Abstract: A quasi-CW diode-pumped, A-O Q-switched solid-state harmonic laser system (10) synchronizes timing of the quasi-CW pumping with movement of the positioning system (36) to reduce pumping while the positioning system (36) is moving from one target area (31) to the next target area (31) to form multiple vias in a substrate at a high throughput. Thus, the available UV power for via formation is higher even though the loading to the laser pumping diodes (14) remains the same as that currently available through conventional CW pumping with conventionally available laser pumping diodes (14). The quasi-CW-pumping current profile can be further modified to realize a preferred UV pulse amplitude profile.

Abstract: A laser beam (102) cuts through a component carrier mask (96) made of thin elastomeric material such as silicone rubber to form slots (98) having slot openings of a desired shape. In a preferred embodiment, a light absorptivity enhancement material such as iron oxide introduced into the silicone rubber causes formation of a flexible support blank that operationally adequately absorbs light within a light absorption wavelength range. A beam positioner (106) receiving commands from a programmed controller causes a UV laser beam of a wavelength that is within the light absorption wavelength range to cut into the mask multiple slots with repeatable, precise dimensions. Each of the slots cut has opposed side margins that define between them a slot opening of suitable shape to receive a miniature component (10) and to exert on it optimal holding and release forces.

Abstract: UV laser cutting throughput through silicon and like materials is improved by dividing a long cut path (112) into short segments (122), from about 10 &mgr;m to 1 mm. The laser output (32) is scanned within a first short segment (122) for a predetermined number of passes before being moved to and scanned within a second short segment (122) for a predetermined number of passes. The bite size, segment size (126), and segment overlap (136) can be manipulated to minimize the amount and type of trench backfill. Real-time monitoring is employed to reduce rescanning portions of the cut path 112 where the cut is already completed. Polarization direction of the laser output (32) is also correlated with the cutting direction to further enhance throughput. This technique can be employed to cut a variety of materials with a variety of different lasers and wavelengths.

Abstract: The semiconductor device includes a blocking layer 12 formed on a substrate 10, an insulation film 14 formed on the blocking layer 12, and a fuse 22 formed on the insulation film 14. The blocking layer 12 is formed below the fuse 22, whereby the fuse is disconnected by laser ablation, and the laser ablation can be stopped by the blocking layer 12 with good controllability without damaging the substrate. The fuses to be disconnected can be arranged at a very small pitch, which can improve integration of the fuse circuit.

Abstract: A set (50) of laser pulses (52) is employed to remove a conductive link (22) and/or its overlying passivation layer (44) in a memory or other IC chip. The duration of the set (50) is preferably shorter than 1,000 ns; and the pulse width of each laser pulse (52) within the set (50) is preferably within a range of about 0.1 ps to 30 ns. The set (50) can be treated as a single “pulse” by conventional laser positioning systems (62) to perform on-the-fly link and/or passivation removal without stopping whenever the laser system (60) fires a set (50) of laser pulses (52) at each link (22). Conventional IR wavelengths or their harmonics can be employed. Selected links (22) can be etched by chemical or other alternative methods when the sets (50) are used to remove only the overlying passivation layer (44) at the selected target positions.

Abstract: A set (50) of one or more laser pulses (52) is employed to remove passivation layer (44) over a conductive link (22). The link (22) can subsequently be removed by a different process such as chemical etching. The duration of the set (50) is preferably shorter than 1,000 ns; and the pulse width of each laser pulse (52) within the set (50) is preferably within a range of about 0.05 ps to 30 ns. The set (50) can be treated as a single “pulse” by conventional laser positioning systems (62) to perform on-the-fly material removal without stopping whenever the laser system (60) fires a set (50) of laser pulses (52) at each target area (51). Conventional wavelengths in the IR range or their harmonics in the green or UV range can be employed.

