Abstract: A method involving plasma cleaning of deposit residues in process chamber using duo-step wafer-less auto clean method is detailed. Specifically, the method involves cleaning the processing chamber by flowing a first gaseous composition with at least about 75% of fluorine-containing compound of the formula XyFz, into a processing chamber and then forming a first etchant plasma which removes silicon and silicon based byproducts from the interior surfaces of the processing chamber. The method then involves flowing a second gaseous composition into the processing chamber with a composition of at least about 50% O2 and forming a plasma from the second gaseous composition to provide a second etchant plasma which removes carbon and carbon based byproducts from the interior surfaces of the processing chamber. A system configured to execute the two step cleaning process is also provided.

Abstract: Apparatus controls the temperature of a wafer for chemical mechanical polishing operations. A wafer carrier wafer mounting surface positions a wafer adjacent to a thermal energy transfer unit for transferring energy relative to the wafer. A thermal energy detector oriented adjacent to the wafer mounting surface detects the temperature of the wafer. A controller is responsive to the detector for controlling the supply of thermal energy relative to the thermal energy transfer unit. Embodiments include defining separate areas of the wafer, providing separate sections of the thermal energy transfer unit for each separate area, and separately detecting the temperature of each separate area to separately control the supply of thermal energy relative to the thermal energy transfer unit associated with the separate area.

Abstract: A method for reducing wafer damage during an etching process is provided. In one of the many embodiments, the method includes assigning a bias voltage to each of at least one etching process, and generating the assigned bias voltage before initiation of one of the at least one etching process. The method further includes applying the assigned bias voltage to an electrostatic chuck before initiation of one of the at least one etching processes. The assigned bias voltage level reduces wafer arcing.

Abstract: A method and assembly for generating a hydrodynamic air bearing is described, wherein at least one rotor is rotated to force air through channels defined in a platen located adjacent to a linear belt and the forced air is directed to the linear belt. The method includes rotating at least one rotor with a motor such that the rotor forces air through channels defined in a platen, and the air is directed toward a linear belt. The assembly includes a housing in which a platen, rotors, and a bearing plate are located.

Abstract: A method and apparatus is disclosed for polishing a semiconductor wafer. A polishing pad including a first surface and a semiconductor wafer including a second surface are aligned to each other. To allow alignment of an axis of rotation of the surfaces, at least one of the first and second surfaces includes an adjustable axis of rotation. After the axis of rotation of the first and second surfaces is aligned, the adjustable axis of rotation is set, preferably with a magneto-rheological fluid or similarly acting material, to maintain a fixed position. Thereafter, the polishing pad is utilized to polish the semiconductor wafer.

Abstract: A solution for cleaning silicon semiconductors or silicon oxides, and methods for cleaning silicon semiconductors or silicon oxides using the solution, is disclosed. The solution includes hydrogen peroxide, ammonium hydroxide, an alkanolamine, and at least one of a tetraalkylammonium hydroxide, an alkanolamide, an amido-betaine, an ?,?-dihydroxyphenol, a carboxylic acid, a phosphonic acid, a chelating agent or a surfactant. The weight ratio of ammonium hydroxide to peroxide to water is between about 1:1:5 and 1:1-4:50, the weight ratio of ammonium hydroxide to water is between 1:5 and 1:50, and the molar ratio of component A to ammonium hydroxide is between 1:10 and 1:5000 is disclosed.

Abstract: A method for rinsing a semiconductor wafer in a module utilizing a fluid delivery ring is provided. The method includes providing a process bowl having a generally circular shape bottom wall, a sidewall that extends upwardly from the bottom wall to define a cylindrical chamber, and a plurality of channels in the sidewall that extend from the bottom wall to an upper edge of the sidewall. A fluid delivery ring is attached onto the sidewall of the process bowl. Utilizing the process bowl, a plurality of supply tubes is inserted into the fluid delivery ring. The fluid delivery ring has a plurality of ring inlet and outlet pairs and a plurality of respective slots. Fluid is supplied to the supply tubes, and fluid is directed onto a surface of the semiconductor wafer defined within the process bowl.

Abstract: A method for creating semiconductor devices by etching a layer over a wafer is provided. A photoresist layer is provided on a wafer. The photoresist layer is patterned. The wafer is placed in a process chamber. The photoresist is hardened by providing a hardening plasma containing high energy electrons in the process chamber to harden the photoresist layer, wherein the high energy electrons have a density. The layer is etched within the process chamber with an etching plasma, where a density of high energy electrons in the etching plasma is less than the density of high energy electrons in the hardening plasma.

Abstract: A cluster tool includes a transfer chamber connected to a plurality of vacuum chambers. An additional process chamber connected to the transfer chamber includes a high pressure chamber assembly seated on a housing. The high pressure chamber assembly, which is adjustable between an open position and a closed position, includes an upper chamber portion and a lower chamber portion. Hydraulic cylinders mounted on the upper chamber portion and having chamber rods that attach to the lower chamber portion are configured to move the lower chamber relative to the upper chamber portion between the two positions. When the two portions are brought together into the closed, the high pressure chamber assembly forms a high pressure chamber suitable for processing wafers with supercritical CO2. Once the high pressure chamber is formed, a region between lower chamber portion and a housing may be evacuated to form a vacuum chamber outside a portion of the high pressure chamber.

