The present invention provides a substrate treating apparatus, including: a housing including a first body and a second body which are combined with each other to provide a treatment space in which a substrate is treated; an actuator which moves the second body in a vertical direction with respect to the first body to seal or open the treatment space; and a pipe which is coupled with the second body and in which a fluid flows, in which the pipe is a stretchable pipe that is stretchable and contractible according to the vertical movement of the second body.

A wafer inspection apparatus according to one embodiment is a wafer inspection apparatus including a plurality of inspection parts arranged in a height direction and a lateral direction, and includes a pair of air circulating means disposed at both ends in a longitudinal direction of an air circulating region including the plurality of inspection parts arranged in the lateral direction and configured to circulate air in the circulating region.

There is provided a film forming apparatus, including: a processing chamber having a processing space in which a film forming process is performed on a substrate; a substrate support part configured to support the substrate inside the processing chamber; at least one sputtering particle emission part including a target and configured to emit sputtering particles to the substrate from the target; and at least one etching particle emission part configured to emit etching particles having an etching action with respect to the substrate, wherein the sputtering particles emitted from the at least one sputtering particle emission part are deposited on the substrate to form a film, and a portion of the film is etched by the etching particles emitted from the at least one etching particle emission part.

Exemplary substrate processing systems may include chamber body defining a transfer region. The systems may include a lid plate seated on the chamber body. The lid plate may define a first plurality of apertures through the lid plate and a second plurality of apertures through the lid plate. The systems may include a plurality of lid stacks equal to a number of apertures of the first plurality of apertures defined through the lid plate. Each lid stack of the plurality of lid stacks may include a choke plate seated on the lid plate along a first surface of the choke plate. The choke plate may define a first aperture axially aligned with an associated aperture of the first plurality of apertures. The choke plate may define a second aperture axially aligned with an associated aperture of the second plurality of apertures.

Methods and apparatus for supporting a substrate are provided herein. In some embodiments, a substrate support to support a substrate having a given diameter includes: a base ring having an inner diameter less than the given diameter, the base ring having a support surface configured to contact a first surface of the substrate and to form a seal between the support surface and the first surface of the substrate, when disposed atop the base ring; and a clamp ring having an inner diameter less than the given diameter, wherein the clamp ring includes a contact surface proximate the inner diameter configured to contact an upper surface of the substrate, when present, and wherein the clamp ring and the base ring are further configured to provide a bias force toward each other to clamp the substrate in the substrate support.

A substrate processing apparatus includes: a loading/unloading block; a processing station provided on one of left and right sides of the loading/unloading block; a relay block provided on one of left and right sides of the processing station; processing blocks provided side by side in a left-right direction to form the processing station, each of the processing blocks including a processing module configured to perform a process on the substrate and a main transfer mechanism configured to deliver the substrate to the processing module; and bypass transfer mechanisms provided separately from the main transfer mechanism and provided respectively for the processing blocks arranged side by side in the left-right direction to transfer the substrate between left and right blocks, wherein bypass transfer paths for the substrate transferred by the plurality of bypass transfer mechanisms have heights different from each other, and partially overlap each other in a plan view.

Exemplary substrate processing systems may include a chamber body defining a transfer region. The systems may include a lid plate seated on the chamber body. The lid plate may define a plurality of apertures. The systems may include a plurality of lid stacks equal to a number of the plurality of apertures. The systems may include a plurality of substrate support assemblies equal to the number of apertures defined through the lid plate. Each assembly may be disposed in one of the processing regions and may include an electrostatic chuck body defining a substrate support surface that defines a substrate seat. Each assembly may include a heater embedded within the chuck body. Each assembly may include bipolar electrodes between the heater and the substrate support surface. Each assembly may include a conductive mesh embedded within the body between the heater and bipolar electrodes.

An apparatus for processing a substrate may include an upper chamber, a lower chamber being combined with the upper chamber and separated from the upper chamber, and at least one driving member for moving the lower chamber in an upward direction and a downward direction. The least one driving member may include a supporting element for supporting the lower chamber, a first driving element for moving the lower chamber and the supporting element, a second driving element for moving the lower chamber, the supporting element and the first driving element, the second driving element being disposed adjacent to the first driving element, and a connecting element for connecting the first driving element to the second driving element. A processing space may be provided between the upper chamber and the lower chamber when the lower chamber is combined with the upper chamber.

A semiconductor manufacturing device has an outer cup and inner cup with a wafer suction mount disposed within the outer cup. A photoresist material is applied to a first surface of a semiconductor wafer disposed on the wafer suction mount while rotating at a first speed. A gas port is disposed on the inner cup for dispensing a gas oriented toward a bottom side of the semiconductor wafer. The gas port purges a second surface of the semiconductor wafer with a gas to remove contamination. The second surface of the semiconductor wafer is rinsed while purging with the gas. The gas can be a stable or inert gas, such as nitrogen. The contamination is removed from the second surface of the semiconductor wafer through an outlet between the inner cup and outer cup. The semiconductor wafer rotates at a second greater speed after discontinuing purge with the gas.

An annealing apparatus includes a heater plate and a cooler plate disposed in a chamber, a delivering robot, a sensor and circuitry. The delivering robot is configured to deliver a wafer between the heater plate and the cooler plate in the chamber. The sensor is located on the delivering robot and configured to output a first signal in response to a motion of the delivering robot. The circuitry is coupled to the sensor and configured to detect whether an abnormality of the delivering robot occurs according to the first signal.