Abstract: Methods of wetting a semiconductor substrate may include forming a controlled atmosphere in a processing chamber housing the semiconductor substrate. The semiconductor substrate may define a plurality of features, which may include vias. The methods may include flowing a wetting agent into the processing chamber. A chamber pressure may be maintained below about 100 kPa. The methods may also include wetting the plurality of features defined in the substrate.

Abstract: Methods of wetting a semiconductor substrate may include forming a controlled atmosphere in a processing chamber housing the semiconductor substrate. The semiconductor substrate may define a plurality of features, which may include vias. The methods may include flowing a wetting agent into the processing chamber. A chamber pressure may be maintained below about 100 kPa. The methods may also include wetting the plurality of features defined in the substrate.

Abstract: A system for processing a workpiece includes a base having a bowl or recess for holding a processing fluid. A sonic energy source, such as a megasonic transducer, provides sonic energy into a processing fluid in the bowl. A process head holds a workpiece. A process head lifter lowers the head holding the workpiece into the processing fluid in the bowl. Sonic energy is provided to the workpiece through the processing fluid, optionally while the processing head spins the workpiece. The processing fluid may include de-ionized water and an etchant.

Abstract: A workpiece processor has a process chamber for holding a liquid. A sonic element, such as a megasonic transducer, is positioned to provide sonic energy into the liquid. A workpiece holder is moveable from a first position, wherein a workpiece is held immersed in the liquid, for sonic processing, to a second position where the workpiece is generally aligned with spray nozzles. Process liquids and gases may be sprayed or otherwise provided onto the workpiece, optionally while the workpiece is rotating within the process chamber. A process chamber gas or vapor exhaust assembly prevents escape of process gases or vapors from the processor. The processor can provide both sonic processing, as well as liquid and/or gas chemical processing.

Abstract: In methods and apparatus for cleaning a wafer, a cleaning liquid is sprayed or jetted in a direction generally tangent to the circular edge of a spinning wafer. This enhances removal of contaminants from areas near the edge. Re-deposition of contaminant pieces or particles back onto the wafer is reduced because the direction of the spray carries the contaminant off of the wafer. Insoluble contaminant films, such as post etch residue, may be removed via one or more of the pressure of the cleaning liquid, the effects of higher process temperatures from heating the cleaning liquid, and by the chemical composition of the cleaning liquid.

Abstract: A workpiece support apparatus for use in a process vessel and process system for treating semiconductor workpieces. The process vessel is to be utilized in an integrated tool for wet chemical treatment of a semiconductor workpiece. The workpiece support apparatus includes a rotor having a central cavity and guide pins mounted at an outer perimeter. A workpiece support having extendable workpiece support fingers is connected to the rotor. The extendable workpiece support fingers are moveable from a first position to a second position. A bellows seal connects the workpiece support to the rotor. A fluid delivery tube is positioned in the central cavity of the rotor and connected to a supply of fluid.

Abstract: A method and apparatus for processing a microelectronic workpiece using metrology. The apparatus can include one or more processing or transport units, a metrology unit, and a control unit coupled to the metrology unit and at least one of the processing or transport units. The control unit can modify a process recipe or a process sequence of the processing unit based on a feed forward or a feed back signal from the metrology unit. The control unit can also provide instructions to the transport unit to move the workpiece to a selected processing unit. The processing unit can include, inter alia, a seed layer deposition unit, a process layer electrochemical deposition unit, a seed layer enhancement unit, a chemical mechanical polishing unit, and/or an annealing chamber arranged for sequential processing of a workpiece. The processing units can be controlled as an integrated system using one or more metrology units, or a separate metrology unit can provide input to the processing units.

Abstract: In a method for cleaning a wafer, the wafer is placed a processing chamber. A layer or film of liquid is provided on the wafer. Electrically charged aerosol droplets of a liquid are formed and directed to the workpiece. The charged aerosol particles accumulate on the workpiece. This creates an electrical charge on the workpiece. Contaminant particles on the workpiece are released and/or repelled by the electrical charge and are carried away in the liquid layer. The liquid layer is optionally continuously replenished with fresh liquid. The liquid layer may be thinned out in a localized aerosol impingement area, via a jet of gas, to allow the electrical charge of the aerosol to better collect on or near the surface of the workpiece.

Abstract: A method for rinsing and drying a workpiece includes placing the workpiece into a chamber and spinning the workpiece. A rinsing fluid, such as water, is applied onto the workpiece through a first outlet in the chamber, with the rinsing fluid moving outwardly towards the edge of the workpiece via centrifugal force, to rinse the workpiece. A drying fluid, such as an alcohol vapor, is applied onto the workpiece through the first outlet, with the drying fluid moving outwardly towards the edge of the workpiece via centrifugal force, to dry the workpiece. The drying fluid advantageously follows a meniscus of the rinsing fluid across the workpiece surface. The rinsing fluid, or the drying fluid, or both fluids, may be applied near or at a central area of the workpiece.

Abstract: In a process for removing etch residue, liquid including an acid and an oxidizer is applied to the back side and peripheral edge of a wafer. The front or device side of the wafer is left unprocessed, or may be exposed to an inert fluid such as a purge gas (e.g., nitrogen or helium), to a rinse such as deionized water, or to another processing fluid such as a more highly diluted etchant. The front side of the wafer is either left unprocessed, or is processed to a lesser degree without damage to the underlying devices, metal interconnects or semiconductor layers.

