Patent application number | Description | Published |
20080299783 | SYSTEMS AND METHODS FOR PROCESSING SEMICONDUCTOR STRUCTURES USING LASER PULSES LATERALLY DISTRIBUTED IN A SCANNING WINDOW - Systems and methods process structures on or within a semiconductor substrate using a series of laser pulses. In one embodiment, a deflector is configured to selectively deflect the laser pulses within a processing window. The processing window is scanned over the semiconductor substrate such that a plurality of laterally spaced rows of structures simultaneously pass through the processing window. As the processing window is scanned, the deflector selectively deflects the series of laser pulses among the laterally spaced rows within the processing window. Thus, multiple rows of structures may be processed in a single scan. | 12-04-2008 |
20080314879 | SYSTEMS AND METHODS FOR ADAPTING PARAMETERS TO INCREASE THROUGHPUT DURING LASER-BASED WAFER PROCESSING - Systems and methods automatically modify a laser-based system for processing target specimens such as semiconductor wafers. In one embodiment, the laser-based system detects a trigger associated with a processing model. The processing model corresponds to a set of wafers. In response to the trigger, the system automatically adjusts one or more system parameters based on the processing model. The system then uses the modified system parameters to selectively irradiate structures on or within at least one wafer in the set of wafers. In one embodiment, the trigger includes variations in a thermal state related to a motion stage. In response to the variations in the thermal state, the system operates the motion stage in a series of movements until a thermal equilibrium threshold is reached. The sequence of movements may, for example, simulate movements used to process a particular wafer. | 12-25-2008 |
20090011614 | RECONFIGURABLE SEMICONDUCTOR STRUCTURE PROCESSING USING MULTIPLE LASER BEAM SPOTS - Methods and systems selectively irradiate structures on or within a semiconductor wafer using multiple laser beams. The structures may be laser-severable conductive links, and the purpose of the irradiation may be to sever selected links. The structures are arranged in rows and may be processed in either an on-axis mode or a cross-axis mode. In the on-axis mode, the beam spots fall on structures in the same row as they move along the row. In the cross-axis mode, the beam spots fall on structures in different rows as they move along the rows. | 01-08-2009 |
20090242522 | PHOTONIC MILLING USING DYNAMIC BEAM ARRAYS - A laser processing system includes a beam positioning system to align beam delivery coordinates relative to a workpiece. The beam positioning system generates position data corresponding to the alignment. The system also includes a pulsed laser source and a beamlet generation module to receive a laser pulse from the pulsed laser source. The beamlet generation module generates a beamlet array from the laser pulse. The beamlet array includes a plurality of beamlet pulses. The system further includes a beamlet modulator to selectively modulate the amplitude of each beamlet pulse in the beamlet array, and beamlet delivery optics to focus the modulated beamlet array onto one or more targets at locations on the workpiece corresponding to the position data. | 10-01-2009 |
20090242531 | PHOTONIC CLOCK STABILIZED LASER COMB PROCESSING - Processing a workpiece with a laser includes generating laser pulses at a first pulse repetition frequency. The first pulse repetition frequency provides reference timing for coordination of a beam positioning system and one or more cooperating beam position compensation elements to align beam delivery coordinates relative to the workpiece. The method also includes, at a second pulse repetition frequency that is lower than the first pulse repetition frequency, selectively amplifying a subset of the laser pulses. The selection of the laser pulses included in the subset is based on the first pulse repetition frequency and position data received from the beam positioning system. The method further includes adjusting the beam delivery coordinates using the one or more cooperating beam position compensation elements so as to direct the amplified laser pulses to selected targets on the workpiece. | 10-01-2009 |
20090245302 | METHODS AND SYSTEMS FOR DYNAMICALLY GENERATING TAILORED LASER PULSES - Processing workpieces such as semiconductor wafers or other materials with a laser includes selecting a target to process that corresponds to a target class associated with a predefined temporal pulse profile. The temporal pulse profile includes a first portion that defines a first time duration, and a second portion that defines a second time duration. A method includes generating a laser pulse based on laser system input parameters configured to shape the laser pulse according to the temporal pulse profile, detecting the generated laser pulse, comparing the generated laser pulse to the temporal pulse profile, and adjusting the laser system input parameters based on the comparison. | 10-01-2009 |
