Abstract: The present invention generally relates to TFTs and methods for fabricating TFTs. For either back channel etch TFTs or for etch stop TFTs, multiple layers for the passivation layer or the etch stop layers permits a very dense capping layer to be formed over a less dense back channel protection layer. The capping layer can be sufficiently dense so that few pin holes are present and thus, hydrogen may not pass through to the semiconductor layer. As such, hydrogen containing precursors may be used for the capping layer deposition.

Abstract: Embodiments of gas distribution apparatus comprise a diffuser support member coupled to a diffuser and movably disposed through a backing plate. Embodiments of methods of processing a substrate on a substrate receiving surface of a substrate support comprise providing a diffuser in which a diffuser support member supports the diffuser and is movably disposed through the backing plate.

Abstract: In one embodiment, an electrostatic chuck is provided and includes a backing substrate, and a puck substrate disposed on the backing substrate, the puck substrate comprising a plurality of central chucking modules surrounded by a perimeter chucking module, the perimeter chucking module having a first electrode and a second electrode that are parallel to each other and substantially parallel to sides of the puck substrate.

Abstract: The present disclosure relates to methods and apparatus for an atomic layer deposition (ALD) processing chamber for device fabrication and methods for replacing a gas distribution plate and mask of the same. The ALD processing chamber has a slit valve configured to allow removal and replacement of a gas distribution plate and mask. The ALD processing chamber may also have actuators operable to move the gas distribution plate to and from a process position and a substrate support assembly operable to move the mask to and from a process position.

Abstract: Embodiments of the present disclosure generally provide a method and apparatus for forming an IGZO active layer within a thin film transistor (TFT) device. In one embodiment, a method is provided for forming an IGZO active layer on a dielectric surface using a PECVD deposition process. In one embodiment, a method is provided for pretreating and passivating the dielectric surface for receiving the PECVD formed IGZO layer. In another embodiment, a method is provided for treating a PECVD formed IGZO layer after depositing said layer. In another embodiment, a method is provided for forming a multi-layer or complex layering structure of IGZO, within a PECVD processing chamber, for optimizing TFT electrical characteristics such as carrier density, contact resistance, and gate dielectric interfacial properties. In yet another embodiment, a method is provided for forming integrated layers for a TFT including IGZO within an in-situ environment of a cluster tool.

Abstract: The present disclosure relates to methods and apparatus for a thin film encapsulation (TFE). A process kit for TFE is provided. The process kit is an assembly including a window, a mask parallel to the window, and a frame. The process kit further includes an inlet channel for flowing process gases into the volume between the window and the mask, an outlet channel for pumping effluent gases away from the volume between the window and the mask, and seals for inhibiting the flow of process gases and effluent gases to undesired locations. A method of performing TFE is provided, including placing a substrate under the mask of the above described process kit, flowing process gases into the process kit, and activating some of the process gases into reactive species by means of an energy source within a processing chamber.

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: An electromagnetic mask chuck is described herein. The electromagnetic mask chuck includes a body with a plurality of electromagnets formed therein. The electromagnets can then deliver a magnetic force to a mask to position and hold the mask over or on the substrate for further deposition. The electromagnets are controlled using a power source, to deliver a controlled magnetic field to the mask.

Abstract: A method and apparatus for sealing an opening of a processing chamber are provided. In one embodiment, the invention generally provides a closure member integrated within a wall of a process chamber for sealing an opening within the wall of the chamber. In another embodiment, the invention provides a closure member configured to seal an opening in the wall of a processing chamber from the inside of the chamber.

Abstract: Embodiments of the present invention relates to apparatus and methods for a maskless lithography on a flexible substrate with active alignment. In one embodiment, a lithography apparatus includes a cylindrical roller rotatable about a central axis and configured to transfer a flexible substrate on a cylindrical substrate supporting surface. A plurality of printing units, each includes an image sensing device and an imaging printing device, may be positioned facing the substrate supporting surface. The plurality of printing units may capture images of pre-existing patterns and/or markers on the flexible substrate as the flexible substrate is being tramsferred continiously and exposure patterns for each printing unit may be adjusted “on-the-fly” according to the captured image, thus achieving active alignment.

Abstract: An apparatus for introducing gas into a processing chamber comprising one or more gas distribution tubes having gas-injection holes which may be larger in size, greater in number, and/or spaced closer together at sections of the gas introduction tubes where greater gas conductance through the gas-injection holes is desired. An outside tube having larger gas-injection holes may surround each gas distribution tube. The gas distribution tubes may be fluidically connected to a vacuum foreline to facilitate removal of gas from the gas distribution tube at the end of a process cycle.

