Disclosed is a method to develop lithographically defined high aspect ratio interconnects. Also disclosed is an apparatus comprising at least one vessel having a bottom and at least one sidewall extending from the bottom, wherein the at least one sidewall encloses an interior of the at least one vessel, a shaft having a proximal end and a distal end, wherein the distal end of the shaft extends into the interior of the at least one vessel, wherein the proximal end of the shaft is coupled to a motor, at least one support structure which extends laterally from the shaft, and a substrate attachment fixture on a distal end of the at least one support structure, wherein the at least one support structure and the substrate attachment fixture are within the interior of the at least one vessel.

A method of processing a substrate includes: performing a first developing process of moving a nozzle having one end surface and a discharge port opened at the end surface while making the end surface come into contact with a developer on a front surface of a substrate in a state in which the nozzle is disposed so that the end surface faces the front surface and the developer is discharged from the discharge port at a first flow rate while rotating the substrate; and after the first developing process, performing a second developing process of discharging the developer from the discharge port at a second flow rate higher than the first flow rate in a state in which the end surface is in contact with the developer on the front surface at a position facing a center of the front surface of the substrate while rotating the substrate.

A method of processing a substrate includes: performing a first developing process of moving a nozzle having one end surface and a discharge port opened at the end surface while making the end surface come into contact with a developer on a front surface of a substrate in a state in which the nozzle is disposed so that the end surface faces the front surface and the developer is discharged from the discharge port at a first flow rate while rotating the substrate; and after the first developing process, performing a second developing process of discharging the developer from the discharge port at a second flow rate higher than the first flow rate in a state in which the end surface is in contact with the developer on the front surface at a position facing a center of the front surface of the substrate while rotating the substrate.

A spin dispenser module and methods for using the same is disclosed. The spin dispenser module includes a cup having a basin with sidewalls and an exhaust, a rotatable platform situated inside the cup adapted for holding and rotating a substrate, a liquid dispenser disposed over the rotatable platform for dispensing a liquid coating material on top of the substrate, one or more ejector inlets disposed over the rotatable platform, the one or more ejectors connected to a negative pressure source, and a motor coupled to the rotatable platform to rate the rotatable platform at different rotational speeds. The one or more ejector inlets may be translatable and/or rotatable with optionally adjustable suction pressure. The ejector inlets operate after a liquid coating material is dispensed to avoid deposition of suspended organic compounds after a coating is formed.

A solution supply apparatus is for supplying a treatment solution to a treatment solution discharger which discharges the treatment solution to a treatment object. The solution supply apparatus includes: a supply pipe line connected to the treatment solution discharger; a filter provided on the supply pipe line which filters the treatment solution to remove foreign substances; and a controller. The controller performs a determination of a state of the treatment solution to be supplied to a primary side of the filter and, when the state of the treatment solution is determined to be bad, outputs a control signal for restricting supply of the treatment solution to the primary side of the filter.

A chemical supply structure includes a bar-shaped body having a plurality of chemical reservoirs in which a plurality of chemicals is individually stored such that the body partially crosses an underlying substrate, a bar-shaped nozzle protruded from a bottom surface of the body and injecting injection chemicals onto the substrate, a plurality of the chemicals being mixed into the injection chemicals, and a hydrophobic unit arranged on the bottom surface of the body and on a side surface of the nozzle such that a mixed solution mixed with the injection chemicals is prevented from adhering to the bottom surface and the side surface by controlling a contact angle of the mixed solution with respect to the bottom surface and the side surface.

A developer tool described herein includes a dispenser that includes a greater quantity of nozzles in a central portion relative to a perimeter portion such that the developer tool is capable of more effectively removing material from a photoresist layer near a center of a substrate (which tends to be thicker near the center of the substrate relative to the edge or perimeter of the substrate). In this way, the developer tool may reduce the amount of photoresist residue or scum remaining on the substrate near the center of the substrate after a development operation, which may enable defect removal and/or prevention, may increase semiconductor processing yield, and/or may increase semiconductor processing quality.

An apparatus, comprising at least one vessel having a bottom and at least one sidewall extending from the bottom, wherein the at least one sidewall encloses an interior of the at least one vessel, a shaft has a proximal end and a distal end, wherein the distal end of the shaft extends into the interior of the at least one vessel, wherein the proximal end of the shaft is coupled to a motor, at least one support structure which extends laterally from the shaft; and a substrate attachment fixture on a distal end of the at least one support structure, wherein the at least one support structure and the substrate attachment fixture are within the interior of the at least one vessel.

A wafer cleaning method is provided. The wafer cleaning method includes providing a wafer on a stage that is inside of a chamber. The wafer is fixed to the stage by moving a grip pin connected to an edge of the stage. First ultrapure water is supplied onto the wafer while the wafer is rotating at a first rotation speed. The grip pin is released from the wafer by moving the grip pin. A development process is performed by supplying liquid chemical onto the wafer while the wafer is rotating at a second rotation speed that is less than the first rotation speed.

A developing method is provided. The developing method includes rotating a wafer. The developing method also includes dispensing, through a first nozzle, a developer solution onto the rotated wafer through a first nozzle at a first rotating speed. The developing method further includes dispensing, through a second nozzle, a rinse solution onto the rotated wafer through a second nozzle at a second rotating speed. The second rotating speed is less than the first rotating speed. In addition, the developing method includes simultaneously moving the first nozzle and the second nozzle during either the dispensing of the developer solution or the dispensing of the rinse solution.