20100084662 | SEMICONDUCTOR STRUCTURE PROCESSING USING MULTIPLE LASER BEAM SPOTS OVERLAPPING LENGTHWISE ON A STRUCTURE - Methods and systems use laser pulses to process a selected structure on or within a semiconductor substrate. The structure has a surface, a width, and a length. The laser pulses propagate along axes that move along a scan beam path relative to the substrate as the laser pulses process the selected structure. The method simultaneously generates on the selected structure first and second laser beam pulses that propagate along respective first and second laser beam axes intersecting the selected structure at distinct first and second locations. The first and second laser beam pulses impinge on the surface of the selected structure respective first and second beam spots. Each beam spot encompasses at least the width of the selected link. The first and second beam spots are spatially offset from one another along the length of the selected structure to define an overlapping region covered by both the first and the second beam spots and a total region covered by one or both of the first and second beam spots. The total region is larger than the first beam spot and also larger than the second beam spot. The method sets respective first and second energy values of the first and second laser beam pulses to cause complete depthwise processing of the selected structure across the width of the structure in at least a portion of the total region. | 04-08-2010 |
20100089881 | SEMICONDUCTOR STRUCTURE PROCESSING USING MULTIPLE LATERALLY SPACED LASER BEAM SPOTS DELIVERING MULTIPLE BLOWS - Methods and systems process a semiconductor substrate having a plurality of structures to be selectively irradiated with multiple laser beams. The structures are arranged in a plurality of substantially parallel rows extending in a generally lengthwise direction. The method generates a first laser beam that propagates along a first laser beam axis that intersects a first target location on or within the semiconductor substrate. The method also generates a second laser beam that propagates along a second laser beam axis that intersects a second target location on or within the semiconductor substrate. The second target location is offset from the first target location in a direction perpendicular to the lengthwise direction of the rows by some amount such that, when the first target location is a structure on a first row of structures, the second target location is a structure or between two adjacent structures on a second row distinct from the first row. The method moves the semiconductor substrate relative to the first and second laser axes in a direction approximately parallel to the rows of structures, so as to pass the first target location along the first row to irradiate for a first time selected structures in the first row, and so as to simultaneously pass the second target location along the second row to irradiate for a second time structures previously irradiated by the first laser beam during a previous pass of the first target location along the second row. | 04-15-2010 |
20100133651 | SEMICONDUCTOR STRUCTURE PROCESSING USING MULTIPLE LATERALLY SPACED LASER BEAM SPOTS WITH JOINT VELOCITY PROFILING - A method is used in processing structures on or within a semiconductor substrate using N series of laser pulses to obtain a throughput benefit, wherein N≧2. The structures are arranged in a plurality of substantially parallel rows extending in a generally lengthwise direction. The N series of laser pulses propagate along N respective beam axes until incident upon selected structures in N respective distinct rows. The method determines a joint velocity profile for simultaneously moving in the lengthwise direction the N laser beam axes substantially in unison relative to the semiconductor substrate so as to process structures in the N rows with the respective N series of laser pulses, whereby the joint velocity profile is such that the throughput benefit is achieved while ensuring that the joint velocity profile represents feasible velocities for each of the N series of laser pulses and for each of the respective N rows of structures processed with the N series of laser pulses. A semiconductor substrate is designed to have a structure layout that takes advantage of the N-fold processing parallelism provided by the N laser beams. | 06-03-2010 |
