A plasma processing apparatus has a vacuum container having a processing chamber in which a wafer is processed by plasma and at least one member constituting the vacuum container movable and detachable in a horizontal direction with respect to a base plate. The plasma processing apparatus includes a lifter arranged at a side of the vacuum container across the vacuum container on the base plate, coupled to an end portion on the opposite side of a vacuum transfer chamber on which the wafer is transferred in a decompressed interior, and having a vertical shaft to move the detachable member vertically. The lifter includes: a coupling portion coupled to the vertical shaft and the detachable member and moved along the vertical shaft; and a turning shaft being a joint portion arranged at the coupling portion and having a vertical rotational shaft, the detachable member being horizontally turned around the turning shaft.

A processing system and platform for improving both the microscopic and macroscopic uniformity of materials during etching is disclosed herein. These improvements may be accomplished through the formation and dissolution of thin, self-limiting layers on the material surface by the use of wet atomic layer etching (ALE) techniques. For etching of polycrystalline materials, these self-limiting reactions can be used to prevent this roughening of the surface during etching. Thus, as disclosed herein, a wet ALE process uses sequential, self-limiting reactions to first modify the surface layer of a material and then selectively remove the modified layer.

Provided is a substrate processing apparatus that removes a film by supplying a processing liquid to the peripheral edge of a substrate. An ejection unit ejects the processing liquid to the peripheral edge of the substrate held and rotated by a substrate holding unit. An ejection position setting unit sets the ejection position of the processing liquid of the ejection unit to correspond to the removal width of the film included in a recipe, and a property information acquisition unit acquires property information of the film to be removed. A correction amount acquisition unit acquires the correction amount for correcting the ejection position of the processing liquid based on the property information of the film, and an ejection position correction unit corrects the ejection position of the processing liquid by the ejection unit based on the correction amount acquired by the correction amount acquisition unit.

Provided is a substrate processing apparatus that removes a film by supplying a processing liquid to the peripheral edge of a substrate. An ejection unit ejects the processing liquid to the peripheral edge of the substrate held and rotated by a substrate holding unit. An ejection position setting unit sets the ejection position of the processing liquid of the ejection unit to correspond to the removal width of the film included in a recipe, and a property information acquisition unit acquires property information of the film to be removed. A correction amount acquisition unit acquires the correction amount for correcting the ejection position of the processing liquid based on the property information of the film, and an ejection position correction unit corrects the ejection position of the processing liquid by the ejection unit based on the correction amount acquired by the correction amount acquisition unit.

Methods are provided for conducting a deposition on a semiconductor substrate by selectively depositing a material on the substrate. The substrate has a plurality of substrate materials, each with a different nucleation delay corresponding to the material deposited thereon. Specifically, the nucleation delay associated with a first substrate material on which deposition is intended is less than the nucleation delay associated with a second substrate material on which deposition is not intended according to a nucleation delay differential, which degrades as deposition proceeds. A portion of the deposited material is etched to reestablish the nucleation delay differential between the first and the second substrate materials. The material is further selectively deposited on the substrate.

Methods, systems, and computer programs are presented for selective deposition of etch-stop layers for enhanced patterning during semiconductor manufacturing. One method includes an operation for adding a photo-resist material (M2) on top of a base material (M1) of a substrate, M2 defining a pattern for etching M1 in areas where M2 is not present above M1. The method further includes operations for conformally capping the substrate with an oxide material (M3) after adding M2, and for gap filling the substrate with filling material M4 after the conformally capping. Further, a stop-etch material (M5) is selectively grown on exposed surfaces of M3 and not on surfaces of M4 after the gap filling. Additionally, the method includes operations for removing M4 from the substrate after selectively growing M5, and for etching the substrate after removing M4 to transfer the pattern into M1. M5 adds etching protection to enable deeper etching into M1.

Methods are provided for conducting a deposition on a semiconductor substrate by selectively depositing a material on the substrate. The substrate has a plurality of substrate materials, each with a different nucleation delay corresponding to the material deposited thereon. Specifically, the nucleation delay associated with a first substrate material on which deposition is intended is less than the nucleation delay associated with a second substrate material on which deposition is not intended according to a nucleation delay differential, which degrades as deposition proceeds. A portion of the deposited material is etched to reestablish the nucleation delay differential between the first and the second substrate materials. The material is further selectively deposited on the substrate.

A substrate processing method according to an exemplary embodiment includes: supplying, to a peeling target portion which is at least a portion of a coating film including a first coating film and a second coating film, a chemical liquid for enhancing a peeling performance between the first coating film and the second coating film, the first coating film being formed on a surface of a substrate, the second coating film being formed on the first coating film and containing carbon with a different composition from that of the first coating film; amplifying a temperature fluctuation of the peeling target portion to which the chemical liquid has been supplied; and supplying a rinse liquid for removing the second coating film to the peeling target portion after the amplification of the temperature fluctuation.

A substrate processing method according to an exemplary embodiment includes: supplying, to a peeling target portion which is at least a portion of a coating film including a first coating film and a second coating film, a chemical liquid for enhancing a peeling performance between the first coating film and the second coating film, the first coating film being formed on a surface of a substrate, the second coating film being formed on the first coating film and containing carbon with a different composition from that of the first coating film; amplifying a temperature fluctuation of the peeling target portion to which the chemical liquid has been supplied; and supplying a rinse liquid for removing the second coating film to the peeling target portion after the amplification of the temperature fluctuation.

Methods, apparatuses and systems are disclosed for chemically etching parts by generating an enclosed chemical etching chamber in contact with a part surface and directing a flow of chemical etchant solution in contact with a part region to be etched.