Abstract: Embodiments of the invention generally relate to pyrometry during thermal processing of semiconductor substrates. More specifically, embodiments of the invention relate to a pyrometry filter for a thermal process chamber. In certain embodiments, the pyrometry filter selectively filters selected wavelengths of energy to improve a pyrometer measurement. The pyrometry filter may have various geometries which may affect the functionality of the pyrometry filter.

Abstract: Embodiments described herein relate to thermal processing of semiconductor substrates. More specifically, embodiments described herein relate to laser thermal processing of semiconductor substrates. In certain embodiments, a uniformizer is provided to spatially and temporally decorrelate a coherent light image.

Abstract: Embodiments described herein relate to apparatus and methods of thermal processing. More specifically, apparatus and methods described herein relate to laser thermal treatment of semiconductor substrates by increasing the uniformity of energy distribution in an image at a surface of a substrate.

Abstract: The present invention generally relates to an optical system that is able to reliably deliver a uniform amount of energy across an anneal region contained on a surface of a substrate. The optical system is adapted to deliver, or project, a uniform amount of energy having a desired two-dimensional shape on a desired region on the surface of the substrate. Typically, the anneal regions may be square or rectangular in shape. Generally, the optical system and methods of the present invention are used to preferentially anneal one or more regions found within the anneal regions by delivering enough energy to cause the one or more regions to re-melt and solidify.

Abstract: A method and apparatus for implanting a semiconductor substrate with boron clusters. A substrate is implanted with octadecaborane by plasma immersion or ion beam implantation. The substrate surface is then annealed to completely dissociate and activate the boron clusters. The annealing may take place by melting the implanted regions or by a sub-melt annealing process.

Abstract: Device for processing a substrate are described herein. Devices can include a radiation source and an aperture positioned to receive radiant energy from the radiation source. The aperture can include one or more members, and one or more interfering areas, wherein the interfering areas surround a transmissive area. The one or more structures can affect transmission of radiant energy through a portion of the transmissive area of the aperture. Structures disposed on the aperture can reduce or redirect transmission to provide for more uniform overall transmission of radiant energy through the aperture.

Abstract: A thermal processing apparatus and method in which a first laser source, for example, a CO2 emitting at 10.6 ?m is focused onto a silicon wafer as a line beam and a second laser source, for example, a GaAs laser bar emitting at 808 nm is focused onto the wafer as a larger beam surrounding the line beam. The two beams are scanned in synchronism in the direction of the narrow dimension of the line beam to create a narrow heating pulse from the line beam when activated by the larger beam. The energy of GaAs radiation is greater than the silicon bandgap energy and creates free carriers. The energy of the CO2 radiation is less than the silicon bandgap energy so silicon is otherwise transparent to it, but the long wavelength radiation is absorbed by the free carriers.

Abstract: Embodiments described herein provide methods and apparatus for thermally treating a substrate. A first radiant energy source that delivers a first radiation at a first fluence and a second radiant energy source that delivers a second radiation at a second fluence are disposed to direct energy toward a substrate support positioned to receive the first radiation at a first location and the second radiation at a second location, wherein the first fluence is 10 to 100 times the second fluence and the first radiation cannot reach the second location. The first radiant energy source may be a laser, and the second radiant energy source may be a plurality of lasers, for example a pulsed laser assembly with a plurality of pulsed lasers. The second radiant energy source may also be a flash lamp. The first and second radiant energy sources may be in the same chamber or different chambers.

Abstract: The present invention generally relates to an optical system that is able to reliably deliver a uniform amount of energy across an anneal region contained on a surface of a substrate. The optical system is adapted to deliver, or project, a uniform amount of energy having a desired two-dimensional shape on a desired region on the surface of the substrate. An energy source for the optical system is typically a plurality of lasers, which are combined to form the energy field.

Abstract: A method and apparatus for decorrelating coherent light from a light source, such as a pulsed laser, in both time and space in an effort to provide intense and uniform illumination are provided. The techniques and apparatus described herein may be incorporated into any application where intense, uniform illumination is desired, such as pulsed laser annealing, welding, ablating, and wafer stepper illuminating.

