Abstract: A unit magnification Wynn-Dyson lens for microlithography has an image field sized to accommodate between four and six die of dimensions 26 mm×36 mm. The lens has a positive lens group that consists of either three or four refractive lens elements, with one of the lens elements being most mirror-wise and having a prism-wise concave aspheric surface. Protective windows respectively reside between object and image planes and the corresponding prism faces. The lens is corrected for at least the i-line LED wavelength spectrum or similar LED-generated wavelengths.

Abstract: Systems and methods for forming a time-averaged line image having a relatively high amount of intensity uniformity along its length is disclosed. The method includes forming at an image plane a line image having a first amount of intensity non-uniformity in a long-axis direction and forming a secondary image that at least partially overlaps the primary image. The method also includes scanning the secondary image over at least a portion of the primary image and in the long-axis direction according to a scan profile to form a time-average modified line image having a second amount of intensity non-uniformity in the long-axis direction that is less than the first amount. For laser annealing a semiconductor wafer, the amount of line-image overlap for adjacent scans of a wafer scan path is substantially reduced, thereby increasing wafer throughput.

Abstract: A programmable illuminator for a photolithography system includes a light source, a first optical system having a light uniformizing element, a programmable micro-mirror device, and a second optical system that forms an illumination field that illuminates a reticle. The programmable micro-mirror device can be configured to perform shutter and edge-exposure-blocking functions that have previously required relatively large mechanical devices. Methods of improving illumination field uniformity using the programmable illuminator are also disclosed.

Abstract: Systems and methods for processing a material layer supported by a substrate using a light-source assembly that includes LED light sources each formed from an array of LEDs. The material layer is capable of undergoing a photo-process having a temperature-dependent reaction rate. Some of the LEDs emit light of a first wavelength that initiate the photo-process while some of the LEDs emit light of a second wavelength that heats the substrate. The heat from the substrate then heats the material layer, which increases the temperature-dependent reaction rate of the photo-process.

Abstract: Methods and apparatuses are provided for improving the intensity profile of a beam image used to process a semiconductor substrate. At least one photonic beam may be generated and manipulated to form an image having an intensity profile with an extended uniform region useful for thermally processing the surface of the substrate. The image may be scanned across the surface to heat at least a portion of the substrate surface to achieve a desired temperature within a predetermined dwell time. Such processing may achieve a high efficiency due to the large proportion of energy contained in the uniform portion of the beam.

Abstract: Photolithographic methods of forming a roughened surface for an LED to improve LED light emission efficiency are disclosed. The methods include photolithographically imaging a phase-shift mask pattern onto a photoresist layer of a substrate to form therein a periodic array of photoresist features. The roughened substrate surface is created by processing the exposed photoresist layer to form a periodic array of substrate posts in the substrate surface. A p-n junction multilayer structure is then formed atop the roughened substrate surface to form the LED. The periodic array of substrate posts serve as scatter sites that improve the LED light emission efficiency as compared to the LED having no roughened substrate surface. The use of the phase-shift mask enables the use of affordable photolithographic imaging at a depth of focus suitable for non-flat LED substrates while also providing the needed resolution to form the substrate posts.

Abstract: Systems for and methods of laser-enhanced plasma processing of semiconductor materials are disclosed. The method includes supporting a semiconductor material in a processing chamber interior and subjecting the semiconductor material to a plasma process. The method also includes simultaneously heating the wafer surface with a laser beam through a window in the processing chamber to increase the reaction rate of the plasma process. Other methods include performing laser heating of the semiconductor material before or after the plasma process but while the semiconductor material resides in the same chamber interior.

Abstract: An alignment system for aligning a wafer when lithographically fabricating LEDs having an LED wavelength ?LED is disclosed. The system includes the wafer. The wafer has a roughened alignment mark with a root-mean-square (RMS) surface roughness ?S. The system has a lens configured to superimpose an image of the reticle alignment mark with an image of the roughened alignment mark. The roughened alignment marked image is formed with alignment light having a wavelength ?A that is in the range from about 2?S to about 8?S. An image sensor detects the superimposed image. An image processing unit processes the detected superimposed image to measure an alignment offset between the wafer and the reticle.

Abstract: Methods of characterizing semiconductor light-emitting devices (LEDs) based on product wafer characteristics are disclosed. The methods include measuring at least one product wafer characteristic, such curvature or device layer stress. The method also includes establishing a relationship between the at least one characteristic and the emission wavelengths of the LED dies formed from the product wafer. The relationship allows for predicting the emission wavelength of LED structures formed in the device layer of similarly formed product wafers. This in turn can be used to characterize the product wafers and in particular the LED structures formed thereon, and to perform process control in high-volume LED manufacturing.

Abstract: A Wynn-Dyson imaging system with reduced thermal distortion is disclosed, wherein the reticle and wafer prisms are made of glass material having a coefficient of thermal expansion of no greater than about 100 ppb/° C. The system also includes a first IR-blocking window disposed between the reticle and the reticle prism, and a second matching window disposed between the wafer and the wafer prism to maintain imaging symmetry. The IR-blocking window substantially blocks convective and radiative heat from reaching the reticle prism, thereby reducing the amount of thermally induced image distortion in the reticle image formed on the wafer.

Abstract: Systems and methods for performing semiconductor laser annealing using dual loop control are disclosed. The first control loop operates at a first frequency and controls the output of the laser and controls the 1/f laser noise. The second control loop also controls the amount of output power in the laser and operates at second frequency lower than the first frequency. The second control loop measures the thermal emission of the wafer over an area the size of one or more die so that within-die emissivity variations are average out when determining the measured annealing temperature. The measured annealing temperature and an annealing temperature set point are used to generate the control signal for the second control loop.