Abstract: A substrate carrier adapted to use in a processing system includes an electrode assembly and a support base. The electrode assembly is configured to generate an electrostatic chucking force for securing a substrate to the substrate carrier. The support base has a heating/cooling reservoir formed therein. The electrode assembly and the support base form an unitary body configured for transport within a processing system. A quick disconnect is coupled to the body and configured to trap a heat regulating medium in the reservoir heating/cooling reservoir when the body is decoupled from a source of heat regulating medium.

Abstract: A guided wave applicator comprising two electrically conductive waveguide walls and a waveguide dielectric. The volume of the waveguide dielectric is composed of non-gaseous dielectric material and is positioned between the two waveguide walls. The waveguide dielectric includes first and second longitudinal ends and includes first, second, third and fourth sides extending longitudinally between the two longitudinal ends. The first waveguide wall is positioned so that it covers the first side of the waveguide dielectric, and the second waveguide wall is positioned so that it covers the second side of the waveguide dielectric. In operation, electrical power can be supplied to one or both longitudinal ends of the waveguide dielectric, whereby the power can be coupled to a plasma through the exposed sides of the waveguide dielectric.

Abstract: A substrate carrier adapted to use in a processing system includes an electrode assembly and a support base. The electrode assembly is configured to generate an electrostatic chucking force for securing a substrate to the substrate carrier. The support base has a heating/cooling reservoir formed therein. The electrode assembly and the support base form an unitary body configured for transport within a processing system. A quick disconnect is coupled to the body and configured to trap a heat regulating medium in the reservoir heating/cooling reservoir when the body is decoupled from a source of heat regulating medium.

Abstract: The present invention generally relates to a thin film semiconductor device having a buffer layer formed between the semiconductor layer and one or more layers. In one embodiment, a thin film semiconductor device includes a semiconductor layer having a first work function and a first electron affinity level, a buffer layer having a second work function greater than the first work function and a second electron affinity level that is less than the first electron affinity level; and a gate dielectric layer having a third work function less than the second work function and a third electron affinity level that is greater than the second electron affinity level.

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: The present invention generally relates to a vertical CVD system having a processing chamber that is capable of processing multiple substrates. The multiple substrates are disposed on opposite sides of the processing source within the processing chamber, yet the processing environments are not isolated from each other. The processing source is a horizontally centered vertical plasma generator that permits multiple substrates to be processed simultaneously on either side of the plasma generator, yet independent of each other. The system is arranged as a twin system whereby two identical processing lines, each with their own processing chamber, are arranged adjacent to each other. Multiple robots are used to load and unload the substrates from the processing system. Each robot can access both processing lines within the system.

Abstract: Methods for encapsulating OLED structures disposed on a substrate using a soft/polymer mask technique are provided. The soft/polymer mask technique can efficiently provide a simple and low cost OLED encapsulation method, as compared to convention hard mask patterning techniques. The soft/polymer mask technique can utilize a single polymer mask to complete the entire encapsulation process with low cost and without alignment issues present when using conventional metal masks. Rather than utilizing a soft/polymer mask, the encapsulation layers may be blanked deposited and then laser ablated such that no masks are utilized during the encapsulation process.

Abstract: Embodiments of a gas diffuser plate for distributing gas in a processing chamber are provided. The gas distribution plate includes a diffuser plate having an upstream side and a downstream side, and a plurality of gas passages passing between the upstream and downstream sides of the diffuser plate. The gas passages include hollow cathode cavities at the downstream side to enhance plasma ionization. The depths, the diameters, the surface area and density of hollow cathode cavities of the gas passages that extend to the downstream end can be gradually increased from the center to the edge of the diffuser plate to improve the film thickness and property uniformity across the substrate. The increasing diameters, depths and surface areas from the center to the edge of the diffuser plate can be created by bending the diffuser plate toward downstream side, followed by machining out the convex downstream side. Bending the diffuser plate can be accomplished by a thermal process or a vacuum process.

Abstract: The embodiments described herein generally relate to active alignment of a fine metal mask. The fine metal mask is connected with a frame through a plurality of microactuators. The microactuators can act on the fine metal mask to stretch the mask, reposition the mask or both. In this way, the position and size of the fine metal mask can be maintained in relation to the substrate.