Abstract: A method and apparatus for decorrelating coherent light from a light source, such as a pulsed laser, in both time and space in an effort to provide intense and uniform illumination are provided. For some embodiments employing a pulsed light source, the output pulse may be stretched relative to the input pulse width. The methods and apparatus described herein may be incorporated into any application where intense, uniform illumination is desired, such as pulsed laser annealing, welding, ablating, and wafer stepper illuminating.

Abstract: Device for processing a substrate are described herein. Devices can include a radiation source and an aperture positioned to receive radiant energy from the radiation source. The aperture can include one or more members, and one or more interfering areas, wherein the interfering areas surround a transmissive area. The one or more structures can affect transmission of radiant energy through a portion of the transmissive area of the aperture. Structures disposed on the aperture can reduce or redirect transmission to provide for more uniform overall transmission of radiant energy through the aperture.

Abstract: A system for thermal processing of a substrate includes a source of radiation, optics disposed between the source and the substrate to receive light from the source of radiation at the optics proximate end, and a housing holding the optics and having a void inside the housing isolated from light emitted from the source. A light detector is disposed within the void in the housing to detect light from the optics emitted into the housing and send a deterioration signal. The system further includes a power supply for the source of radiation, and a controller to control the power supply based on the deterioration signal from the light detector.

Abstract: The present invention generally relates to an optical system that is able to reliably deliver a uniform amount of energy across an anneal region contained on a surface of a substrate. The optical system is adapted to deliver, or project, a uniform amount of energy having a desired two-dimensional shape on a desired region on the surface of the substrate. An energy source for the optical system is typically a plurality of lasers, which are combined to form the energy field.

Abstract: Photovoltaic module and methods for the manufacture of photovoltaic modules are described. Operative layers of the photovoltaic cell are deposited onto a superstrate having one or more of at least one peak allowing for electrical isolation of a portion of a photovoltaic module and at least one ramp creating a series connection between individual photovoltaic cells with minimal loss of the efficiency due to dead space between the cells.

Abstract: Apparatus and methods for combining beams of amplified radiation are disclosed. A beam combiner has a collimating optic positioned to receive a plurality of coherent radiation beams at a constant angle of incidence with respect to an optical axis of the collimating optic. The respective angles of incidence may also be different in some embodiments. The collimating optic has an optical property that collimates the beams. The optical property may be refractive or reflective, or a combination thereof. A collecting optic may also be provided to direct the plurality of beams to the collimating optic. The beam combiner may be used in a thermal processing apparatus to combine more than two beams of coherent amplified radiation, such as lasers, into a single beam.

Abstract: Methods and apparatus for aligning a substrate in a process chamber are provided herein. In some embodiments, an apparatus may include a process chamber having an interior volume for processing a substrate therein; and a substrate positioning system configured to determine a substrate position within the interior volume, wherein the substrate positioning system determines the substrate position in two dimensions by the interaction of a first position and a second position along an edge of a substrate with two beams of electromagnetic radiation provided by the substrate positioning system.

Abstract: A method and apparatus for decorrelating coherent light from a light source, such as a pulsed laser, in both time and space in an effort to provide intense and uniform illumination are provided. The techniques and apparatus described herein may be incorporated into any application where intense, uniform illumination is desired, such as pulsed laser annealing, welding, ablating, and wafer stepper illuminating.

Abstract: Substrate processing equipment and methods are used to improve the uniformity of illumination across an illuminated portion of a substrate by processing light with multiple optical homogenizers. The multiple optical homogenizers each include micro-lens arrays and Fourier lens. The multiple optical homogenizers are arranged so that the output numerical aperture of one of the optical homogenizers is within 5% of the input numerical aperture of another optical homogenizer.

Abstract: The present invention generally relates to a laser processing systems for thermally processing substrates. The laser processing systems include a shield disposed between an energy source of the laser processing system and a substrate which is to be thermally processed. The shield includes an optically transparent window disposed adjacent to a cavity within the shield. The optically transparent window allows annealing energy to pass therethrough and to illuminate the substrate. The shield also includes one or more gas inlets and one or more gas outlets for introducing and removing a purge gas from the cavity within the shield. The purge gas is utilized to remove volatized or ablated components during thermal processing, and to provide a gas of predetermined composition, such as oxygen-free, to the thermally processed area.