Patent application number | Description | Published |
20100089884 | LASER MACHINING SYSTEMS AND METHODS WITH MOVING LASER SCANNING STAGE(S) PROVIDING FORCE CANCELLATION - Laser machining systems and methods may use one or more moving laser scanning stages with force cancellation. The force cancellation is provided by moving masses linearly with equal and opposition motion. One or more of the masses may be a laser scanning stage. The laser machining systems may be used to scribe one or more lines in large flat workpieces such as solar panels. In particular, laser machining systems and methods may be used to scribe lines in thin film photovoltaic (PV) solar panels with accuracy, high speed and reduced cost. | 04-15-2010 |
20100089885 | LASER MACHINING SYSTEMS AND METHODS WITH MULTIPLE BEAMLET LASER BEAM DELIVERY SYSTEMS - Multiple beamlet laser beam delivery systems and methods may be used in laser machining systems and methods to machine multiple regions on a workpiece simultaneously. One embodiment of a laser machining system and method may be used, for example, to scribe one or more lines in large flat workpieces such as solar panels. In particular, laser machining systems and methods may be used to scribe lines in thin film photovoltaic (PV) solar panels with accuracy, high speed and reduced cost. The multiple beam delivery systems may be movable to scribe multiple lines simultaneously in the workpiece. | 04-15-2010 |
20110132549 | LASER LIFT OFF SYSTEMS AND METHODS - Laser lift off systems and methods may be used to provide monolithic laser lift off with minimal cracking by reducing the size of one or more beam spots in one or more dimensions to reduce plume pressure while maintaining sufficient energy to provide separation. By irradiating irradiation zones with various shapes and in various patterns, the laser lift off systems and methods use laser energy more efficiently, reduce cracking when separating layers, and improve productivity. Some laser lift off systems and methods described herein separate layers of material by irradiating non-contiguous irradiation zones with laser lift off zones (LOZs) that extend beyond the irradiation zones. Other laser lift off systems and methods described herein separate layers of material by shaping the irradiation zones and by controlling the overlap of the irradiation zones in a way that avoids uneven exposure of the workpiece. Consistent with at least one embodiment, a laser lift off system and method may be used to provide monolithic lift off of one or more epitaxial layers on a substrate of a semiconductor wafer. | 06-09-2011 |
20110132885 | LASER MACHINING AND SCRIBING SYSTEMS AND METHODS - A laser machining system may include an opposite side camera to provide workpiece alignment from an opposite side of the system (i.e., the side opposite the laser machining process). The opposite side camera may be used with an air bearing positioning stage, and a portion of the stage and/or the opposite side camera may be moved to allow the opposite side camera to image a feature on the workpiece to be aligned. The opposite side alignment may be used with back side scribing and/or dual side scribing of a workpiece with alignment from one or both sides of the workpiece. Laser machining systems and methods may also be used to provide quasi-stealth scribing and multi-beam scribing. | 06-09-2011 |
20120234807 | LASER SCRIBING WITH EXTENDED DEPTH AFFECTATION INTO A WORKPLACE - Systems and methods for laser scribing provide extended depth affectation into a substrate or workpiece by focusing a laser beam such that the beam passes into the workpiece using a waveguide, self-focusing effect to cause internal crystal damage along a channel extending into the workpiece. Different optical effects may be used to facilitate the waveguide, self-focusing effect, such as multi-photon absorption in the material of the workpiece, transparency of the material of the workpiece, and aberrations of the focused laser. The laser beam may have a wavelength, pulse duration, and pulse energy, for example, to provide transmission through the material and multi-photon absorption in the material. An aberrated, focused laser beam may also be used to provide a longitudinal spherical aberration range sufficient to extend the effective depth of field (DOF) into the workpiece. | 09-20-2012 |
20130256286 | LASER PROCESSING USING AN ASTIGMATIC ELONGATED BEAM SPOT AND USING ULTRASHORT PULSES AND/OR LONGER WAVELENGTHS - An adjustable astigmatic elongated beam spot may be formed from a laser beam having ultrashort laser pulses and/or longer wavelengths to machine substrates made of a variety of different materials. The laser beam may be generated with pulses having a pulse duration of less than 1 ns and/or having a wavelength greater than 400 nm. The laser beam is modified to produce an astigmatic beam that is collimated in a first axis and converging in a second axis. The astigmatic beam is focused to form the astigmatic elongated beam spot on a substrate, which is focused on the substrate in the first axis and defocused in the second axis. The astigmatic elongated beam spot may be adjusted in length to provide an energy density sufficient for a single ultrashort pulse to cause cold ablation of at least a portion of the substrate material. | 10-03-2013 |
20140102643 | LASER LIFT OFF SYSTEMS AND METHODS THAT OVERLAP IRRADIATION ZONES TO PROVIDE MULTIPLE PULSES OF LASER IRRADIATION PER LOCATION AT AN INTERFACE BETWEEN LAYERS TO BE SEPARATED - Laser lift off systems and methods overlap irradiation zones to provide multiple pulses of laser irradiation per location at the interface between layers of material to be separated. To overlap irradiation zones, the laser lift off systems and methods provide stepwise relative movement between a pulsed laser beam and a workpiece. The laser irradiation may be provided by a non-homogeneous laser beam with a smooth spatial distribution of energy across the beam profile. The pulses of laser irradiation from the non-homogenous beam may irradiate the overlapping irradiation zones such that each of the locations at the interface is exposed to different portions of the non-homogeneous beam for each of the multiple pulses of the laser irradiation, thereby resulting in self-homogenization. Thus, the number of the multiple pulses of laser irradiation per location is generally sufficient to provide the self-homogenization and to separate the layers of material. | 04-17-2014 |
20150179523 | LASER LIFT OFF SYSTEMS AND METHODS - Laser lift off systems and methods may be used to provide monolithic laser lift off with minimal cracking by reducing the size of one or more beam spots in one or more dimensions to reduce plume pressure while maintaining sufficient energy to provide separation. By irradiating irradiation zones with various shapes and in various patterns, the laser lift off systems and methods use laser energy more efficiently, reduce cracking when separating layers, and improve productivity. Some laser lift off systems and methods described herein separate layers of material by irradiating non-contiguous irradiation zones with laser lift off zones (LOZs) that extend beyond the irradiation zones. Other laser lift off systems and methods described herein separate layers of material by shaping the irradiation zones and by controlling the overlap of the irradiation zones in a way that avoids uneven exposure of the workpiece. Consistent with at least one embodiment, a laser lift off system and method may be used to provide monolithic lift off of one or more epitaxial layers on a substrate of a semiconductor wafer. | 06-25-2015 |