Abstract: Device for processing a substrate are described herein. An apparatus for controlling deposition on a substrate can include a chamber comprising a shadow frame support, a substrate support comprising a substrate supporting surface, a shadow frame with a shadow frame body including a first support surface, a second support surface opposite the first surface, and a detachable lip connected with the shadow frame body. The detachable lip can include a support connection, a first lip surface facing the substrate, a second lip surface opposite the first lip surface, a first edge positioned over the first support surface, and a second edge opposite the first edge to contact the substrate.

Abstract: Embodiments of the present invention generally relates to substrate supports for use in a plasma processing chamber. The substrate supports, which are metallic, have ceramic inserts to prevent arcing between the substrate support and the shadow frame used to protect the edges of the substrate support during processing. In large area substrate processing chambers, the shadow frame may comprise multiple pieces. The individual pieces may be coupled together, but spaced slightly apart by a gap to permit thermal expansion. Ceramic inserts are positioned on the substrate support so that when a shadow frame is positioned adjacent thereto, the ceramic inserts are located adjacent the gaps in the shadow frame. The ceramic inserts adjacent the gap prevent and/or reduce the arcing because the gaps are located over electrically insulating material rather than electrically conductive material.

Abstract: The present invention generally includes a coupling between components. When igniting a plasma remote from a processing chamber, the reactive gas ions may travel to the processing chamber through numerous components. The reactive gas ions may be quite hot and cause the various components to become very hot and thus, the seals between apparatus components may fail. Therefore, it may be beneficial to cool any metallic components through which the reactive gas ions may travel. However, at the interface between the cooled metallic component and a ceramic component, the ceramic component may experience a temperature gradient sufficient to crack the ceramic material due to the heat of the reactive gas ions and the coolness of the metallic component. Therefore, extending a flange of the metallic component into the ceramic component may lessen the temperature gradient at the interface and reduce cracking of the ceramic component.

Abstract: Embodiments of the present invention generally relate to a TFT and a method for its fabrication. The TFT disclosed herein is a silicon based TFT in which the active channel comprises amorphous silicon. Over the amorphous silicon, multiple layers of doped silicon are deposited in which the resistivity of the doped silicon layers is higher at the interface with the amorphous silicon layer as compared to the interface with the source and drain electrodes. Alternatively, a single doped silicon layer is deposited over the amorphous silicon in which the properties of the single doped layer change throughout the thickness. It is better to have a lower resistivity at the interface with the source and drain electrodes, but lower resistivity usually means less substrate throughput. By utilizing multiple or graded layers, low resistivity can be achieved. The embodiments disclosed herein include low resistivity without sacrificing substrate throughput.

Abstract: The present invention generally comprises an RF shutter assembly for use in a plasma processing apparatus. The RF shutter assembly may reduce the amount of plasma creep below the substrate and shadow frame during processing, thereby reducing the amount of deposition that occurs on undesired surfaces. By reducing the amount of deposition on undesired surfaces, particle flaking and thus, substrate contamination may be reduced.

Abstract: Embodiments of the present invention provide methods for depositing a nitrogen-containing material on large-sized substrates disposed in a processing chamber. In one embodiment, a method includes processing a batch of substrates within a processing chamber to deposit a nitrogen-containing material on a substrate from the batch of substrates, and performing a seasoning process at predetermined intervals during processing the batch of substrates to deposit a conductive seasoning layer over a surface of a chamber component disposed in the processing chamber. The chamber component may include a gas distribution plate fabricated from a bare aluminum without anodizing. In one example, the conductive seasoning layer may include amorphous silicon, doped amorphous silicon, doped silicon, doped polysilicon, doped silicon carbide, or the like.

Abstract: Embodiments of the invention generally include shield frame assembly for use with a showerhead assembly, and a showerhead assembly having a shield frame assembly that includes an insulator that tightly fits around the perimeter of a showerhead in a vacuum processing chamber. In one embodiment, a showerhead assembly includes a gas distribution plate and a multi-piece frame assembly that circumscribes a perimeter edge of the gas distribution plate. The multi-piece frame assembly allows for expansion of the gas distribution plate without creating gaps which may lead to arcing. In other embodiments, the insulator is positioned to be have the electric fields concentrated at the perimeter of the gas distribution plate located therein, thereby reducing arcing potential.

Abstract: Embodiments of the present invention generally relate to a TFT and a method for its fabrication. The TFT disclosed herein is a silicon based TFT in which the active channel comprises amorphous silicon. Over the amorphous silicon, multiple layers of doped silicon are deposited in which the resistivity of the doped silicon layers is higher at the interface with the amorphous silicon layer as compared to the interface with the source and drain electrodes. Alternatively, a single doped silicon layer is deposited over the amorphous silicon in which the properties of the single doped layer change throughout the thickness. It is better to have a lower resistivity at the interface with the source and drain electrodes, but lower resistivity usually means less substrate throughput. By utilizing multiple or graded layers, low resistivity can be achieved. The embodiments disclosed herein include low resistivity without sacrificing substrate throughput.