Abstract: A movable microchamber system with a gas curtain is disclosed. The microchamber system has a top member with a light-access feature and a stage assembly that supports a substrate to be processed. The stage assembly is disposed relative to the top member to define a microchamber and a peripheral microchamber gap. An inert gas is flowed into the peripheral microchamber gap to form the gas curtain just outside of the microchamber. The gas curtain substantially prevents reactive gas in the ambient environment from entering the microchamber when the stage assembly moves relative to the top member.

Abstract: Methods and apparatuses are provided for improving the intensity profile of a beam image used to process a semiconductor substrate. At least one photonic beam may be generated and manipulated to form an image having an intensity profile with an extended uniform region useful for thermally processing the surface of the substrate. The image may be scanned across the surface to heat at least a portion of the substrate surface to achieve a desired temperature within a predetermined dwell time. Such processing may achieve a high efficiency due to the large proportion of energy contained in the uniform portion of the beam.

Abstract: A through silicon via structure and a method of fabricating the through silicon via. The method includes: (a) forming a trench in a silicon substrate, the trench open to a top surface of the substrate; (b) forming a silicon dioxide layer on sidewalls of the trench, the silicon dioxide layer not filling the trench; (c) filling remaining space in the trench with polysilicon; after (c), (d) fabricating at least a portion of a CMOS device in the substrate; (e) removing the polysilicon from the trench, the dielectric layer remaining on the sidewalls of the trench; (f) re-filling the trench with an electrically conductive core; and after (f), (g) forming one or more wiring layers over the top surface of the substrate, a wire of a wiring level of the one or more wiring levels closest to the substrate contacting a top surface of the conductive core.

Abstract: Systems and methods for performing semiconductor laser annealing using dual loop control are disclosed. The first control loop operates at a first frequency and controls the output of the laser and controls the 1/f laser noise. The second control loop also controls the amount of output power in the laser and operates at second frequency lower than the first frequency. The second control loop measures the thermal emission of the wafer over an area the size of one or more die so that within-die emissivity variations are average out when determining the measured annealing temperature. The measured annealing temperature and an annealing temperature set point are used to generate the control signal for the second control loop.

Abstract: A through silicon via structure and a method of fabricating the through silicon via. The method includes: (a) forming a trench in a silicon substrate, the trench open to a top surface of the substrate; (b) forming a silicon dioxide layer on sidewalls of the trench, the silicon dioxide layer not filling the trench; (c) filling remaining space in the trench with polysilicon; after (c), (d) fabricating at least a portion of a CMOS device in the substrate; (e) removing the polysilicon from the trench, the dielectric layer remaining on the sidewalls of the trench; (f) re-filling the trench with an electrically conductive core; and after (f), (g) forming one or more wiring layers over the top surface of the substrate, a wire of a wiring level of the one or more wiring levels closest to the substrate contacting a top surface of the conductive core.

Abstract: Structure and methods of making the structures. The structures include a structure, comprising: an organic dielectric passivation layer extending over a substrate; an electrically conductive current spreading pad on a top surface of the organic dielectric passivation layer; an electrically conductive solder bump pad comprising one or more layers on a top surface of the current spreading pad; and an electrically conductive solder bump containing tin, the solder bump on a top surface of the solder bump pad, the current spreading pad comprising one or more layers, at least one of the one or more layers consisting of a material that will not form an intermetallic with tin or at least one of the one or more layers is a material that is a diffusion barrier to tin and adjacent to the solder bump pad.

Abstract: Methods of performing fast thermal annealing in forming GaN light-emitting diodes (LEDs) are disclosed, as are GaN LEDs formed using fast thermal annealing. An exemplary method includes forming a GaN multilayer structure having a n-GaN layer and a p-GaN layer that sandwich an active layer. The method includes performing fast thermal annealing of the p-GaN layer using either a laser or a flash lamp. The method further includes forming a transparent conducting layer atop the GaN multilayer structure, and adding a p-contact to the transparent conducting layer and a n-contact to the n-GaN layer. The resultant GaN LEDs have enhanced output power, lower turn-on voltage and reduced series resistance.

Abstract: A microelectronic structure, such as a semiconductor structure, and a method for fabricating the microelectronic structure, include an aperture within a substrate. Into the aperture is located and formed a via. The via may include a through substrate via. The aperture includes, progressing sequentially contiguously at least partially through the substrate: (1) a first comparatively wide region at a surface of the substrate; (2) a constricted region contiguous with the first comparatively wide region; (3) a second comparatively wide region contiguous with the constricted region; and (4) a tapered region contiguous with the second comparatively wide region. The structure of the aperture provides for ease in filling the aperture, as well as void isolation within the via that is filled into the aperture.

Abstract: A through silicon via structure and a method of fabricating the through silicon via. The method includes: (a) forming a trench in a silicon substrate, the trench open to a top surface of the substrate; (b) forming a silicon dioxide layer on sidewalls of the trench, the silicon dioxide layer not filling the trench; (c) filling remaining space in the trench with polysilicon; after (c), (d) fabricating at least a portion of a CMOS device in the substrate; (e) removing the polysilicon from the trench, the dielectric layer remaining on the sidewalls of the trench; (f) re-filling the trench with an electrically conductive core; and after (f), (g) forming one or more wiring layers over the top surface of the substrate, a wire of a wiring level of the one or more wiring levels closest to the substrate contacting a top surface of the conductive core.