Abstract: A set (50) of laser pulses (52) is employed to sever a conductive link (22) in a memory or other IC chip. The duration of the set (50) is preferably shorter than 1,000 ns; and the pulse width of each laser pulse (52) within the set (50) is preferably within a range of about 0.1 ps to 30 ns. The set (50) can be treated as a single “pulse” by conventional laser positioning systems (62) to perform on-the-fly link removal without stopping whenever the laser system (60) fires a set (50) of laser pulses (52) at each link (22). Conventional IR wavelengths or their harmonics can be employed.

Abstract: A burst (50) of ultrashort laser pulses (52) is employed to sever a conductive link (22) in a nonthermal manner and offers a wider processing window, eliminates undesirable HAZ effects, and achieves superior severed link quality. The duration of the burst (50) is preferably in the range of 10 ns to 500 ns; and the pulse width of each laser pulse (52) within the burst (50) is generally shorter than 25 ps, preferably shorter than or equal to 10 ps, and most preferably about 10 ps to 100 fs or shorter. The burst (50) can be treated as a single “pulse” by conventional laser positioning systems (62) to perform on-the-fly link removal without stopping whenever the laser system (60) fires a burst (50) of laser pulses (52) at each link (22). Conventional wavelengths or their harmonics can be employed.

Abstract: A uniform laser spot, such as from an imaged shaped Gaussian output (118) or a clipped Gaussian spot, that is less than 20 &mgr;m in diameter can be employed for both thin and thick film resistor trimming to substantially reduce microcracking. These spots can be generated in an ablative, nonthermal, UV laser wavelength to reduce the HAZ and/or shift in TCR.

Abstract: A quasi-CW diode-pumped, A-O Q-switched solid-state harmonic laser system (10) synchronizes timing of the quasi-CW pumping with movement of the positioning system (36) to reduce pumping while the positioning system (36) is moving from one target area (31) to the next target area (31) to form multiple vias in a substrate at a high throughput. Thus, the available UV power for via formation is higher even though the loading to the laser pumping diodes (14) remains the same as that currently available through conventional CW pumping with conventionally available laser pumping diodes (14). The quasi-CW-pumping current profile can be further modified to realize a preferred UV pulse amplitude profile.

Abstract: UV laser cutting throughput through silicon and like materials is improved by dividing a long cut path (112) into short segments (122), from about 10 &mgr;m to 1 mm. The laser output (32) is scanned within a first short segment (122) for a predetermined number of passes before being moved to and scanned within a second short segment (122) for a predetermined number of passes. The bite size, segment size (126), and segment overlap (136) can be manipulated to minimize the amount and type of trench backfill. Real-time monitoring is employed to reduce rescanning portions of the cut path 112 where the cut is already completed. Polarization direction of the laser output (32) is also correlated with the cutting direction to further enhance throughput. This technique can be employed to cut a variety of materials with a variety of different lasers and wavelengths.

Abstract: A quasi-CW diode- or lamp-pumped, A-O Q-switched solid-state UV laser system (10) synchronizes timing of the quasi-CW pumping with movement of the positioning system (36) to reduce pumping while the positioning system (36) is moving from one target area (31) to the next target area (31) to form multiple vias in a substrate at a high throughput. Thus, the available UV power for via formation is higher even though the average pumping power to the laser medium (16), and thermal loading of the laser pumping diodes (14), remains the same as that currently available through conventional CW pumping with conventionally available laser pumping diodes (14). The quasi-CW pumping current profile can be further modified to realize a preferred UV pulse amplitude profile.

Abstract: A uniform laser spot, such as from an imaged shaped Gaussian output (118) or a clipped Gaussian spot, that is less than 20 &mgr;m in diameter can be employed for both thin and thick film resistor trimming to substantially reduce microcracking. These spots can be generated in an ablative, nonthermal, UV laser wavelength to reduce the HAZ and/or shift in TCR.

Abstract: The semiconductor device comprises a blocking layer 12 formed on a substrate 10, an insulation film 14 formed on the blocking layer 12, and a fuse 22 formed on the insulation film 14. The blocking layer 12 is formed below the fuse 22, whereby the fuse is disconnected by laser ablation, and the laser ablation can be stopped by the blocking layer 12 with good controllability without damaging the substrate. The fuses to be disconnected can be arranged at a very small pitch, which can improve integration of the fuse circuit.

