Abstract: Implementations disclosed describe a collimator assembly having a collimator housing that includes an interface configured to optically couple to a process chamber that has a target surface, and a port to receive an optical fiber to deliver, to an enclosure formed by the collimator housing, a first (second) plurality of spectral components of light belonging to a first (second) range of wavelengths, and an achromatic lens located, at least partially, within the enclosure formed by the collimator housing, the achromatic lens to direct the first (second) plurality of spectral components of light onto the target surface to illuminate a first (second) region on the target surface, wherein the second region is substantially the same as the first region.

Abstract: Implementations disclosed describe a collimator assembly having a collimator housing that includes an interface configured to optically couple to a process chamber that has a target surface, and a port to receive an optical fiber to deliver, to an enclosure formed by the collimator housing, a first (second) plurality of spectral components of light belonging to a first (second) range of wavelengths, and an achromatic lens located, at least partially, within the enclosure formed by the collimator housing, the achromatic lens to direct the first (second) plurality of spectral components of light onto the target surface to illuminate a first (second) region on the target surface, wherein the second region is substantially the same as the first region.

Abstract: Implementations disclosed describe a collimator assembly having a collimator housing that includes an interface configured to optically couple to a process chamber that has a target surface, and a port to receive an optical fiber to deliver, to an enclosure formed by the collimator housing, a first (second) plurality of spectral components of light belonging to a first (second) range of wavelengths, and an achromatic lens located, at least partially, within the enclosure formed by the collimator housing, the achromatic lens to direct the first (second) plurality of spectral components of light onto the target surface to illuminate a first (second) region on the target surface, wherein the second region is substantially the same as the first region.

Abstract: Embodiments include wafer and photomask processing equipment. An etch processing system including an endpoint detection system having a light source and a photodetector is described. In an example, the light source emits light toward an alignment region over a substrate support member of an etch chamber, and the photodetector receives a reflection of the light from the alignment region. The reflection is monitored for endpoint and process control. A second light source emits light toward the alignment region, and a camera receives the light to image the alignment region. The image can be used to align the light emitted by the endpoint detection system to a spot location within the alignment region, e.g., within an alignment opening of a substrate mounted on the substrate support member.

Abstract: Embodiments include wafer and photomask processing equipment. An etch processing system including an endpoint detection system having a light source and a photodetector is described. In an example, the light source emits light toward an alignment region over a substrate support member of an etch chamber, and the photodetector receives a reflection of the light from the alignment region. The reflection is monitored for endpoint and process control. A second light source emits light toward the alignment region, and a camera receives the light to image the alignment region. The image can be used to align the light emitted by the endpoint detection system to a spot location within the alignment region, e.g., within an alignment opening of a substrate mounted on the substrate support member.

Abstract: Embodiments of the invention generally provide a lid heater for a plasma processing chamber. In one embodiment, a lid heater assembly is provided that includes a thermally conductive base. The thermally conductive base has a planar ring shape defining an inner opening. The lid heater assembly further includes a heating element disposed on the thermally conductive base, and an insulated center core disposed across the inner opening of the thermally conductive base.

Abstract: A plasma reactor has an array of plural gas injectors arranged around a circular side wall that are individually controlled.

Abstract: Embodiments include wafer and photomask processing equipment. An etch processing system including an endpoint detection system having a light source and a photodetector is described. In an example, the light source emits light toward an alignment region over a substrate support member of an etch chamber, and the photodetector receives a reflection of the light from the alignment region. The reflection is monitored for endpoint and process control. A second light source emits light toward the alignment region, and a camera receives the light to image the alignment region. The image can be used to align the light emitted by the endpoint detection system to a spot location within the alignment region, e.g., within an alignment opening of a substrate mounted on the substrate support member.

Abstract: The present invention provides a method and apparatus for etching a photomask substrate with enhanced process monitoring, for example, by providing for optical monitoring at certain regions of the photomask to obtain dual endpoints, e.g., etch rate or thickness loss of both a photoresist layer and an absorber layer. By monitoring transmissity of an optical beam transmitted through areas having photoresist layer and etched absorber layer at two different predetermined wavelength, dual process endpoints may be obtained by a signal optical detection.

Abstract: The present invention provides a method and apparatus for etching a photomask substrate with enhanced process monitoring, for example, by providing for optical monitoring at certain regions of the photomask to obtain dual endpoints, e.g., etch rate or thickness loss of both a photoresist layer and an absorber layer. By monitoring transmissity of an optical beam transmitted through areas having photoresist layer and etched absorber layer at two different predetermined wavelength, dual process endpoints may be obtained by a signal optical detection.

