Abstract: Methods for stabilizing a ceramic contact surface of an electrostatic chuck, wherein the electrostatic chuck can be disposed within a reaction chamber of a semiconductor wafer processing assembly including a radio frequency source and a coolant gas supply are described herein. The method may include: clamping electrostatically a conditioning wafer to the ceramic contact surface of the electrostatic chuck; and cycling an output power of the radio frequency source and an output pressure of the coolant gas supply for multiple hot/cold cycles. Each of the hot/cold cycles includes a hot abrasion state and a cold abrasion state. At the hot abrasion state, the output power of the radio frequency source is relatively high and the output pressure of the coolant gas supply is relatively low to yield a relatively hot conditioning wafer.

Abstract: Methods for stabilizing a ceramic contact surface of an electrostatic chuck, wherein the electrostatic chuck can be disposed within a reaction chamber of a semiconductor wafer processing assembly including a radio frequency source and a coolant gas supply are described herein. The method may include: clamping electrostatically a conditioning wafer to the ceramic contact surface of the electrostatic chuck; and cycling an output power of the radio frequency source and an output pressure of the coolant gas supply for multiple hot/cold cycles. Each of the hot/cold cycles includes a hot abrasion state and a cold abrasion state. At the hot abrasion state, the output power of the radio frequency source is relatively high and the output pressure of the coolant gas supply is relatively low to yield a relatively hot conditioning wafer.

Abstract: A substrate support for a plasma processing chamber has an angled sidewall at an upper periphery thereof. The substrate is surrounded by an edge ring which underlies a substrate supported on an upper substrate support surface of the substrate support during plasma processing. The angled sidewall is the only surface of the substrate support exposed and subject to byproduct deposition during plasma processing. The angled sidewall enhances sputtering rate of the byproduct deposition during an in situ chamber clean process wherein a cleaning gas supplied to the chamber is energized into a plasma state for cleaning the byproduct deposition.

Abstract: A method of fault detection for use in a plasma processing chamber is provided. The method comprises monitoring plasma parameters within a plasma chamber and analyzing the resulting information. Such analysis enables detection of failures and the diagnosis of failure modes in a plasma processing reactor during the course of wafer processing. The method comprises measuring the plasma parameters as a function of time and analyzing the resulting data. The data can be observed, characterized, compared with reference data, digitized, processed, or analyzed in any way to reveal a specific fault. Monitoring can be done with a detector such as a probe, which is preferably maintained within the plasma chamber substantively coplanar with a surface within the chamber, and directly measures net ion flux and other plasma parameters.

Abstract: A method of fault detection for use in a plasma processing chamber is provided. The method comprises monitoring plasma parameters within a plasma chamber with a single planar ion flux (PIF) probe, analyzing the resulting information, measuring the plasma parameters as a function of time and analyzing the resulting data. The data can be observed, characterized, compared with reference data, digitized, processed, or analyzed to reveal a specific fault. The PIF probe is preferably positioned at a grounded surface within the reactor. Chamber faults that can be detected include a build-up of process by-products in the process chamber, a helium leak, a match re-tuning event, a poor stabilization rate, and a loss of plasma confinement.

Abstract: A method of fault detection for use in a plasma processing chamber is provided. The method comprises monitoring plasma parameters within a plasma chamber and analyzing the resulting information. Such analysis enables detection of failures and the diagnosis of failure modes in a plasma processing reactor during the course of wafer processing. The method comprises measuring the plasma parameters as a function of time and analyzing the resulting data. The data can be observed, characterized, compared with reference data, digitized, processed, or analyzed in any way to reveal a specific fault. Monitoring can be done with a detector such as a probe, which is preferably maintained within the plasma chamber substantively coplanar with a surface within the chamber, and directly measures net ion flux and other plasma parameters.