Abstract: An asymmetrically grounded susceptor used in a plasma processing chamber for chemical vapor deposition onto large rectangular panels supported on and grounded by the susceptor. A plurality of grounding straps are connected between the periphery of the susceptor to the grounded vacuum chamber to shorten the grounding paths for RF electrons. Flexible straps allow the susceptor to vertically move. The straps provide a conductance to ground which is asymmetric around the periphery. The straps may be evenly spaced but have different thicknesses or different shapes or be removed from available grounding point and hence provide different RF conductances. The asymmetry is selected to improve the deposition uniformity and other qualities of the PECVD deposited film.

Abstract: A method and apparatus is provided for controlling the etch profile of a multilayer layer stack by depositing a first and second material layer with differential etch rates in the same or different processing chamber.

Abstract: An asymmetrically grounded susceptor used in a plasma processing chamber for chemical vapor deposition onto large rectangular panels supported on and grounded by the susceptor. A plurality of grounding straps are connected between the periphery of the susceptor to the grounded vacuum chamber to shorten the grounding paths for RF electrons. Flexible straps allow the susceptor to vertically move. The straps provide a conductance to ground which is asymmetric around the periphery. The straps may be evenly spaced but have different thicknesses or different shapes or be removed from available grounding point and hence provide different RF conductances. The asymmetry is selected to improve the deposition uniformity and other qualities of the PECVD deposited film.

Abstract: Embodiments of the present invention generally relate to a gas distribution showerhead having insulated corner regions to reduce arcing and improve deposition uniformity control. In one embodiment, the gas distribution showerhead is formed of a conductive material with material from the corner regions removed. Corner members formed substantially in the shape of the removed portion of corner regions are attached to the conductive showerhead. The corner members may be made of a material having electrical insulating properties, such as a ceramic or insulating polymer.

Abstract: A method and apparatus for reducing arcing in a plasma processing system when processing large area substrates which contain one or more holes. In one embodiment of the invention, a substrate support member includes an electrically insulating insert located beneath a hole in an insulating, large area substrate. The insulating insert is made of aluminum oxide, and is located within a hole in the support member such that the insert is disposed beneath a hole in a glass substrate. The substrate support member is made of aluminum with an anodized surface.

Abstract: We have a method of improving the deposition rate uniformity of the chemical vapor deposition (CVD) of films when a number of substrates are processed in series, sequentially in a deposition chamber. The method includes the plasma pre-heating of at least one processing volume structure within the processing volume which surrounds the substrate when the substrate is present in the deposition chamber. We also have a device-controlled method which adjusts the deposition time for a few substrates at the beginning of the processing of a number of substrates in series, sequentially in a deposition chamber, so that the deposited film thickness remains essentially constant during processing of the series of substrates. A combination of these methods into a single method provides the best overall results in terms of controlling average film thickness from substrate to substrate.

Abstract: We have a method of improving the deposition rate uniformity of the chemical vapor deposition (CVD) of films when a number of substrates are processed in series, sequentially in a deposition chamber. The method includes the plasma pre-heating of at least one processing volume structure within the processing volume which surrounds the substrate when the substrate is present in the deposition chamber. We also have a device-controlled method which adjusts the deposition time for a few substrates at the beginning of the processing of a number of substrates in series, sequentially in a deposition chamber, so that the deposited film thickness remains essentially constant during processing of the series of substrates. A combination of these methods into a single method provides the best overall results in terms of controlling average film thickness from substrate to substrate.

Abstract: Embodiments disclosed herein generally relate to an apparatus having an anodized gas distribution showerhead. In large area, parallel plate RF processing chambers, mastering the RF return path can be challenging. Arcing is a frequent problem encountered in RF processing chambers. To reduce arcing in RF processing chambers, straps may be coupled to the susceptor to shorten the RF return path, a ceramic or insulating or anodized shadow frame may be coupled to the susceptor during processing, and an anodized coating may be deposited onto the edge of the showerhead that is nearest the chamber walls. The anodized coating may reduce arcing between the showerhead and the chamber walls and therefore enhance film properties and increase deposition rate.

Abstract: A method and apparatus for providing an electrically symmetrical ground or return path for electrical current between two electrodes is described. The apparatus includes at least on radio frequency (RF) device coupled to one of the electrodes and between a sidewall and/or a bottom of a processing chamber. The method includes moving one electrode relative to another and realizing a ground return path based on the position of the displaced electrode using one or both of a RF device coupled to a sidewall and the electrode, a RF device coupled to a bottom of the chamber and the electrode, or a combination thereof.

Abstract: Embodiments disclosed herein generally include methods of ensuring uniform deposition on a substrate. The smallest gap between a portion of the substrate and the substrate support upon which the substrate rests may lead to uneven deposition of material or ‘thin spots’ on the substrate. Large area substrates, due to their size, are susceptible to numerous gaps at random locations. By inducing an electrostatic charge on the substrate prior to placing the substrate onto the substrate support, the substrate may be placed generally flush against the substrate support. The electrostatic charge on the substrate creates an attraction between the substrate and substrate support to pull substantially the entire surface of the substrate into contact with the substrate support. Material may then be substantially uniformly deposited on the substrate while reducing ‘thin spots’.