Abstract: A method of forming a dynamic liquid meniscus includes forming a meniscus at a first size, the meniscus being formed between a proximity head and a first surface and changing the meniscus to a second size by modulating a flow through at least one of a set of ports on the proximity head. A system for modulating flow through the ports in a proximity head is also described.

Abstract: An edge wheel for supporting and rotating a disk-shaped substrate includes a wheel body having a peripheral groove configured to support an edge of a substrate and at least one radial channel extending into said wheel body from said peripheral groove. An edge wheel dryer and a method for processing a disk-shaped substrate are also described.

Abstract: A method of determining a parameter of interest during fabrication of a patterned substrate includes illuminating at least a portion of the patterned substrate with a normal incident light beam, obtaining a measured net reflectance spectrum of the portion of the patterned substrate from a normal reflected light beam, calculating a modeled net reflectance spectrum of the portion of the patterned substrate, and determining a set of parameters that provides a close match between the measured net reflectance spectrum and the modeled net reflectance spectrum. The modeled net reflectance spectrum is calculated as a weighted incoherent sum of reflectances from n?1 different regions constituting the portion of the patterned substrate, wherein the reflectance of each of the n different regions is a weighted coherent sum of reflected fields from k?1 laterally-distinct areas constituting the region.

Abstract: An air platen assembly is described and includes a platen that has a plurality of concentric rings. Each of the rings has a plurality of openings in order to provide a cushion of air to a CMP belt. At least one of the rings extends beyond an outer edge of a wafer to be planarized by the CMP belt. A support is attached with the platen and has a plurality of air ports for pressurized air to pass to the rings of the platen. A gasket is positioned between the support and the platen and has a plurality of cutouts that align with the openings and the air ports. A base is also included and supports the support.

Abstract: The present invention is a system for controlling a pad conditioner in a CMP device. The system includes a roughness-sensing device mounted in proximity to a polishing pad. The roughness-sensing device generates an output responsive to a roughness of the polishing pad. A signal-processing unit then generates a roughness value of the polishing pad in response to the output from the roughness-sensing device, and generates a control signal in response to the generated roughness value. Finally, a control device controls motion of the pad conditioner in response to the control signal.

Abstract: A method and apparatus is provided for measuring multiple locations on a wafer for controlling a subsequent semiconductor processing step to achieve greater dimensional uniformity across that wafer. The method and apparatus maps a dimension of a feature at multiple locations to create a dimension map, transforms the dimension map into a processing parameter map, and uses the processing parameter map to tailor the subsequent processing step to that specific wafer. The wafer can also be measured after the processing to compare an actual outcome with the targeted outcome, and the difference can be used to refine the transformation from a dimension map to a processing parameter map for a subsequent wafer.

Abstract: A method for controlling a removal of photoresist material from a semiconductor substrate is provided. The method includes providing the semiconductor substrate having a photoresist mask formed thereon. The method also includes forming a conformal layer of polymer over the photoresist mask and a portion of the semiconductor substrate not covered by the photoresist mask while concurrently removing a portion of the conformal layer of polymer. The thickness of the conformal layer of polymer on each region of the semiconductor substrate is set to vary depending on a removal rate of the conformal layer of polymer in each region of the semiconductor substrate.

Abstract: A platen is provided for use in a chemical mechanical planarization (CMP) system. The platen is provided with diaphragms that overcome a fluid-conservation problem experienced in prior air-bearing platens. The diaphragms enable a removal profile to be manipulated by configuring one or more diaphragms to control localized polishing pressure while capturing free-flowing fluid that is input to the apparatus. The diaphragms also minimize loss of normally-free-flowing fluid from a fluid-bearing.

Abstract: A system for applying a microtopography to a semiconductor wafer (“wafer”) is provided. The system includes a chuck configured to hold and rotate the wafer. The system also includes a grinding wheel disposed over the chuck in a proximately adjustable manner relative to the wafer to be held by the chuck. The grinding wheel is configured to rotate about a central axis of the grinding wheel, wherein the central axis of the grinding wheel is non-parallel to the central axis of the chuck. The grinding wheel is capable of contacting the wafer and removing material from the wafer at the area of contact. Appropriate application of the grinding wheel to the wafer serves to generate a microtopography across the wafer surface. The resulting microtopography can then be planarized more effectively by conventional chemical mechanical planarization methods.

Abstract: An apparatus and method for minimizing the size of agglomerated particles in a polishing fluid is provided. The method includes positioning a polishing pad between a sacrificial member and a support member such that the sacrificial member is in communication with the polishing pad, thereby causing the agglomerated particles to separate. The apparatus includes a polishing pad and a polishing fluid condition. The polishing fluid conditioner includes a sacrificial member and a support member, wherein the sacrificial member is in communication with the polishing pad so as to cause the agglomerated particles to separate.

Abstract: A method for converting a slope based detection task to a threshold based detection task is provided. The method initiates with defining an approximation equation for a set of points corresponding to values of a process being monitored. Then, an expected value at a current point of the process being monitored is predicted. Next, a difference between a measured value at the current point of the process being monitored and the corresponding expected value is calculated. Then, the difference is monitored for successive points to detect a deviation value between the measured value and the expected value. Next, a transition point for the process being monitored is identified based on the detection of the deviation value. A processing system configured to provide real time data for a slope based transition and a computer readable media are also provided.