Abstract: Methods and systems of detection of wafer de-chucking in a semiconductor processing chamber are disclosed. Methods and systems of interdiction are also disclosed to prevent hardware and wafer damage during semiconductor fabrication if and when de-chucking is detected. In one embodiment, a de-chucking detection method is based on measuring change in imaginary impedance of a plasma circuit, along with measuring one or both of reflected RF power and arc count. In another embodiment, a possibility of imminent de-chucking is detected even before complete de-chucking occurs by analyzing the signature change in imaginary impedance.

Abstract: Methods and systems of detection of wafer de-chucking in a semiconductor processing chamber are disclosed. Methods and systems of interdiction are also disclosed to prevent hardware and wafer damage during semiconductor fabrication if and when de-chucking is detected. In one embodiment, a de-chucking detection method is based on measuring change in imaginary impedance of a plasma circuit, along with measuring one or both of reflected RF power and arc count. In another embodiment, a possibility of imminent de-chucking is detected even before complete de-chucking occurs by analyzing the signature change in imaginary impedance.

Abstract: Methods and apparatus for plasma processing are provided herein. For example, apparatus can include a system for plasma processing including a remote plasma source including a supply terminal configured to connect to a power source and an output configured to deliver RF power to a plasma block of the remote plasma source for creating a plasma and a controller configured to control operation of the remote plasma source based on a measured input power at the supply terminal.

Abstract: Methods and apparatus for plasma processing are provided herein. For example, apparatus can include a system for plasma processing including a remote plasma source including a supply terminal configured to connect to a power source and an output configured to deliver RF power to a plasma block of the remote plasma source for creating a plasma and a controller configured to control operation of the remote plasma source based on a measured input power at the supply terminal.

Abstract: Methods and apparatus for processing a substrate are provided herein. For example, apparatus can include a system for processing a substrate, comprising: a remote plasma source including a supply terminal configured to connect to a power source and an output configured to deliver RF power to a plasma block of the remote plasma source for creating a plasma; and a controller connected to the supply terminal of the remote plasma source and configured to determine, based on a predictive model of the remote plasma source, whether a power at the supply terminal is equal to a predetermined threshold during processing of a substrate, wherein the predictive model includes a correlation of remote plasma performance with delivered RF power at the output, and to control the processing of the substrate based on a determination of the predetermined threshold being met to control processing of the substrate.

Abstract: The present disclosure relate to methods and apparatus for temperature sensing and control during substrate processing. Substrate temperatures during processing, which are difficult to measure directly, may be determined by examination of deposited film properties or by measuring changes in power output over time of the substrate heating apparatus. Temperatures are determined for many substrates during processing, showing how substrate temperatures change over time, and the temperature changes are then used to build models via machine learning techniques. The models are used to adjust heating apparatus setpoints for future processing operations.

Abstract: Methods and systems of detection of wafer placement error in a semiconductor processing chamber are disclosed. Methods and systems of interdiction are also disclosed to prevent hardware and wafer damage during semiconductor fabrication if and when a wafer placement error is detected. The method—is based on measuring a slope of current in an electrostatic chuck (ESC), which is correlated to lack of contact between the wafer and the ESC. Wafer placement detection at an early stage, when a heater and an ESC are being set up, gives the option of stopping the process before high power RF plasma is created.

Abstract: Methods and systems of detection of wafer placement error in a semiconductor processing chamber are disclosed. Methods and systems of interdiction are also disclosed to prevent hardware and wafer damage during semiconductor fabrication if and when a wafer placement error is detected. The method-is based on measuring a slope of current in an electrostatic chuck (ESC), which is correlated to lack of contact between the wafer and the ESC. Wafer placement detection at an early stage, when a heater and an ESC are being set up, gives the option of stopping the process before high power RF plasma is created.

Abstract: Methods and systems of detection of wafer de-chucking in a semiconductor processing chamber are disclosed. Methods and systems of interdiction are also disclosed to prevent hardware and wafer damage during semiconductor fabrication if and when de-chucking is detected. In one embodiment, a de-chucking detection method is based on measuring change in imaginary impedance of a plasma circuit, along with measuring one or both of reflected RF power and arc count. In another embodiment, a possibility of imminent de-chucking is detected even before complete de-chucking occurs by analyzing the signature change in imaginary impedance.

Abstract: The present disclosure relate to methods and apparatus for temperature sensing and control during substrate processing. Substrate temperatures during processing, which are difficult to measure directly, may be determined by examination of deposited film properties or by measuring changes in power output over time of the substrate heating apparatus. Temperatures are determined for many substrates during processing, showing how substrate temperatures change over time, and the temperature changes are then used to build models via machine learning techniques. The models are used to adjust heating apparatus setpoints for future processing operations.

Abstract: Embodiments of the invention contemplate the formation of a high efficiency solar cell using a novel processing sequence to form a solar cell device. Methods of forming the high efficiency solar cell may include the use of a prefabricated back plane that is bonded to the metalized solar cell device to form an interconnected solar cell module. Solar cells most likely to benefit from the invention including those having active regions comprising single or multicrystalline silicon with both positive and negative contacts on the rear side of the cell.

Abstract: The present invention is directed to improving defect performance in semiconductor processing systems. In specific embodiments, an apparatus for processing semiconductor substrates comprises a chamber defining a processing region therein, and a substrate support disposed in the chamber to support a semiconductor substrate. At least one nozzle extends into the chamber to introduce a process gas into the chamber through a nozzle opening. The apparatus comprises at least one heat shield, each of which is disposed around at least a portion of one of the at least one nozzle. The heat shield has an extension which projects distally of the nozzle opening of the nozzle and which includes a heat shield opening for the process gas to flow therethrough from the nozzle opening. The heat shield decreases the temperature of nozzle in the processing chamber for introducing process gases therein to reduce particles.

