The inventive concept relates to a liquid dispensing nozzle and an apparatus for treating a substrate. The liquid dispensing nozzle includes a first fluid channel that is formed in the nozzle and through which a processing liquid flows and a second fluid channel in communication with the first fluid channel, the second fluid channel being connected to a dispensing end of the nozzle. The second fluid channel has a larger width than the first fluid channel, and a central axis of the first fluid channel and a central axis of the second fluid channel are connected with each other in a straight line.

Disclosed is a substrate treating apparatus that treats a substrate with processing liquids. The apparatus includes a substrate holder, an exterior cup, and an interior cup. The interior cup includes an interior cup body, and an interior cup outlet. The exterior cup includes an exterior cup body, an exterior bottom cup, a first drain outlet, a first exhaust port, a second drain outlet, a second exhaust port, and a separation partition. The apparatus further includes an annular member movable upwardly/downwardly, and a drive unit that causes the annular member to move to shift the interior cup body between a collecting position and a retracting position.

A nozzle is stored in a nozzle storage hole of a waiting pod. In this state, a cleaning liquid is discharged to an outer peripheral surface of the nozzle from a plurality of discharge ports. Thus, a coating liquid and its solidified matter adhering to the nozzle are dissolved and removed from the nozzle. Subsequently, a metal removal liquid is discharged from a plurality of discharge ports to the outer peripheral surface of the nozzle. Thus, a metallic component remaining on the nozzle is dissolved and removed from the nozzle. Further, pure water is discharged to the outer peripheral surface of the nozzle from the plurality of discharge ports, and the metal removal liquid adhering to the nozzle is cleaned away.

A method includes forming a liquid puddle of a mixed solution of the diluting liquid and the processing liquid; rotating the substrate at a first rotation speed which allows the mixed solution located at a region facing an inner side than an edge of the liquid contact surface to stay between the liquid contact surface and the surface of the substrate and allows the mixed solution located at a region facing an outer side than the edge of the liquid contact surface to be diffused toward an edge of the substrate; rotating the substrate at a second rotation speed smaller than the first rotation speed after the substrate is rotated at the first rotation speed; and moving the nozzle toward the edge of the substrate while discharging the processing liquid from the discharge hole in a state that the substrate is rotated at the second rotation speed.

A treatment solution supply apparatus supplies a treatment solution to a solution treatment apparatus which applies the treatment solution to a substrate to perform a predetermined treatment. Plural solution treatment apparatuses are supply destinations of the treatment solution. The treatment solution supply apparatus includes: a sending unit common among the solution treatment apparatuses, the sending unit sends the treatment solution stored in a treatment solution supply source to each of the solution treatment apparatuses; and a control unit that controls the sending unit. The sending unit includes pumps that suck the treatment solution and load the treatment solution thereinto and send the loaded treatment solution. The control unit controls suction timing of each of the pumps so that one (or more) of the pumps becomes in a state capable of sending the treatment solution to the solution treatment apparatuses at all times.

A photolithography method includes dispensing a first liquid onto a first target layer formed over a first wafer through a nozzle at a first distance from the first target layer; capturing an image of the first liquid on the first target layer; patterning the first target layer after capturing the image of the first liquid; comparing the captured image of the first liquid to a first reference image to generate a first comparison result; responsive to the first comparison result, positioning the nozzle and a second wafer such that the nozzle is at a second distance from a second target layer on the second wafer; dispensing a second liquid onto the second target layer formed over the second wafer through the nozzle at the second distance from the second target layer; and patterning the second target layer after dispensing the second liquid.

The present disclosure provides an apparatus for dispensing liquid material, including a dispensing arm, a wafer holder against the dispensing arm, a first nozzle on the dispensing arm, a first distance laterally spacing the first nozzle and a center of the wafer holder, and a first height vertically spacing the first nozzle and a surface of the wafer holder, and a second nozzle on the dispensing arm, a second distance laterally spacing the second nozzle and the center of the wafer holder, and a second height vertically spacing the second nozzle and the surface of the wafer holder, wherein the second distance is greater than the first distance, and the first height is greater than the second height.

A substrate processing method includes a substrate holding step of holding a substrate by a substrate holding unit, a chemical liquid supplying step of supplying a chemical liquid to a main surface of the substrate while rotating the substrate around a rotational axis passing through a central portion of the substrate, a foreign matter detecting step of detecting foreign matter, contained in the chemical liquid expelled from the substrate, in parallel with the chemical liquid supplying step, and a flow destination switching step of switching, based on the detection of the foreign matter by the foreign matter detecting step, a flow destination of the chemical liquid expelled from the substrate from a drain piping to a recovery piping during the chemical liquid supplying step.

An apparatus for performing liquid treatment for a substrate is provided. The apparatus for performing the liquid treatment for the substrate may include a housing having a treatment space, a substrate support unit to support and rotate the substrate in the treatment space, a liquid feeding unit including a nozzle device including a central exhaust port and multiple first outer exhaust ports, which are provided in a shape of a ring to form a concentric circle with the central exhaust port to feed mutually different treating liquids onto the substrate through respective exhaust ports, and a controller to control the liquid feeding unit.

A substrate inspection system is provided to monitor characteristics of a substrate, while the substrate is disposed within (or being transferred into/out of) a processing unit of a liquid dispense substrate processing system. The inspection system is integrated within a liquid dispense substrate processing system and includes one or more optical sensors of a reflectometer (such as a spectrometer or laser-based transceiver) configured to obtain spectral data from a substrate. A controller is coupled to receive the spectral data from the optical sensors(s). The one or more optical sensors (or one or more optical fibers coupled to the rest of the optical sensor hardware) are coupled at locations within the substrate processing system. The controller analyzes the spectral data received from the optical sensors(s) to detect characteristic(s) of the substrate including, but not limited to, film thickness (FT), refractive index changes, and associated critical dimension (CD) changes.