Abstract: A processing fluid is selectively applied or excluded from an outer peripheral margin of the front side, back side, or both sides of a workpiece. Exclusion and/or application of the processing fluid occurs by applying one or more processing fluids to the workpiece as the workpiece is spinning. The flow rate of the one or more processing fluids, fluid pressure, and/or spin rate are used to control the extent to which the processing fluid is selectively applied or excluded from the outer peripheral margin.

Abstract: A system for processing semiconductor wafers has process units on a deck of a frame. The process units and the deck have precision locating features, such as tapered pins, for precisely positioning the process units on the deck. Process units can be removed and replacement process units installed on the deck, without the need for recalibrating the load/unload robot. This reduces the time needed to replace process units and restart processing operations. Liquid chemical consumption during processing is reduced by drawing unused liquid out of supply lines and pumping it back to storage.

Abstract: In a process for removing an anti-reflective coating, a workpiece such as a semiconductor wafer is placed in a support in a process chamber. A heated liquid including a halogenated additive is applied onto the workpiece, forming a liquid layer on the workpiece. The thickness of the liquid layer is controlled. Ozone is introduced into the process chamber by injection into the liquid or directly into the process chamber. Ozone oxidizes and removes the film on the workpiece. The methods are especially useful for anti-reflective coating or sacrificial light absorbing layers.

Abstract: An apparatus for processing a semiconductor wafer or similar article includes a reactor having a processing chamber formed by upper and lower rotors. The wafer is supported between the rotors. The rotors are rotated by a spin motor. A processing fluid is introduced onto the top or bottom surface of the wafer, or onto both surfaces, at a central location. The fluid flows outwardly uniformly and in all directions. A wafer support automatically lifts the wafer, so that it can be removed from the reactor by a robot, when the rotors separate from each other after processing.

Abstract: In a process for treating a workpiece such as a semiconductor wafer, a processing fluid is selectively applied or excluded from an outer peripheral-margin of at least one of the front or back sides of the workpiece. Exclusion and/or application of the processing fluid occurs by applying one or more processing fluids to the workpiece while the workpiece and a reactor holding the workpiece are spinning. The flow rate of the processing fluids, fluid pressure, and/or spin rate are used to control the extent to which the processing fluid is selectively applied or excluded from the outer peripheral margin.

Abstract: An apparatus for processing a semiconductor wafer or similar article includes a reactor having a processing chamber formed by upper and lower rotors. The wafer is supported between the rotors. The rotors are rotated by a spin motor. A processing fluid is introduced onto the top or bottom surface of the wafer, or onto both surfaces, at a central location. The fluid flows outwardly uniformly and in all directions. A wafer support automatically lifts the wafer, so that it can be removed from the reactor by a robot, when the rotors separate from each other after processing.

Abstract: A process system for processing a semiconductor wafer or other similar flat workpiece has a head including a workpiece holder. A motor in the head spins the workpiece. A head lifter lowers the head to move the workpiece into a bath of liquid in a bowl. Sonic energy is introduced into the liquid and travels through the liquid to the workpiece, to assist in processing. The head is lifted to bring the workpiece to a rinse position. The bath liquid is drained. The workpiece is rinsed via radial spray nozzles in the base. The head is lifted to a dry position. A reciprocating swing arm sprays a drying fluid onto the bottom surface of the spinning wafer, to dry the wafer.

Abstract: A system for processing semiconductor wafers has process units on a deck of a frame. The process units and the deck have precision locating features, such as tapered pins, for precisely positioning the process units on the deck. Process units can be removed and replacement process units installed on the deck, without the need for recalibrating the load/unload robot. This reduces the time needed to replace process units and restart processing operations. Liquid chemical consumption during processing is reduced by drawing unused liquid out of supply lines and pumping it back to storage.

Abstract: A method for processing a semiconductor wafer or similar article includes the step of spinning the wafer and applying a fluid to a first side of the wafer, while it is spinning. The fluid flows radially outwardly in all directions, over the first side of the wafer, via centrifugal force. As the fluid flows off of the circumferential edge of the wafer, it is contained in an annular reservoir, so that the fluid also flows onto an outer annular area of the second side of the wafer. An opening allows fluid to flow out of the reservoir. The opening defines the location of a parting line beyond which the fluid will not travel on the second side of the wafer. An apparatus for processing a semiconductor wafer or similar article includes a reactor having a processing chamber formed by upper and lower rotors. The wafer is supported between the rotors. The rotors are rotated by a spin motor. A processing fluid is introduced onto the top or bottom surface of the wafer, or onto both surfaces, at a central location.

Abstract: A process system for processing a semiconductor wafer or other similar flat workpiece has a head including a workpiece holder. A motor in the head spins the workpiece. A head lifter lowers the head to move the workpiece into a bath of liquid in a bowl. Sonic energy is introduced into the liquid and travels through the liquid to the workpiece, to assist in processing. The head is lifted to bring the workpiece to a rinse position. The bath liquid is drained. The workpiece is rinsed via radial spray nozzles in the base. The head is lifted to a dry position. A reciprocating swing arm sprays a drying fluid onto the bottom surface of the spinning wafer, to dry the wafer.