Abstract: Embodiments in accordance with the present invention relate to techniques for enhancing uniformity of plasma-based semiconductor processing. In one technique, the exterior of a plasma-based processing chamber features a series of substantially continuous plates composed of a material exhibiting a low permeability to magnetic fields. This high-? shielding material is utilized to block exposure of a plasma within the chamber to the effects of external magnetic fields. Embodiments in accordance with the present invention are effective to shield plasma-based processing chambers from external magnetic fields originating from adjacent clustered chambers, and/or from the earth's geomagnetic field.

Abstract: The present invention is directed to improving defect performance in semiconductor processing systems. In specific embodiments, an apparatus for processing semiconductor substrates comprises a chamber defining a processing region therein, and a substrate support disposed in the chamber to support a semiconductor substrate. At least one nozzle extends into the chamber to introduce a process gas into the chamber through a nozzle opening. The apparatus comprises at least one heat shield, each of which is disposed around at least a portion of one of the at least one nozzle. The heat shield has an extension which projects distally of the nozzle opening of the nozzle and which includes a heat shield opening for the process gas to flow therethrough from the nozzle opening. The heat shield decreases the temperature of nozzle in the processing chamber for introducing process gases therein to reduce particles.

Abstract: Methods deposit a film on a substrate disposed in a substrate processing chamber. The substrate has a gap formed between adjacent raised surfaces. Flows of first precursor deposition gases are provided to the substrate processing chamber. A first high-density plasma is formed from the flows of first deposition gases to deposit a first portion of the film over the substrate and within the gap with a first deposition process that has simultaneous deposition and sputtering components until after the gap has closed. A sufficient part of the first portion of the film is etched back to reopen the gap. Flows of second precursor deposition gases are provided to the substrate processing chamber. A second high-density plasma is formed from the flows of second precursor deposition gases to deposit a second portion of the film over the substrate and within the reopened gap with a second deposition process that has simultaneous deposition and sputtering components.

Abstract: The present invention is directed to improving defect performance in semiconductor processing systems. In specific embodiments, an apparatus for processing semiconductor substrates comprises a chamber defining a processing region therein, and a substrate support disposed in the chamber to support a semiconductor substrate. At least one nozzle extends into the chamber to introduce a process gas into the chamber through a nozzle opening. The apparatus comprises at least one heat shield, each of which is disposed around at least a portion of one of the at least one nozzle. The heat shield has an extension which projects distally of the nozzle opening of the nozzle and which includes a heat shield opening for the process gas to flow therethrough from the nozzle opening. The heat shield decreases the temperature of nozzle in the processing chamber for introducing process gases therein to reduce particles.

Abstract: Methods are provided for depositing a silicon oxide film on a substrate disposed in a substrate processing chamber. The substrate has a gap formed between adjacent raised surfaces. A process gas having a silicon-containing gas, an oxygen-containing gas, and a fluent gas is flowed into the substrate processing chamber. The fluent gas is introduced into the substrate processing chamber at a flow rate of at least 500 sccm. A plasma is formed having an ion density of at least 1011 ions/cm3 from the process gas to deposit a first portion of the silicon oxide film over the substrate and into the gap. Thereafter, the deposited first portion is exposed to an oxygen plasma having at least 1011 ions/cm3. Thereafter, a second portion of the silicon oxide film is deposited over the substrate and into the gap.

Abstract: A film is deposited over a substrate by flowing a process gas to a process chamber and flowing a fluent gas to the process chamber. The process gas includes a silicon-containing gas and an oxygen-containing gas. The fluent gas includes a flow of helium and a flow of molecular hydrogen, the flow of molecular hydrogen being provided at a flow rate less than 20% of a flow rate of the helium. A plasma is formed in the process chamber with a density greater than 1011 ions/cm3. The film is deposited over the substrate with the plasma.

Abstract: A replaceable gas nozzle is insertable in a gas distributor ring of a substrate processing chamber and that can be shielded within the chamber. The replaceable gas nozzle has a longitudinal ceramic body having a channel to direct the flow of the gas into the chamber. The ceramic body includes a first external thread to mate with the gas distributor ring, and a second external thread to receive a heat shield. The channel has an inlet to receive the gas from the gas distributor ring and a pinhole outlet to release the gas into the chamber. A heat shield can be used to shield the nozzle extending into the chamber. The heat shield has a hollow member configured to be coupled with the nozzle that has an internal dimension sufficiently large to be disposed around at least a portion of the nozzle. The hollow member also has an extension which projects distally of the outlet of the nozzle and a heat shield opening for the process gas to flow therethrough from the nozzle outlet.

Abstract: The present invention is directed to improving defect performance in semiconductor processing systems. In specific embodiments, an apparatus for processing semiconductor substrates comprises a chamber defining a processing region therein, and a substrate support disposed in the chamber to support a semiconductor substrate. At least one nozzle extends into the chamber to introduce a process gas into the chamber through a nozzle opening. The apparatus comprises at least one heat shield, each of which is disposed around at least a portion of one of the at least one nozzle. The heat shield has an extension which projects distally of the nozzle opening of the nozzle and which includes a heat shield opening for the process gas to flow therethrough from the nozzle opening. The heat shield decreases the temperature of nozzle in the processing chamber for introducing process gases therein to reduce particles.