Abstract: Provided are a substrate supporting unit and a substrate treating apparatus using the substrate supporting unit. The substrate supporting unit comprises a base plate and a supporting portion formed on the base plate. The supporting portion comprises two supporting rods and a plurality of supporting members. The two supporting rods extend in a predetermined direction to be separated from each other. The plurality of supporting members is disposed to be separated from each other in the predetermined direction. Each of the supporting members connects the supporting rods.

Abstract: The wafer processing apparatus 100 included in an etching apparatus selectively etches the peripheral portion of a wafer 200. The wafer processing apparatus 100 includes a lower electrode 112 as a stage on which the wafer 200 is placed, a process gas introducing duct 120 supplying therethgouh a process gas etching the peripheral portion, an etching-interfering gas introducing duct 118 supplying therethrough an etching-interfering gas interfering supply of the process gas to the center portion of the wafer, and a movable alignment mechanism 102 aligning the wafer on the lower electrode 112. The etching-interfering gas introducing duct 118 and the process gas introducing duct 120 can be provided in an upper electrode 106.

Abstract: A plasma processing apparatus and a focus ring enables to perform uniform plasma processing over the entire surface of a substrate to be processed to thereby improve in-surface uniformity of plasma processing compared with conventional cases. The focus ring is disposed on a susceptor 2, which serves to mount thereon a semiconductor wafer W and further functions as a lower electrode, to surround a periphery of the semiconductor wafer W. The focus ring 6 includes a ring member of a thin plate shape disposed to surround the periphery of the wafer W while maintaining a gap therebetween and a lower ring body installed below the semiconductor wafer and the ring member of the thin plate shape.

Abstract: A first flow passage (16), which cools a temperature controlled object by a circulating first cooling water (15), and a second flow passage (19) separate from the first flow passage are provided so as to exchange heat between a second cooling water (18) flowing through the second flow passage (19) and the first cooling water (15). There is no need to store the first cooling water (15) in a tank of a constant capacity, and the first cooling water (15) flowing through the first flow passage (16) of a chiller corresponding part is absorbed substantially in its entirety by the second cooling water (18). A response becomes quick with respect to a load fluctuation of the temperature controlled object, and waste of energy can be reduced while improving accuracy of temperature control.

Abstract: Provided is an apparatus and a method for heating fluid in a proximity head. A method for semiconductor wafer processing, includes providing liquid to a proximity head including a heating portion, heating the liquid within the heating portion of the proximity head and delivering the heated liquid to a surface of a semiconductor wafer for use in a wafer processing operation including forming a meniscus between the proximity head and the surface of the semiconductor wafer.

Abstract: A thermally zoned substrate holder including a substantially cylindrical base having top and bottom surfaces configured to support a substrate. A plurality of temperature control elements are disposed within the base. An insulator thermally separates the temperature control elements. The insulator is made from an insulting material having a lower coefficient of thermal conductivity than the base (e.g., a gas- or vacuum-filled chamber).

Abstract: A carrier head for chemical mechanical polishing of a substrate includes a base and a flexible membrane extending beneath the base. The flexible membrane includes a central portion with an outer surface providing a substrate receiving surface, a perimeter portion connecting the central portion to the base, and at least one flap extending from an inner surface of the central portion. The flap divides a volume between the flexible membrane and the base into a plurality of chambers, and the flap includes a laterally extending first section and an angled second section extending beneath the first section and connecting the laterally extending first section to the central portion.

Abstract: A pedestal assembly and method for controlling temperature of a substrate during processing is provided. In one embodiment, the pedestal assembly includes an electrostatic chuck coupled to a metallic base. The electrostatic chuck includes at least one chucking electrode and metallic base includes at least two fluidly isolated conduit loops disposed therein. In another embodiment, the pedestal assembly includes a support member that is coupled to a base by a material layer. The material layer has at least two regions having different coefficients of thermal conductivity. In another embodiment, the support member is an electrostatic chuck. In further embodiments, a pedestal assembly has channels formed between the base and support member for providing cooling gas in proximity to the material layer to further control heat transfer between the support member and the base, thereby controlling the temperature profile of a substrate disposed on the support member.

