Provided is an apparatus for treating a substrate. The apparatus for treating the substrate includes a chamber having an inner space, a support unit configured to support the substrate in the inner space, a gas supply tube configured to supply a gas onto the substrate supported on the support unit, a gas exhaust tube configured to exhaust the gas from the inner space, and a gas block connected to the gas supply tube and the gas exhaust tube and provided above the chamber.

In an embodiment, a pattern transfer processing chamber includes a pattern transfer processing chamber and a loading area external to the pattern transfer processing chamber. The loading area is configured to transfer a wafer to or from the pattern transfer processing chamber. The loading area comprises a first region including a loadport, a second region including a load-lock between the first region and the pattern transfer processing chamber, and an embedded baking chamber configured to heat a patterned photoresist on the wafer.

Semiconductor processing apparatuses and methods are provided in which an electrostatic discharge (ESD) prevention layer is utilized to prevent or reduce ESD events from occurring between a semiconductor wafer and one or more components of the apparatuses. In some embodiments, a semiconductor processing apparatus includes a wafer handling structure that is configured to support a semiconductor wafer during processing of the semiconductor wafer. The apparatus further includes an ESD prevention layer on the wafer handling structure. The ESD prevention layer includes a first material and a second material, and the second material has an electrical conductivity that is greater than an electrical conductivity of the first material.

A substrate processing device includes a transfer chamber configured to transfer a substrate under an atmospheric atmosphere and a plurality of processing units each including at least one processing chamber for processing the substrate under a vacuum atmosphere and at least one load-lock chamber connected to the processing chamber to switch an inner atmosphere thereof between the atmospheric atmosphere and the vacuum atmosphere. The transfer chamber includes a connection unit configured to connect the transfer chamber and the load-lock chamber such that each of the processing units is detachably attached. The connection unit includes an opening that allows the transfer chamber to communicate with the load-lock chamber, and an opening/closing mechanism configured to open and close the opening portion.

An atmosphere-to-vacuum (ATV) transfer module for a substrate processing tool includes a first side configured to interface with at least one loading station, a transfer robot assembly arranged within the ATV transfer module, and a second side opposite the first side. The transfer robot assembly is configured to transfer substrates between the at least one loading station and at least one load lock arranged between the ATV transfer module and a vacuum transfer module (VTM). The second side is configured to interface with the at least one load lock. The transfer robot assembly is arranged adjacent to the second side, and the at least one load lock extends through the second side into an interior volume of the ATV transfer module.

A substrate processing method is provided. The method comprises a first step of supplying a processing gas containing a halogen-containing gas and a basic gas to a substrate, which a silicon film is formed on and has a first temperature, and generating a reaction product by deforming a surface of the silicon film; and a second step of removing the reaction product by setting the substrate to a second temperature after the first step.

According to various embodiments, a frame cassette includes a housing and a mounting structure within the housing. The mounting structure includes a plurality of tape-frame slots, each tape-frame slot configured to receive a tape-frame. The housing includes an opening configured to introduce a tape-frame into a tape-frame slot of the plurality of tape-frame slots, or to remove the tape frame from the tape-frame slot of the plurality of tape-frame slots. The housing also includes an electrostatic discharge protection. A corresponding automatic transportation system and method of automatic transportation of semiconductor wafers is also provided.

A method of preparing a self-aligned via on a semiconductor workpiece includes using an integrated sequence of processing steps executed on a common manufacturing platform hosting a plurality of processing modules including one or more film-forming modules, one or more etching modules, and one or more transfer modules. The integrated sequence of processing steps include receiving the workpiece into the common manufacturing platform, the workpiece having a pattern of metal features in a dielectric layer wherein exposed surfaces of the metal features and exposed surfaces of the dielectric layer together define an upper planar surface; selectively etching the metal features to form a recess pattern by recessing the exposed surfaces of the metal features beneath the exposed surfaces of the dielectric layer using one of the one or more etching modules; and depositing an etch stop layer over the recess pattern using one of the one or more film-forming modules.

Disclosed in the present disclosure are a cleaning machine and a cleaning method. The cleaning machine includes: a wet cleaning module, configured to execute a wet cleaning process on a wafer; a dry cleaning module, configured to execute a dry cleaning process on the wafer; a conveying module, configured to input the wafer into the wet cleaning module or the dry cleaning module, or output the wafer from the wet cleaning module or the dry cleaning module; a transferring module, configured to transfer the wafer from the wet cleaning module to the dry cleaning module or transfer the wafer from the dry cleaning module to the wet cleaning module; and a processing module, configured to extract gas from the transferring module.

In an embodiment, a system, includes: a first pressurized load port interfaced with a workstation body; a second pressurized load port interfaced with the workstation body; the workstation body maintained at a set pressure level, wherein the workstation body comprises an internal material handling system configured to move a semiconductor workpiece within the workstation body between the first and second pressurized load ports at the set pressure level; a first modular tool interfaced with the first pressurized load port, wherein the first modular tool is configured to process the semiconductor workpiece; and a second modular tool interfaced with the second pressurized load port, wherein the second modular tool is configured to inspect the semiconductor workpiece processed by the first modular tool.