A photoresist removal method is provided. The photoresist removal method includes analyzing the process status of each of a number of semiconductor substrate models undergoing a tested plasma ash process by a residue gas analyzer. The tested plasma ash processes for the semiconductor substrate models utilize a plurality of tested recipes. The photoresist removal method further includes selecting one of the tested recipes as a process recipe based on the analysis results from the residue gas analyzer and at least one expected performance criterion. In addition, the photoresist removal method includes performing a plasma ash process on a semiconductor substrate according to the process recipe to remove a photoresist layer from the semiconductor substrate.

Embodiments of the inventive concept provide a substrate treating apparatus. According to an exemplary embodiment, the substrate treating apparatus comprises a first process chamber applying a process fluid containing an organic solvent to a substrate wet with a developer and introduced; and a second process chamber treating the substrate applied with the process fluid and introduced, through a supercritical fluid.

An atmospheric pressure plasma generating device includes a nozzle block in which fourth gas passages from which plasma gas is emitted are formed, is covered by cover, and a through-hole is formed in the cover such that the leading end of the fourth gas passage is positioned on the inside. Heated gas is supplied inside the cover and is emitted from the through-hole of the cover, and plasma gas is emitted so as to penetrate the heated gas. By the plasma gas being surrounded by the heated gas in this manner, deactivation of the plasma gas is prevented. A distance between the leading end of the fourth gas passage and an opening of the through-hole at an outer wall of the cover is set from 0 to 2 mm in an emission direction of the plasma gas.

A plasma ashing system includes a plasma generator configured to generate a plasma from a gas source. The system further includes a plasma reaction chamber configured to house a substrate comprising a Parylene coating, wherein the plasma reaction chamber is configured to expose surfaces of the Parylene coating on the substrate to the plasma, wherein the plasma is configured to remove portions of the Parylene coating on the substrate. The plasma reaction chamber comprises a sensor or analyzer configured to determine when to stop plasma ashing the substrate.

Plasma-Activated liquids and methods of using the same are described. In one aspect, a method of manufacturing an integrated circuit includes activating a photolithography liquid with a plasma; and treating a device component with the activated photolithography liquid. In one example, the photolithography liquid is a photoresist. Activating the photoresist liquid may impart reactive species to the photoresist.

Disclosed are a substrate treating apparatus and a substrate treating method. The substrate treating apparatus includes a first process chamber configured to supply a development liquid to a substrate that is carried into the first process chamber after an exposure process is performed on the substrate, a second process chamber configured to treat the substrate through a supercritical fluid, a feeding robot configured to transfer the substrate from the first process chamber to the second process chamber, and a controller configured to control the feeding robot such that the substrate is transferred to the second process chamber in a state in which the development liquid supplied by the first process chamber resides in the substrate.

Methods for processing a workpiece with fluorine radicals are provided. In one example implementation, the method includes a workpiece having at least one silicon layer and at least one silicon germanium layer. The method can include placing the workpiece on a workpiece support in a processing chamber. The method can include generating one or more species from a process gas in a plasma chamber. The method can include filtering the one or more species to create a filtered mixture. The method can include exposing the workpiece to the filtered mixture to remove at least a portion of the at least one silicon layer.

A single layer process is utilized to reduce swing effect interference and reflection during imaging of a photoresist. An anti-reflective additive is added to a photoresist, wherein the anti-reflective additive has a dye portion and a reactive portion. Upon dispensing the reactive portion will react with underlying structures to form an anti-reflective coating between the underlying structure and a remainder of the photoresist. During imaging, the anti-reflective coating will either absorb the energy, preventing it from being reflected, or else modify the optical path of reflection, thereby helping to reduce interference caused by the reflected energy.

Processes for removing a mask layer (e.g., doped amorphous carbon mask layer) from a substrate with high aspect ratio structures are provided. In one example implementation, a process can include depositing a polymer layer on at least a portion of a top end of a high aspect ratio structure on a substrate. The process can further include removing at least a portion of the polymer layer and the doped amorphous carbon film form the substrate using a plasma strip process. In example embodiments, depositing a polymer layer can include plugging one or more high aspect ratio structures with the polymer layer. In example embodiments, depositing a polymer layer can include forming a polymer layer on a sidewall of one or more high aspect ratio structures.

Processes for removing photoresist layer(s) from a workpiece, such as a semiconductor are provided. In one example implementation, a method for processing a workpiece can include supporting a workpiece on a workpiece support. The workpiece can have a photoresist layer and a low-k dielectric material layer. The method can include performing a hydrogen radical etch process on the workpiece to remove at least a portion of the photoresist layer. The method can also include exposing the workpiece to an ozone process gas to remove at least a portion of the photoresist layer.