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: The present invention generally relates to a method of manufacturing a TFT. The TFT has an active channel that comprises IGZO or zinc oxide. After the source and drain electrodes are formed, but before the passivation layers or etch stop layers are deposited thereover, the active channel is exposed to an N2O or O2 plasma. The interface between the active channel and the passivation layers or etch stop layers are either altered or damaged during formation of the source and drain electrodes. The N2O or O2 plasma alters and repairs the interface between the active channel and the passivation or etch stop layers.

Abstract: Embodiments of the present disclosure generally relate to methods and devices for use of low temperature polysilicon (LTPS) thin film transistors in liquid crystal display (LCD) and organic light-emitting diode (OLED) displays.

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: The present invention generally relates to a method of manufacturing a TFT. The TFT has an active channel that comprises IGZO or zinc oxide. After the source and drain electrodes are formed, but before the passivation layers or etch stop layers are deposited thereover, the active channel is exposed to an N2O or O2 plasma. The interface between the active channel and the passivation layers or etch stop layers are either altered or damaged during formation of the source and drain electrodes. The N2O or O2 plasma alters and repairs the interface between the active channel and the passivation or etch stop layers.

Abstract: Embodiments of the present disclosure generally relate to methods and devices for use of low temperature polysilicon (LTPS) thin film transistors in liquid crystal display (LCD) and organic light-emitting diode (OLED) displays.

Abstract: Techniques are disclosed for methods of post-treating an etch stop or a passivation layer in a thin film transistor to increase the stability behavior of the thin film transistor.

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: 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: The present invention generally relates to methods measuring pinhole determination. In one aspect, a method of measuring pinholes in a stack, such as a TFT stack, is provided. The method can include forming an active layer on a deposition surface of a substrate, forming a dielectric layer over the active layer, delivering an etchant to at least the dielectric layer, to etch both the dielectric layer and any pinholes formed therein and optically measuring the pinhole density of the etched dielectric layer using the active layer.

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: A metal oxide thin film transistor incorporating reduced hydrogen silicon-containing layers and methods of making the same are disclosed herein. The thin film transistor can include a substrate, a metal oxide semiconductor layer, a substantially hydrogen free channel interface layer and a cap layer comprising silicon formed over the channel interface layer. The method for making a thin film transistor can include depositing a metal oxide semiconductor layer over a substrate, activating a deposition gas comprising SiF4 to create an activated deposition gas, delivering the activated deposition gas to the substrate to deposit a channel interface layer comprising SiOF and depositing a cap layer over the channel interface layer and the metal oxide thin film transistor layer.

Abstract: Methods for processing a substrate are described herein. Methods can include positioning a substrate in a processing chamber, maintaining the processing chamber at a temperature below 400° C., flowing a reactant gas comprising either a silicon hydride or a silicon halide and an oxidizing precursor into the process chamber, applying a microwave power to create a microwave plasma from the reactant gas, and depositing a silicon oxide layer on at least a portion of the exposed surface of a substrate.

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: The present invention generally relates to TFTs and methods for fabricating TFTs. When multiple layers are used for the semiconductor material in a TFT, a negative Vth shift may result. By exposing the semiconductor layer to an oxygen containing plasma and/or forming an etch stop layer thereover, the negative Vth shift may be negated.

Abstract: The present invention generally relates to methods measuring pinhole determination. In one aspect, a method of measuring pinholes in a stack, such as a TFT stack, is provided. The method can include forming an active layer on a deposition surface of a substrate, forming a dielectric layer over the active layer, delivering an etchant to at least the dielectric layer, to etch both the dielectric layer and any pinholes formed therein and optically measuring the pinhole density of the etched dielectric layer using the active layer.

Abstract: The present invention generally relates to a sputtering target comprised of zinc and a dopant. Zinc is utilized for metal oxide semiconductor materials, such as IGZO, zinc oxide and zinc oxynitride. The zinc may be delivered by sputtering a zinc target in a desired atmosphere. If a pure zinc sputtering target is used, a stable film cannot be produced unless mobility is sacrificed to below 10 cm2/V-s. By adding a dopant, such as gallium, not only can a stable film be deposited, but the film will have a mobility of greater than 30 cm2/V-s. The dopant can be incorporated directly into the zinc or as a separate sputtering target directly adjacent the zinc sputtering target.

Abstract: Methods for processing a substrate are described herein. Methods can include positioning a substrate in a processing chamber, maintaining the processing chamber at a temperature below 400° C., flowing a reactant gas comprising either a silicon hydride or a silicon halide and an oxidizing precursor into the process chamber, applying a microwave power to create a microwave plasma from the reactant gas, and depositing a silicon oxide layer on at least a portion of the exposed surface of a substrate.

Abstract: Embodiments of the disclosure provide methods of fabricating a thin film transistor device with good profile control of peripheral sidewall of an active layer formed in the thin film transistor devices. In one embodiment, a method for manufacturing a thin film transistor device includes providing a substrate having a source-drain metal electrode layer disposed on an active layer formed thereon, wherein the active layer is a metal oxide layer, performing a back-channel-etching process to form a channel in the source-drain metal electrode layer, and performing an active layer patterning process after the back-channel-etching process.

Abstract: The present invention generally comprises a method and an apparatus for guiding the flow of processing gases away from chamber walls and slit valve opening. By controlling the flow path of the process gases within a processing chamber, undesirable deposition upon chamber walls and within slit valve openings may be reduced. By reducing deposition in slit valve openings, flaking may be reduced. By reducing deposition on chamber walls, the time between chamber cleaning may be increased. Thus, guiding the flow of processing gases within the processing chamber may increase substrate throughput.