The present disclosure provides a substrate treating apparatus, in which stability is secured by performing a process under a lower pressure condition, and a substrate treating method using the same. The substrate treating apparatus comprises a chamber including a housing and a treating region, wherein a substrate on which a rinse liquid remains is loaded into the chamber, a supply port installed in the housing and for supplying a first drying gas and a second drying gas to the treating region, a first supply line connected to the supply port, and through which the first drying gas is moved, and a second supply line connected to the supply port, and through which the second drying gas is moved, wherein the first drying gas is a gas below a first temperature, and the second drying gas is a gas equal to or above the first temperature, wherein the second drying gas dries the rinse liquid remaining on the substrate.

Cleaning systems and methods for semiconductor fabrication use rotatable and translatable chuck assemblies that incorporate a compact drive system to cause chuck rotation. The system uses an offset drive gear that drives a ring gear. This reduces components whose friction or lubricants might generate undue contamination. The low friction chuck functionality of the present invention is useful in any fabrication tool in which a workpiece is supported on a rotating support during a treatment. The chuck is particularly useful in cryogenic cleaning treatments.

A substrate processing apparatus and a substrate processing method are provided, in which a flow rate of CO.sub.2 injected into a supercritical drying vessel is controlled through multi-level pressure control. The substrate processing method includes disposing a substrate coated with a chemical liquid in a process chamber, that includes a space in which the substrate is processed; drying the substrate by using a supercritical fluid; and taking the substrate out of the process chamber when the substrate is dried.

A system for controlling damages in cleaning a semiconductor wafer comprising features of patterned structures, the system comprising: a wafer holder for temporary restraining a semiconductor wafer during a cleaning process; an inlet for delivering a cleaning liquid over a surface of the semiconductor wafer; a sonic generator configured to alternately operate at a first frequency and a first power level for a first predetermined period of time and at a second frequency and a second power level for a second predetermined period of time, to impart sonic energy to the cleaning liquid, the first predetermined period of time and the second predetermined period of time consecutively following one another; and a controller programmed to provide the cleaning parameters, wherein at least one of the cleaning parameters is determined such that a percentage of damaged features as a result of the imparting sonic energy is lower than a predetermined threshold.

A semiconductor cleaning agent containing a sulfonic acid group-containing polymer, wherein a content of at least one metal selected from the group consisting of Na, Al, K, Ca and Fe is 0.7 ppm or less.

A cleaning method applied in semiconductor manufacturing is provided. The method includes: receiving a substrate having a surface; identifying a location of a particle on the surface of the substrate; moving a cleaning apparatus toward the location of the particle; performing a cleaning operation, thereby removing the particle by spraying a cleaning liquid from the cleaning apparatus flowing against gravity and toward the surface of the substrate; detecting the surface of the substrate; and performing a second cleaning operation when a cleaning result of the detection is not acceptable. A semiconductor manufacturing method and a system for cleaning a substrate are also provided.

Methods, apparatus, and systems are provided herein for processing a substrate. Generally, the processing involves Spacer-on-Spacer (SoS) Self-Aligned Quadruple Patterning (SAQP) techniques. The disclosed techniques provide a novel process flow that reduces defects by ensuring that cores are not removed from the substrate until the substrate is transferred to a deposition chamber used to deposit a second spacer layer. This reduces or eliminates the risk of structural damage to features on the substrate while the substrate is being transferred or cleaned. Such structural damage is common when the cores are removed from the substrate prior to cleaning and transfer.

A device for cleaning a wafer in a semiconductor manufacturing apparatus includes a showerhead and an adjustable distributor assembly. The showerhead is disposed over a wafer stage within a cleaning chamber and configured to eject cleaning material through the showerhead towards a cleaning surface of a wafer. The adjustable distributor assembly is disposed within the showerhead through which the cleaning material passes. The adjustable distributor assembly includes a base sheet and a plurality of control sheets. The base sheet includes base openings, and the plurality of control sheets include control openings and are configured to slidably mate with the base sheet to provide selectively adjustable openings.

A substrate processing method includes a substrate holding step of holding a substrate having a front surface on which a metal is exposed, an inert gas replacing step of replacing an atmosphere around the front surface of the substrate with an inert gas by supplying an inert gas to a vicinity of the front surface of the substrate, an adjusting step of adjusting a pH of the rinsing liquid so as to form an inactive state in which the metal does not react with the rinsing liquid or so as to form a passive state by allowing the metal to react with the rinsing liquid, and a rinsing liquid supplying step of supplying the rinsing liquid whose pH has been adjusted to the front surface of the substrate after the atmosphere around the front surface of the substrate has been replaced with the inert gas.

A cleaning apparatus includes a gas supply line and a cleaning liquid supply line. A nozzle is connected to the gas and the cleaning liquid supply lines. The nozzle applies the cleaning liquid to a substrate. A gas entrance port at a top of a body of the nozzle is connected to the gas supply line. A first cleaning liquid entrance port is disposed on a sidewall of the nozzle body and is connected to the cleaning liquid supply line. A fluid injection port is disposed at a bottom of the nozzle body and discharges both the gas and the cleaning liquid. An internal passage of the nozzle body connects each of the gas entrance port and the first cleaning liquid entrance port to the fluid injection port. The fluid injection port has a diameter that is greater than a diameter of the first cleaning liquid entrance port.