A wafer cleaning apparatus may include a cleaning tank, a support part and a cleaning unit installed to be capable of moving upward or downward into the cleaning tank, and configured to inject a cleaning solution onto an inner wall of the cleaning tank. The cleaning unit may include an injection pipe disposed adjacent to the inner wall of the cleaning tank and having a plurality of injection holes, and an injection nozzle coupled to the injection pipe and formed to be inclined such that a diameter of the injection hole decreases in a direction from the injection pipe toward the cleaning tank.

Exemplary substrate processing systems may include a plurality of processing regions. The systems may include a transfer region housing defining a transfer region fluidly coupled with the plurality of processing regions. The systems may include a plurality of substrate supports, and each substrate support of the plurality of substrate supports may be vertically translatable between the transfer region and an associated processing region of the plurality of processing regions. The systems may include a transfer apparatus including a rotatable shaft extending through the transfer region housing. The transfer apparatus may include an end effector coupled with the rotatable shaft. The end effector may include a central hub defining a central aperture fluidly coupled with a purge source. The end effector may also include a plurality of arms having a number of arms equal to a number of substrate supports of the plurality of substrate supports.

The present invention relates to a substrate processing apparatus, and more particularly, the substrate processing apparatus includes a gas utility exhausting each of the reaction space and the protective space so that a pressure change process including a high-pressure process, which is in a state of a pressure higher than atmospheric pressure, and a low-pressure process that is in a state of a pressure lower than the atmospheric pressure, is performed on a plurality of substrates introduced into the reaction space.

The present invention relates to a substrate processing apparatus, and more particularly, to a substrate processing apparatus in which a substrate is processed at a high pressure and a low pressure. The substrate processing apparatus includes an outer tube which defines a protective space therein and has a lower portion in which a first inlet is provided and an inner tube which defines a reaction space therein and has a lower portion in which a second inlet is provided, wherein a portion of the inner tube is accommodated in the outer tube, and the portion, in which the second inlet is provided, protrudes downward from the outer tube.

In this method for manufacturing a semiconductor element, a modified layer produced by subjecting a substrate (70) to mechanical polishing is removed by heating the substrate (70) under Si vapor pressure. An epitaxial layer formation step, an ion implantation step, an ion activation step, and a second removal step are then performed. In the second removal step, macro-step bunching and insufficient ion-implanted portions of the surface of the substrate (70) performed the ion activation step are removed by heating the substrate (70) under Si vapor pressure. After that, an electrode formation step in which electrodes are formed on the substrate (70) is performed.

A substrate processing apparatus includes a first processing module including a first processing module, a second processing module, a first utility system adjacent to a back surface of the first processing module, and a second utility system adjacent to a back surface of the second processing module, a first exhaust box of the first utility system and a second exhaust box of the second utility system being disposed to face each other across a maintenance area located behind a part of the back surface of the first processing module that is close to the second processing module and behind a part of the back surface of the second processing module that is close to the first processing module, and a first supply box of the first utility system and a second supply box of the second utility system being disposed to face each other across the maintenance area.

Methods and apparatus for supporting substrates are provided herein. In some embodiments, a substrate support for supporting a plurality of substrates includes: a plurality of substrate support elements having a ring shape configured to support a plurality of substrates in a vertically spaced apart relation; and a plurality of substrate lift elements interfacing with the plurality of substrate support elements and configured to simultaneously selectively raise or lower substrates off of or onto respective substrate support elements.

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.

The invention relates to a substrate rack and a substrate processing system for processing substrates in a reaction chamber. The substrate rack may be used for introducing a plurality of substrates in the reaction chamber. The substrate rack may have a plurality of spaced apart substrate holding provisions configured to hold the substrates in a spaced apart relationship. The rack may have an illumination system to irradiate radiation with a range from 100 to 500 nanometers onto a top surface of the substrates.

Provided are a cleaning device and a method for driving the cleaning device which cleans a wafer after chemical mechanical polishing. The cleaning device includes a cleaning modules and a running beam, the running beam including a first blade and a second blade to insert or remove the wafer with respect to one of the cleaning modules in a second direction, the first blade and the second blade being fixed to the running beam and movable in the second direction, and the cleaning modules including an input module, a megasonic module, a first brush module, a second brush module and a drying module. The driving method includes performing an operation of inserting or removing the wafer in the second direction using the first blade in a first area; and performing an operation of inserting or removing the wafer in the second direction using the second blade in a second area.