A method of cleaning and polishing a backside surface of a semiconductor wafer is provided. The method includes placing an abrasive brush, comprising an abrasive tape wound around an outer surface of a brush member of the abrasive brush, on the backside surface of the semiconductor wafer. The method also includes rotating the brush member to polish the backside surface of the semiconductor wafer by abrasive grains formed on the abrasive tape and to clean the backside surface of the semiconductor wafer by the brush member which is not covered by the abrasive tape.

A substrate aligning method includes receiving a substrate by moving a substrate support from an outside of an outer periphery toward a central portion of the substrate along the substrate; and aligning the substrate such that the substrate support moves from a position different from a position partially upwardly warped along an outer peripheral edge of the substrate and a position partially downwardly warped along the outer peripheral edge of the substrate toward the central portion of the substrate so as to receive the substrate.

A method for manufacturing an SOI wafer including a step of performing an adjustment to a film thickness of an SOI layer of the SOI wafer by wet etching. In the step of performing the adjustment to the film thickness of the SOI layer, a first etching step of etching a surface of the SOI layer using an SC1 solution; and a second etching step of etching the surface of the SOI layer by bringing the SOI layer into contact with ozone water to form an oxide film on the surface of the SOI layer and then bringing the formed oxide film into contact with an HF-containing aqueous solution to remove the oxide film, are performed in combination. The etchings are performed such that a removal amount of the SOI layer in the first etching step is smaller than that in the second etching step.

A method for dry-etching a semiconductor substrate having an oxide film, including: evaluating a film quality of the oxide film and determining a time for performing the dry-etching on a basis of results of the evaluation in advance. This provides a method for controlling the etching amount of an oxide film accurately and suppressing over-etching and insufficient etching without influence from variation in the film quality of the oxide film when dry-etching the oxide film on the surface of the semiconductor substrate.

A manufacturing process of wafer thinning includes a step of wafer-grinding to grind a surface of a wafer to a first predetermined thickness, and a step of wafer-etching to etch the grinded face of the wafer with the first predetermined thickness to a second predetermined thickness.

Provided are a method and system for increasing etch rate and etch selectivity of a masking layer on a substrate in an etch treatment system, the etch treatment system configured for single substrate processing. The method comprises placing the substrate into the etch processing chamber, the substrate containing the masking layer and a layer of silicon or silicon oxide, obtaining a supply of steam water vapor mixture at elevated pressure, obtaining a supply of treatment liquid for selectively etching the masking layer over the silicon or silicon oxide at a selectivity ratio, combining the treatment liquid and the steam water vapor mixture, and injecting the combined treatment liquid and the steam water vapor mixture into the etch processing chamber. The flow of the combined treatment liquid and the steam water vapor mixture is controlled to maintain a target etch rate and a target etch selectivity ratio of the masking layer to the layer of silicon or silicon oxide.

An exemplary embodiment of the present invention provides a substrate treating method including removing particles formed on a substrate by continuously performing a process of supplying a treatment liquid including a polymer and a solvent onto the substrate, forming a solidified liquid film by volatilizing the solvent in the treatment liquid, removing the solidified liquid film from the substrate by supplying a stripping liquid onto the substrate; and supplying a rinse liquid onto the substrate.

Disclosed is a method of adjusting a concentration of a chemical liquid in a treatment liquid, the method including: treating a substrate by supplying a treatment liquid stored in a main tank from a nozzle in a heated state to the substrate, and recovering the treatment liquid used in the treatment of the substrate to the main tank directly or via still another tank, and then reusing the recovered treatment liquid, a concentration adjustment operation of adjusting a concentration of the treatment liquid in the main tank is performed in a standby time period in which the substrate is not treated with the treatment liquid, and the concentration adjustment operation is performed by discharging the treatment liquid in a heated state from the nozzle to evaporate a part of the diluting solution, and recovering the discharged treatment liquid to the main tank.

There is provided a substrate processing apparatus including: a substrate holder configured to hold a substrate on which a resist pattern is formed; a rinse solution supply unit configured to supply a rinse solution onto the substrate held by the substrate holder; a vapor supply unit configured to supply vapor of a first processing solution, which hydrophobicizes the resist pattern, onto the substrate on which the rinse solution is supplied from the rinse solution supply unit; and a rinse solution removing unit configured to remove the rinse solution from the substrate in an atmosphere including the vapor of the first processing solution supplied from the vapor supply unit.

A cleaning device includes: a substrate rotation mechanism that holds and rotates a substrate around center axis thereof; a first single-tube nozzle that discharges first cleaning liquid toward a top surface of the substrate; and a second single-tube nozzle that discharges second cleaning liquid toward the top surface of the substrate. The first single-tube nozzle and the second single-tube nozzle are disposed such that the second single-tube nozzle discharges the second cleaning liquid in a forward direction of a rotation direction of the substrate at a position farther away from the center of the substrate than a landing position of the first cleaning liquid, and a part is generated in which liquid flow on the top surface of the substrate after landing of the first cleaning liquid and liquid flow on the top surface of the substrate after landing of the second cleaning liquid are combined.