another, and each including a supporting face that comes into contact with a wafer to support the wafer. The apparatus further includes supporting columns to join the supporting tables together and provided at positions where the supporting columns are contained inside outer circumferences of the supporting tables. The apparatus further includes a gas feeder to feed a gas to the wafers on the supporting tables, and a gas discharger to discharge the gas fed to the wafers on the supporting tables. Each of the supporting tables includes a first upper face as the supporting face, and a second upper face provided so as to surround the first upper face at a level higher than a level of the first upper face.

Provided is a substrate processing apparatus, and more particularly, a batch-type substrate processing apparatus where processes can be performed independently on a plurality of substrates. The substrate processing apparatus includes a substrate boat including a plurality of partition plates and a plurality of connection rods, an internal reaction tube, a gas supply unit, and an exhaust unit, and a plurality of substrates are loaded to be separated from the partition plates.

A wafer boat handling device, configured to be positioned under a process chamber of a vertical batch furnace. The wafer boat handling device comprises a main housing having a wall defining and bounding a wafer boat handling space, and a boat transporter comprising a wafer boat support for supporting a wafer boat and configured to transport the wafer boat to a cooldown position within the wafer boat handling space. A part of the wall adjacent the cooldown position is a wall part with a heat radiation surface absorptance of at least 0.60 so as to withdraw heat from the wafer boat which is in the cooldown position by means of heat radiation absorption.

An embodiment relates to a loading cassette and a target substrate loading method to which same is applied. The loading cassette according to the embodiment comprises: an upper plate; a lower plate facing the upper plate while having a space therebetween; an edge support part for connecting the upper plate to the lower plate and supporting the left and right edges of a target substrate; and a rear surface support part for connecting the upper plate to the lower plate and supporting the center and the rear surface-edge of the target substrate.

Devices and methods for transferring solar cells while maintaining a controlled environment are provided. Such devices include a solar cell carrying cassette adapted to support a stack of solar cells within a solar cell carrying pod that maintains a sealed micro-environment of inert gas and allows for automated transfer of solar cells between the pod and a fabrication line. The solar cell carrying cassette includes a pair of end plates and a plurality of rods extending therebetween that are configured to support a stack of solar cells. An identifier, such as an RFID chip, is included in each of the pair of end plates so as to allow for ready identification of the cassette from a single location relative the pod, while the cassette is coupled within the pod, regardless of the orientation of the cassette within the pod.

The present invention describe a substrate handling system that exerts no or controllable external forces to hold substrates, does not contact front or back of the substrates, has minimum contact with side edge area of the substrate, can hold one or two substrate to each position, can be positioned in any orientation, and can be easily handled by human or robots. In the case that no deposition materials is desirable on the edge or sides of substrate, a self-aligned mask that can be attached to the substrate carrier is presented.

There is provided a substrate processing apparatus including a process chamber in which a substrate is accommodated, a processing gas supply system configured to introduce a processing gas containing hydrogen peroxide into the process chamber and an exhaust system configured to exhaust an interior of the process chamber, wherein at least one selected from the group of the process chamber, the processing gas supply system, and the exhaust system includes a metal member, the metal member exposed to the processing gas or a liquid generated by liquefying the processing gas is made of a material containing an iron element, and a surface of a plane of the metal members, which is exposed to the processing gas or the liquid, is formed of a layer containing iron oxide which is formed by performing a baking process on the metal member.

There is provided an apparatus including a substrate holder to hold substrates including a product substrate and a dummy substrate, a transfer mechanism that loads the substrates into the substrate holder, a storage part to store a device parameter including at least the number of substrates that can be loaded on the substrate holder and the number of product substrates to be loaded on the substrate holder, and a controller to: (1) create substrate transfer data, which includes information indicating an order for transferring the substrates, transfer source information, and transfer destination information, according to the device parameter, (2) read the created substrate transfer data, (3) by transferring the substrates to the transfer mechanism based on the read substrate transfer data, transfer the dummy substrate to a substrate holding region except for a heat equalization region, and transfer the product substrate to the heat equalization region on the substrate holder.

A method for producing a crystal substrate includes preparing, measuring, holding, and machining. The preparing prepares a crystal substrate body including a curved crystal lattice plane. The measuring measures a shape feature of the crystal lattice plane. The holding holds the crystal substrate body in a warped state in accordance with the shape feature measured by the measuring, to more flatten the crystal lattice plane than the crystal lattice plane at the preparing. The machining machines a surface of the crystal substrate body held in the warped state, to flatten the surface.