Abstract: Preheat processes for a millisecond anneal system are provided. In one example implementation, a heat treatment process can include receiving a substrate on a wafer support in a processing chamber of a millisecond anneal system; heating the substrate to an intermediate temperature; and heating the substrate using a millisecond heating flash. Prior to heating the substrate to the intermediate temperature, the process can include heating the substrate to a pre-bake temperature for a soak period.

Abstract: Apparatus, systems, and processes for substrate breakage detection in a thermal processing system are provided. In one example implementation, a process can include: accessing data indicative of a plurality of temperature measurements for a substrate, the plurality of measurements obtained during a cool down period of a thermal process; estimating one or more metrics associated with a cooling model based at least in part on the data indicative of the plurality of temperature measurements; and determining a breakage detection signal based at least in part on the one or more metrics associated with the cooling model. The breakage detection signal is indicative of whether the substrate has broken during thermal processing.

Abstract: Processes and apparatuses for the treatment of semiconductor workpieces are provided. In some embodiments, a method can include placing the workpiece in a processing chamber. The processing chamber can be separated from a plasma chamber by a separation grid assembly. The method can include forming a passivation layer on the workpiece in the processing chamber using radicals generated in a first plasma in the plasma chamber. The method can include performing a surface treatment process on the workpiece in the processing chamber using a second plasma generated in the plasma chamber.

Abstract: A method and system for calibrating temperature measurement devices, such as pyrometers, in thermal processing chambers are disclosed. According to the present invention, the system includes a calibrating light source that emits light energy onto a substrate contained in the thermal processing chamber. A light detector then detects the amount of light that is being transmitted through the substrate. The amount of detected light energy is then used to calibrate a temperature measurement device that is used in the system.

Abstract: The plasma reactor of the invention is intended for treating the surfaces of objects such as semiconductor wafers and large display panels, or the like, with plasma. The main part of the plasma reactor is an array of RF antenna cells, which are deeply immersed into the interior of the working chamber. Each antenna cell has a ferromagnetic core with a heat conductor and a coil wound onto the core. The core and coil are sealed in the protective cap. Deep immersion of the antenna cells having the structure of the invention provides high efficiency of plasma excitation, while the arrangement of the plasma cells and possibility of their individual adjustment provide high uniformity of plasma distribution and possibility of adjusting plasma parameters, such as plasma density, in a wide range.

Abstract: Processes for removing a photoresist from a substrate after, for instance, ion implantation are provided. In one example implementation, a process can include placing a substrate having a bulk photoresist and a crust formed on the bulk photoresist in a processing chamber. The process can include initiating a first strip process in the processing chamber. The process can include accessing an optical emission signal associated with a plasma during the first strip process. The process can include identifying an endpoint for the first strip process based at least in part on the optical emission signal. The process can include terminating the first strip process based at least in part on the endpoint. The process can include initiating a second strip process to remove the photoresist from the substrate.

Abstract: Systems and methods for protecting vacuum seals in a plasma processing system are provided. The processing system can include a vacuum chamber defining a sidewall and an inductive coil wrapped around at least a portion of the sidewall. A vacuum seal can be positioned between the sidewall of the vacuum chamber and a heat sink. A thermally conductive bridge can be coupled between the sidewall and heat sink. Further, the thermally conductive bridge can be positioned relative to the vacuum seal such that the thermally conductive bridge redirects a conductive heat path from the sidewall or any heat source to the heat sink so that the heat path bypasses the vacuum seal.

Abstract: A method and apparatus are provided for processing a substrate with a radiofrequency inductive plasma in the manufacture of a device. The inductive plasma is maintained with an inductive plasma applicator having one or more inductive coupling elements. There are thin windows between the inductive coupling elements and the interior of the processing chamber. Various embodiments have magnetic flux concentrators in the inductive coupling element and feed gas holes interspersed among the inductive coupling elements. The thin windows, magnetic flux concentrators, and interspersed feed gas holes are useful to effectuate uniform processing, high power transfer efficiency, and a high degree of coupling between the applicator and plasma. In some embodiments, capacitive current is suppressed using balanced voltage to power an inductive coupling element.

Abstract: Apparatus, systems, and processes for substrate breakage detection in a thermal processing system are provided. In one example implementation, a process can include: accessing data indicative of a plurality of temperature measurements for a substrate, the plurality of measurements obtained during a cool down period of a thermal process; estimating one or more metrics associated with a cooling model based at least in part on the data indicative of the plurality of temperature measurements; and determining a breakage detection signal based at least in part on the one or more metrics associated with the cooling model. The breakage detection signal is indicative of whether the substrate has broken during thermal processing.

Abstract: Plasma processing apparatus and methods are disclosed. Embodiments of the present disclosure include a processing chamber having an interior space operable to receive a process gas, a substrate holder in the interior of the processing chamber operable to hold a substrate, and at least one dielectric window. A metal shield is disposed adjacent the dielectric window. The metal shield can have a peripheral portion and a central portion. The processing apparatus includes a primary inductive element disposed external to the processing chamber adjacent the peripheral portion of the metal shield. The processing apparatus can further include a secondary inductive element disposed between the central portion of the metal shield and the dielectric window. The primary and secondary inductive elements can perform different functions, can have different structural configurations, and can be operated at different frequencies.

Abstract: A customizable chamber spectral response is described which can be used at least to tailor chamber performance for wafer heating, wafer cooling, temperature measurement, and stray light. In one aspect, a system is described for processing a treatment object having a given emission spectrum at a treatment object temperature which causes the treatment object to produce a treatment object radiated energy. The chamber responds in a first way to the heating arrangement radiated energy and in a second way to the treatment object radiated energy that is incident thereon. The chamber may respond in the first way by reflecting the majority of the heat source radiated energy and in the second way by absorbing the majority of the treatment object radiated energy. Different portions of the chamber may be treated with selectively reflectivity based on design considerations to achieve objectives with respect to a particular chamber performance parameter.

