A wafer processing method of the present invention includes mounting a wafer part on a chuck table, loading the wafer part on the chuck table, spraying, by a spray arm module, a first processing solution onto the wafer part to process the wafer part, spraying, by the spray arm module, a second processing solution onto the wafer part to process the wafer part, drying the wafer part on the chuck table, and unloading the wafer part from the chuck table.

A processing condition specifying method that includes Steps S31, S32, and S33. In Step S31, a prediction thickness information piece containing prediction values of thicknesses after processing on the substrate W is calculated for each of a plurality of recipe information pieces based on measurement thickness information containing measurement values of thicknesses of the substrate W. In Step S32, the prediction thickness information pieces each calculated for a corresponding one of the recipe information pieces are evaluated according to a prescribed evaluation method and a prediction thickness information piece is selected from among the prediction thickness information pieces. In Step S33, a recipe information piece corresponding to the selected prediction thickness information piece is specified. The measurement values contained in the measurement thickness information indicate a thickness of the substrate W measured before processing on the substrate W.

A wafer processing method of the present invention includes mounting a wafer part on a chuck table, loading a ring cover unit on the chuck table to restrain the wafer part to the chuck table, spraying, by a spray suction arm module, a processing solution onto the wafer part and suctioning, by the spray suction arm module, foreign materials from the processing solution, unloading the ring cover unit from the chuck table, and spraying, by a spray arm module, a cleaning solution onto the wafer part to clean the wafer part.

The inventive concept provides a substrate treating apparatus. The substrate treating apparatus includes a chamber providing a treating space; and a fluid supply unit supplying a treating fluid to the chamber, and wherein the fluid supply unit includes: a supply tank storing the treating fluid; a supply line connecting the supply tank and the chamber; and a plurality of valves installed at the supply line, and wherein any one valve among the plurality of valves is provided as a safety valve, and wherein the safety valve is opened after confirming that the chamber has been switched to a closed state when supplying the treating fluid from a tank to the chamber.

Disclosed is a substrate treating apparatus that performs a cleaning treatment on substrates. A treating block includes a plurality of treating units in an upper and lower stages, respectively. The treating block includes a front face cleaning unit and a back face cleaning unit, each being at least one in number, in the upper stage. The treating block includes at least one tower unit including the front face cleaning unit and the back face cleaning unit, each being at least one in number, in the lower stage. Moreover, a transportation block is provided that includes a center robot in each of the upper and lower stages.

A method for cleaning semiconductor substrate without damaging patterned structure on the substrate using ultra/mega sonic device comprising applying liquid into a space between a substrate and an ultra/mega sonic device; setting an ultra/mega sonic power supply at frequency f.sub.1 and power P.sub.1 to drive said ultra/mega sonic device; before bubble cavitation in said liquid damaging patterned structure on the substrate, setting said ultra/mega sonic power supply at frequency f.sub.2 and power P.sub.2 to drive said ultra/mega sonic device; after temperature inside bubble cooling down to a set temperature, setting said ultra/mega sonic power supply at frequency f.sub.1 and power P.sub.1 again; repeating above steps till the substrate being cleaned. Normally, if f.sub.1=f.sub.2, then P.sub.2 is equal to zero or much less than P.sub.1; if P.sub.1=P.sub.2, then f.sub.2 is higher than f.sub.1; if the f.sub.1<f.sub.2, then, P.sub.2 can be either equal or less than P.sub.1.

A wafer cleaning apparatus, a method of cleaning wafer and a method of fabricating a semiconductor device are provided. The method of fabricating the semiconductor device includes disposing a wafer on a rotatable chuck, irradiating a lower surface of the wafer with a laser to heat the wafer, and supplying a chemical to an upper surface of the wafer to clean the wafer, wherein the laser penetrates an optical system including an aspheric lens array, the laser penetrates a calibration window, which includes a first window structure including a first light projection window including first and second regions different from each other, a first coating layer covering the first region of the first light projection window, and a second coating layer covering the second region of the first light projection window, and the first coating layer and the second coating layer have different light transmissivities from each other.

The inventive concept provides a substrate treating apparatus. The substrate treating apparatus includes a support unit horizontally maintaining a substrate; a laser irradiation unit for irradiating the substrate with a laser; a photo-detector for detecting an energy of a reflective light reflected from the substrate among a laser irradiated on the substrate; and a processor, and wherein the processor irradiates a first laser of a first output to the substrate, and sets a second output of a second laser for irradiating the substrate to heat the substrate, based on an energy of a first reflective light reflected from the substrate by the first laser detected from the photo-detector.

A substrate processing chamber includes a housing providing a process space; a spin apparatus provided in the housing; and a fluid spraying nozzle configured to spray fluid into the process space, wherein the spin apparatus includes: a spin chuck configured to support a substrate; a rotation driving part configured to rotate the spin chuck; and a weight sensor configured to measure a weight of the substrate supported on the spin chuck.

Embodiments of wet clean chambers are provided herein. In some embodiments, a wet clean chamber includes: a deck plate; a substrate support that is rotatable and configured to support a substrate; a rotor disposed about and configured to rotate with the substrate support, wherein the rotor includes an upper fluid collection region disposed radially outward of the substrate support in position to collect fluid leaving the substrate support during processing, and wherein the upper fluid collection region includes a plurality of drain openings along a radially outward perimeter of a bottom of the upper fluid collection region; a stationary housing surrounding the rotor and having a lower fluid collection region disposed beneath the drain openings of the rotor; and one or more fluid delivery arms coupled to the deck plate and configured to deliver fluid to the substrate.