Abstract: A burst (50) of ultrashort laser pulses (52) is employed to sever a conductive link (22) in a nonthermal manner and offers a wider processing window, eliminates undesirable HAZ effects, and achieves superior severed link quality. The duration of the burst (50) is preferably in the range of 10 ns to 500 ns; and the pulse width of each laser pulse (52) within the burst (50) is generally shorter than 25 ps, preferably shorter than or equal to 10 ps, and most preferably about 10 ps to 100 fs or shorter. The burst (50) can be treated as a single “pulse” by conventional laser positioning systems (62) to perform on-the-fly link removal without stopping whenever the laser system (60) fires a burst (50) of laser pulses (52) at each link (22). Conventional wavelengths or their harmonics can be employed.

Abstract: A wavelength switchable laser (10) of this invention is based on a solid-state laser source (12) in which a fourth harmonic UV laser beam (26) is ordinarily used for processing, and a second harmonic “green” laser beam (28) is dumped and wasted. However, this invention uses the ordinarily wasted green laser beam for processing ECB (30) conductor layers (32, 36), which enhances processing throughout because of the higher power of the green energy than of the UV energy. A Pockel cell (16) effects laser beam polarization switching that causes either the green beam or the UV beam to be directed to the ECB for processing different materials. This invention requires only a single rail laser source and is, therefore, simple, cost effective, efficient, inherently aligned, and has high processing throughput.

Abstract: The semiconductor device comprises a blocking layer 12 formed on a substrate 10, an insulation film 14 formed on the blocking layer 12, and a fuse 22 formed on the insulation film 14. The blocking layer 12 is formed below the fuse 22, whereby the fuse is disconnected by laser ablation, and the laser ablation can be stopped by the blocking layer 12 with good controllability without damaging the substrate. The fuses to be disconnected can be arranged at a very small pitch, which can improve integration of the fuse circuit.

Abstract: Ultraviolet (UV) laser output (88) exploits the absorption characteristics of the materials from which an electrically conductive link (42), an underlying semiconductor substrate (50), and passivation layers (48 and 54) are made to effectively remove the link (42) without damaging the substrate (50). The UV laser output (88) forms smaller than conventional IR laser link-blowing spot diameters (58) because of its shorter wavelength, thus permitting the implementation of greater circuit density. A passivation layer positioned between the link and the substrate can be formulated to be sufficiently absorptive to UV laser energy and sufficiently thick to attenuate the laser energy to prevent it from damaging the substrate (50) in the laser beam spot area (43) in both the off-link and link-overlapped portions. The UV laser output (88) can be employed to controllably ablate a depthwise portion of the passivation layer (54) underlying the link (42) to facilitate complete removal of the link (42).

Abstract: The present invention provides a method and system for irradiating resist material from multiple target positions (150) on one or more IC chips (12) with individually directed laser output pulses (74, 94). In one embodiment, an IC (12), including one or more etch targets (104, 106) such as conductive links (72, 92), is coated with an etch protection layer (90) of photoresist material. Then, position data direct, toward multiple positions (150) on the photoresist material, individual laser output pulses (94) of predetermined parameters selected to expose the photoresist material. Because photoresist exposure requires less energy than link blowing, low-power UV lasers (120) can be employed, and their shorter wavelengths permit a smaller practical laser output spot size (98).

Abstract: A laser system (50) and processing method exploit a wavelength range (40) in which devices, including any semiconductor material-based devices (10) affected by conventional laser wavelengths and devices having light-sensitive or photo-electronic portions integrated into their circuits, can be effectively functionally trimmed without inducing performance drift or malfunctions in the processed devices. True measurement values of operational parameters of the devices can, therefore, be obtained without delay for device recovery, i.e., can be obtained substantially instantaneously with laser impingement. Accordingly, the present invention allows faster functional laser processing, eases geometric restrictions on circuit design, and facilitates production of denser and smaller devices.