Abstract: Embodiments of the present invention generally provide an inductively coupled plasma (ICP) reactor having a substrate RF bias that is capable of control of the RF phase difference between the ICP source (a first RF source) and the substrate bias (a second RF source) for plasma processing reactors used in the semiconductor industry. Control of the RF phase difference provides a powerful knob for fine process tuning. For example, control of the RF phase difference may be used to control one or more of average etch rate, etch rate uniformity, etch rate skew, critical dimension (CD) uniformity, and CD skew, CD range, self DC bias control, and chamber matching.

Abstract: A plasma reactor has an array of plural gas injectors arranged around a circular side wall that are individually controlled.

Abstract: A plasma reactor has an array of passages extending through its workpiece support pedestal from a bottom thereof that forms a two-dimensional array of openings in the support surface. The reactor further includes a plurality of optical fibers, each fiber extending through a respective one of the passages. Optical sensing apparatus is coupled to the output ends of the optical fibers and is responsive in the range of wavelengths. The reactor further includes a tunable element capable of changing a two-dimensional etch rate distribution across the surface of a workpiece supported on the pedestal, and a process controller connected to receive information from the optical sensing apparatus and to transmit control commands to the tunable element.

Abstract: The present invention provides a method and apparatus for etching a photomask substrate with enhanced process monitoring, for example, by providing for optical monitoring at different regions of the photomask to obtain desired etch rate or thickness loss. In one embodiment, the method includes etching a first substrate through a patterned mask layer in a plasma etch chamber, the first substrate having a backside disposed on a substrate support and a front side facing away from the substrate support, directing a first radiation source from the backside of the first substrate to a first area covered by the patterned mask layer, directing a second radiation source from the backside of the first substrate to a second area uncovered by the patterned mask layer, collecting a first signal reflected from the first area covered by the patterned mask layer, collecting a second signal reflected from the second area uncovered by the patterned mask layer, and analyzing the combined first and the second signal.

Abstract: A method and apparatus for monitoring a target layer in a plasma process having a photoresist layer is provided. The method is useful in removing noise associated with the photoresist layer, and is particularly useful when signals associated with the target layer is weak, such as when detecting an endpoint for a photomask etching process.

Abstract: The present invention provides a method and apparatus for etching a photomask substrate with enhanced process monitoring, for example, by providing for optical monitoring at different regions of the photomask to obtain desired etch rate or thickness loss. In one embodiment, the method includes etching a first substrate through a patterned mask layer in a plasma etch chamber, the first substrate having a backside disposed on a substrate support and a front side facing away from the substrate support, directing a first radiation source from the backside of the first substrate to a first area covered by the patterned mask layer, directing a second radiation source from the backside of the first substrate to a second area uncovered by the patterned mask layer, collecting a first signal reflected from the first area covered by the patterned mask layer, collecting a second signal reflected from the second area uncovered by the patterned mask layer, and analyzing the combined first and the second signal.

Abstract: A method and apparatus for monitoring a target layer in a plasma process having a photoresist layer is provided. The method is useful in removing noise associated with the photoresist layer, and is particularly useful when signals associated with the target layer is weak, such as when detecting an endpoint for a photomask etching process.

Abstract: Embodiments of the invention generally provide a lid heater for a plasma processing chamber. In one embodiment, a lid heater assembly is provided that includes a thermally conductive base. The thermally conductive base has a planar ring shape defining an inner opening. The lid heater assembly further includes a heating element disposed on the thermally conductive base, and an insulated center core disposed across the inner opening of the thermally conductive base.

Abstract: A plasma etch method includes simultaneously illuminating an array of plural locations on front surface of the workpiece through the backside of the workpiece with light of a wavelength range for which the workpiece is transparent, while viewing light reflected from the array of plural locations to the backside of the workpiece. The method further includes determining plural etch depths at the array of locations from the light reflected from the array of locations on the front side of the workpiece, and deducing from the plural etch depths a spatial distribution of etch rate across the array of locations. The method also includes changing the etch rate distribution by adjusting a tunable element of the reactor.

Abstract: A method is provided for defining a pattern on a workpiece such as a transparent substrate or mask or a workpiece that is at least transparent within a range of optical wavelengths. The method includes defining a photoresist pattern on the top surface of the mask, the pattern including a periodic structure having a periodic spacing between elements of the structure. The method further includes placing the mask on a support pedestal in a plasma reactor chamber and generating a plasma in the chamber to etch the top surface of the mask through openings in the photoresist pattern. The method also includes transmitting light through the pedestal and through the bottom surface of the mask, while viewing through the support pedestal light reflected from the periodic structure and detecting an interference pattern in the reflected light. The method further includes determining from the interference pattern a depth to which periodic structure has been etched in the top surface.