Abstract: Apparatuses and methods for supporting a workpiece such as a semiconductor wafer. A support system is configured to support the workpiece while allowing thermally-induced motion of the workpiece, which may include thermal bowing or thermal bending. The system may include a support member having a moveable engagement portion engageable with the workpiece, the engagement portion being moveable to allow the thermally-induced motion of the workpiece while supporting the workpiece. The moveable engagement portion may include a plurality of moveable engagement portions of a plurality of respective support members, which may be resiliently engageable with the workpiece. The support members may include flexible support members each having an unconstrained portion and a constrained portion, and the moveable engagement portions may include the unconstrained portions.

Abstract: As part of a system for processing workpieces, a workpiece support arrangement, separate from a process chamber arrangement supports at least two workpieces at least generally in a stacked relationship to form a workpiece column. A transfer arrangement transports at least two of the workpieces between the workpiece column and the process chamber arrangement by simultaneously moving the two workpieces at least generally along first and second transfer paths, respectively, that are defined between the workpiece column and the first and second process stations. The transfer arrangement can simultaneously move untreated and treated workpieces. Vertical motion swing arms and coaxial swing arms are described. A pair of spaced apart swing arms, the workpiece column and the processing stations can cooperatively define a pentagonal shape. Timing belt backlash elimination, a dual degree of freedom slot valve and low point chamber pumping, for removing chamber contaminants, are also described.

Abstract: A first heat-treating method involves monitoring at least one thermal efficiency parameter associated with an irradiance system configured to produce an irradiance flash incident on a surface of a workpiece, and automatically updating control information used by the irradiance system to produce the irradiance flash, in response to the monitoring of the thermal efficiency parameter. A second method involves predicting a heating effect of an irradiance flash to be incident upon a surface of a workpiece, in response to a measurement of a heating parameter of the surface, and pre-adjusting the irradiance flash, in response to the predicted heating effect. A third method involves measuring a temperature of a surface of a workpiece during an initial portion of an irradiance flash incident on the surface, and controlling a power of a remaining portion of the irradiance flash, in response to the temperature.

Abstract: A method and system for determining a shape of an irradiance pulse to which a semiconductor wafer is to be exposed during a thermal cycle are disclosed. The method includes receiving, with a processor circuit, thermal cycle parameters specifying requirements of the thermal cycle, and determining, with the processor circuit, a shape of a heating portion of the irradiance pulse. Determining includes optimizing at least one parameter of a flux profile model of the heating portion of the irradiance pulse to satisfy the requirements while minimizing frequency-domain energy spectral densities of the flux profile model at resonant frequencies of the wafer, to minimize vibration of the wafer at the resonant frequencies when the wafer is exposed to the irradiance pulse.

Abstract: An apparatus for generating electromagnetic radiation includes an envelope, a vortex generator configured to generate a vortexing flow of liquid along an inside surface of the envelope, first and second electrodes within the envelope configured to generate a plasma arc therebetween, and an insulative housing associated surrounding at least a portion of an electrical connection to one of the electrodes. The apparatus further includes a shielding system configured to block electromagnetic radiation emitted by the arc to prevent the electromagnetic radiation from striking all inner surfaces of the insulative housing. The apparatus further includes a cooling system configured to cool the shielding system.

Abstract: Systems and methods for protecting vacuum seals in a plasma processing system are provided. The processing system can include a vacuum chamber defining a sidewall and an inductive coil wrapped around at least a portion of the sidewall. A vacuum seal can be positioned between the sidewall of the vacuum chamber and a heat sink. A thermally conductive bridge can be coupled between the sidewall and heat sink. Further, the thermally conductive bridge can be positioned relative to the vacuum seal such that the thermally conductive bridge redirects a conductive heat path from the sidewall or any heat source to the heat sink so that the heat path bypasses the vacuum seal.

Abstract: A plasma reactor and method for improved gas injection for an inductive plasma source for dry strip plasma processing are disclosed. According to embodiments of the present disclosure, gas is fed into a plasma chamber through a gas injection channel located adjacent to the side wall of the plasma chamber, rather than from the center, so that the process gas enters the plasma chamber in a close proximity to the induction coil. In particular embodiments, the process gas that enters the chamber is forced to pass through a reactive volume or active region adjacent the induction coil where efficient heating of electrons occurs, providing increased efficiency of the reactor by improving process gas flow and confinement in the heating area.

Abstract: An apparatus and method are described for processing workpieces in a treatment process. A multi-wafer chamber defines a chamber interior including at least two processing stations within the chamber interior such that the processing stations share the chamber interior. Each processing station includes a plasma source and a workpiece pedestal for exposing one of the workpieces to the treatment process using a respective plasma source. The chamber includes an arrangement of one or more electrically conductive surfaces that are asymmetrically disposed about the workpiece at each processing station in a way which produces a given level of uniformity of the treatment process on a major surface of each workpiece. A shield arrangement provides an enhanced uniformity of exposure of the workpiece to the respective one of the plasma sources that is greater than the given level of uniformity that would be provided in an absence of the shield arrangement.

Abstract: Methods and apparatus for heat-treating a workpiece are disclosed. An illustrative method includes measuring deformation of a workpiece during heat-treating thereof, and taking an action in relation to the heat-treating of the workpiece, in response to the measuring of the deformation of the workpiece. The workpiece may include a semiconductor wafer. Taking an action may include applying a deformation correction to a temperature or reflectivity measurement of the wafer during thermal processing, or may include modifying the heat-treating of the wafer, for example.