20110186555 | SYSTEM FOR SEMICONDUCTOR STRUCTURE PROCESSING USING MULTIPLE LASER BEAM SPOTS - Methods and systems selectively irradiate structures on or within a semiconductor substrate using a plurality of pulsed laser beams. The structures are arranged in a row extending in a generally lengthwise direction. The method generates a first pulsed laser beam that propagates along a first laser beam axis that intersects the semiconductor substrate and a second pulsed laser beam that propagates along a second laser beam axis that intersects the semiconductor substrate. The method directs respective first and second pulses from the first and second pulsed laser beams onto distinct first and second structures in the row. The method moves the first and second laser beam axes relative to the semiconductor substrate substantially in unison in a direction substantially parallel to the lengthwise direction of the row. | 08-04-2011 |
20110210103 | SYSTEMS AND METHODS FOR PROCESSING SEMICONDUCTOR STRUCTURES USING LASER PULSES LATERALLY DISTRIBUTED IN A SCANNING WINDOW - Systems and methods process structures on or within a semiconductor substrate using a series of laser pulses. In one embodiment, a deflector is configured to selectively deflect the laser pulses within a processing window. The processing window is scanned over the semiconductor substrate such that a plurality of laterally spaced rows of structures simultaneously pass through the processing window. As the processing window is scanned, the deflector selectively deflects the series of laser pulses among the laterally spaced rows within the processing window. Thus, multiple rows of structures may be processed in a single scan. | 09-01-2011 |
20110272388 | PHOTONIC CLOCK STABILIZED LASER COMB PROCESSING - Processing a workpiece with a laser includes generating laser pulses at a first pulse repetition frequency. The first pulse repetition frequency provides reference timing for coordination of a beam positioning system and one or more cooperating beam position compensation elements to align beam delivery coordinates relative to the workpiece. The method also includes, at a second pulse repetition frequency that is lower than the first pulse repetition frequency, selectively amplifying a subset of the laser pulses. The selection of the laser pulses included in the subset is based on the first pulse repetition frequency and position data received from the beam positioning system. The method further includes adjusting the beam delivery coordinates using the one or more cooperating beam position compensation elements so as to direct the amplified laser pulses to selected targets on the workpiece. | 11-10-2011 |
20110298156 | METHODS AND SYSTEMS FOR LASER PROCESSING A WORKPIECE USING A PLURALITY OF TAILORED LASER PULSE SHAPES - Tailored laser pulse shapes are used for processing workpieces. Laser dicing of semiconductor device wafers on die-attach film (DAF), for example, may use different tailored laser pulse shapes for scribing device layers down to a semiconductor substrate, dicing the semiconductor substrate, cutting the underlying DAF, and/or post processing of the upper die edges to increase die break strength. Different mono-shape laser pulse trains may be used for respective recipe steps or passes of a laser beam over a scribe line. In another embodiment, scribing a semiconductor device wafer includes only a single pass of a laser beam along a scribe line using a mixed-shape laser pulse train that includes at least two laser pulses that are different than one another. In addition, or in other embodiments, one or more tailored pulse shapes may be selected and provided to the workpiece on-the-fly. The selection may be based on sensor feedback. | 12-08-2011 |
20120160814 | METHODS AND SYSTEMS FOR LINK PROCESSING USING LASER PULSES WITH OPTIMIZED TEMPORAL POWER PROFILES AND POLARIZATIONS - Systems and methods ablate electrically conductive links using laser pulses with optimized temporal power profiles and/or polarizations. In certain embodiments, the polarization property of a laser beam is set such that coupling between the laser beam and an electrically conductive link reduces the pulse energy required to ablate the electrically conductive link. In one such embodiment, the polarization is selected based on a depth of a target link structure. In another embodiment, the polarization changes as deeper material is removed from a target location. In addition, or in other embodiments, a first portion of a temporal power profile of a laser beam includes a rapid rise time to heat an upper portion of an electrically conductive link so as to form cracks in a passivation layer over upper corners of the electrically conductive link, without forming cracks at lower corners of the electrically conductive link. | 06-28-2012 |