Abstract: A gas injection head 200 is provided above a substantial center of a substrate W. Nitrogen gas introduced from a gas feed port 291 is injected from a slit-shaped injection port 293 via an internal buffer space BF. In this way, a radial gas flow substantially isotropic in a horizontal direction while having an injection direction restricted in a vertical direction is generated above the substrate. Thus, dust D, mist M and the like around the substrate are blown off in outward directions and do not adhere to the substrate W. The gas injection head 200 can be made smaller than the diameter of the substrate W and needs to be neither retracted from the substrate surface nor rotated, wherefore an apparatus can be miniaturized.

Abstract: A method of controlling surface non-uniformity of a wafer in a polishing operation includes (a) providing a model for a wafer polishing that defines a plurality of regions on a wafer and identifies a wafer material removal rate in a polishing step of a polishing process for each of the regions, wherein the polishing process comprises a plurality of polishing steps, (b) polishing a wafer using a first polishing recipe based upon an incoming wafer thickness profile, (c) determining a wafer thickness profile for the post-polished wafer of step (b), and (d) calculating an updated polishing recipe based upon the wafer thickness profile of step (c) and the model of step (a) to maintain a target wafer thickness profile. The model can information about the tool state to improve the model quality. The method can be used to provide feedback to a plurality of platen stations.

Abstract: Provided is an apparatus and a method for heating fluid in a proximity head. A fluid source supplies fluid to a channel within the proximity head. The fluid flows in the channel, through the proximity head, to an outlet port located on a bottom surface of the proximity head. Further, within the proximity head is a heating portion that heats the fluid. Various methods can heat the fluid in the heating portion. For example, the fluid can be heated via resistive heating and heat exchange. However, any mechanism for heating fluid in the proximity head is possible. After heating the fluid, the proximity head delivers the heated fluid through the outlet port to a surface of a semiconductor wafer. An inlet port proximately disposed near the outlet port vacuums the heated fluid to remove the heated fluid from the surface of the semiconductor wafer.

Abstract: A CVD device has a reaction furnace (39) for processing a wafer (1); a seal cap (20) for sealing the reaction furnace (39) hermetically; an isolation flange (42) opposite to the seal cap (20); a small chamber (43) formed by the seal cap (20), the isolation flange (42), and the wall surface in the reaction furnace (39); a feed pipe (19b) for supplying a first gas to the small chamber (43); an outflow passage (42a) provided in the small chamber (43) for allowing the first gas to flow into the reaction furnace (39); and a feed pipe (19a) provided downstream from the outflow passage (42a) for supplying a second gas into the reaction furnace (39). Byproducts such as NH4Cl are prevented from adhering to low temperature sections such as the furnace opening and therefore the semiconductor device production yield is therefore increased.

Abstract: The invention provides a plasma processing apparatus capable of minimizing the non-uniformity of potential distribution around wafer circumference, and providing a uniform process across the wafer surface. The apparatus is equipped with a focus ring formed of a dielectric, a conductor or a semiconductor and having RF applied thereto, the design of which is optimized for processing based on a design technique clarifying physical conditions for flattening a sheath-plasma interface above a wafer and the sheath-plasma interface above the focus ring. A surface voltage of the focus ring is determined to be not less than a minimum voltage for preventing reaction products caused by wafer processing from depositing thereon.

Abstract: A chemical treatment apparatus includes an outer bath; an inner bath, located inside the outer bath; a circulation system, connecting the outer bath to the inner bath; and a draining system, having a first draining pipe and a connecting pipe, wherein the connecting pipe connects the first draining pipe to the circulation system. The suction force generated by a pump of the circulation system is thereby transferred to the first draining pipe. Therefore when the chemical solution is to be drained out from the inner bath, the draining of the chemical solution into the first draining pipe can be quickly done with the aid of the suction force.

Abstract: Of process steps of polymer removal in a substrate processing apparatus (3), in a step of discharging and spreading a removal solution to coat a rotating substrate (W), data indicative of the number of revolutions of a substrate, the temperature and flow rate of a removal solution, and removal solution discharge time is collected and a combination thereof is synthetically assessed to detect a processing abnormality. In a pure water discharge step, data indicative of the number of revolutions of a substrate, the flow rate of pure water and pure water discharge time is collected and a combination thereof synthetically assessed to detect a processing abnormality. Thus, a processing abnormality in polymer removal is detected based on a combination of important control elements in important steps largely exerting influence on the results of processing, thereby allowing detection of a processing abnormality with a higher degree of accuracy.

Abstract: An apparatus for control of a temperature of a substrate has a temperature-controlled base, a heater, a metal plate, a layer of dielectric material. The heater is thermally coupled to an underside of the metal plate while being electrically insulated from the metal plate. A first layer of adhesive material bonds the metal plate and the heater to the top surface of the temperature controlled base. This adhesive layer is mechanically flexible, and possesses physical properties designed to balance the thermal energy of the heaters and an external process to provide a desired temperature pattern on the surface of the apparatus. A second layer of adhesive material bonds the layer of dielectric material to a top surface of the metal plate. This second adhesive layer possesses physical properties designed to transfer the desired temperature pattern to the surface of the apparatus. The layer of dielectric material forms an electrostatic clamping mechanism and supports the substrate.

Abstract: A liquid processing apparatus is arranged to planarize a film on a substrate by supplying onto the film a process liquid for dissolving the film while rotating the substrate. The apparatus includes a substrate holding member configured to rotatably hold the substrate in a horizontal state, a rotation mechanism configured to rotate the substrate holding member, and a liquid supply mechanism configured to supply the process liquid onto a surface of the substrate. The liquid supply mechanism includes first and second liquid delivery nozzles configured to deliver the same process liquid. The first liquid delivery nozzle has a smaller diameter and provides a smaller delivery flow rate, as compared to the second liquid delivery nozzle. The first liquid delivery nozzle is inclined to deliver the process liquid in a rotational direction of the substrate, and is movable between a center of the substrate and a peripheral edge thereof.

Abstract: The present invention generally provides a high efficiency electrostatic chuck for holding a substrate in a processing volume. The high efficiency electrostatic chuck includes an electrode embedded within a high-purity, thermoplastic member. In particular, the high-purity, thermoplastic member may include a high-purity, polyaryletherketone having an extremely low level of metallic ions present therein. The high-purity, polyaryletherketone has excellent wear resistance, high temperature resistance, plasma resistance, corrosive chemical resistance, electrical stability, and strength as compared to polyimide films used in electrostatic chucks. The present invention also provides a simplified method of manufacturing the high efficiency electrostatic chuck.

Abstract: A substrate processing apparatus discharges a hydrofluoric acid solution from discharge nozzles toward grooves formed in side walls of an inner bath. The hydrofluoric acid solution discharged from the discharge nozzles impinges upon the grooves to diffuse, thereby moving toward a top portion of the inner bath in the form of low-speed uniform liquid flows. Thus, a metal component and foreign substances generated in the inner bath float up toward the top portion of the inner bath without being agitated within the inner bath, and are rapidly drained to an outer bath together with the hydrofluoric acid solution.

Abstract: A CVD device has a reaction furnace (39) for processing a wafer (1); a seal cap (20) for sealing the reaction furnace (39) hermetically; an isolation flange (42) opposite to the seal cap (20); a small chamber (43) formed by the seal cap (20), the isolation flange (42), and the wall surface in the reaction furnace (39); a feed pipe (19b) for supplying a first gas to the small chamber (43); an outflow passage (42a) provided in the small chamber (43) for allowing the first gas to flow into the reaction furnace (39); and a feed pipe (19a) provided downstream from the outflow passage (42a) for supplying a second gas into the reaction furnace (39). Byproducts such as NH4Cl are prevented from adhering to low temperature sections such as the furnace opening and therefore the semiconductor device production yield is therefore increased.