Abstract: The present invention provides an antenna with low resistance and a semiconductor device having an antenna whose communication distance is improved. A fluid containing conductive particles is applied over an object. After curing the fluid containing the conductive particles, the fluid is irradiated with a laser to form an antenna. As a method for applying the fluid containing the conductive particles, screen printing, spin coating, dipping, or a droplet discharging method is used. Further, a solid laser having a wavelength of 1 nm or more and 380 nm or less is used as the laser.

Abstract: It is an object of the present invention to provide a manufacturing method of a semiconductor device where a semiconductor element is prevented from being damaged and throughput speed thereof is improved, even in a case of thinning or removing a supporting substrate after forming the semiconductor element over the supporting substrate.

Abstract: Provided are a crystallization apparatus and method, which prevent cracks from being generated, a method of manufacturing a thin film transistor (TFT), and a method of manufacturing an organic light emitting display apparatus. The crystallization apparatus includes a chamber for receiving a substrate, a first flash lamp and a second flash lamp, which are disposed facing each other within the chamber, wherein amorphous silicon layers are disposed on a first surface of the substrate facing the first flash lamp and a second surface of the substrate facing the second flash lamp, respectively.

Abstract: A laser processing method comprising a step of irradiating an object to be processed with laser light elliptically polarized with an ellipticity of other than 1 such that a light-converging point of the laser light is located within the object along the major axis of an ellipse indicative of the elliptical polarization of laser light, along a line which the object is intended to be cut, to form a modified region caused by multiphoton absorption within the object, along the line which the object is intended to be cut.

Abstract: A system for preparing a semiconductor film, the system including: a laser source; optics to form a line beam, a stage to support a sample capable of translation; memory for storing a set of instructions, the instructions including irradiating a first region of the film with a first laser pulse to form a first molten zone, said first molten zone having a maximum width (Wmax) and a minimum width (Wmin), wherein the first molten zone crystallizes to form laterally grown crystals; laterally moving the film in the direction of lateral growth a distance greater than about one-half Wmax less than Wmin; and irradiating a second region of the film with a second laser pulse to form a second molten zone, wherein the second molten zone crystallizes to form laterally grown crystals that are elongations of the crystals in the first region, wherein laser optics provide less than 2×Wmin.

Abstract: A laser annealing method for executing laser annealing by irradiating a semiconductor film formed on a surface of a substrate with a laser beam, the method including the steps of, generating a linearly polarized rectangular laser beam whose cross section perpendicular to an advancing direction is a rectangle with an electric field directed toward a long-side direction of the rectangle or an elliptically polarized rectangular laser beam having a major axis directed toward a long-side direction, causing the rectangular laser beam to be introduced to the surface of the substrate, and setting a wavelength of the rectangular laser beam to a length which is about a desired size of a crystal grain in a standing wave direction.

Abstract: A fiber laser system enables a method for treating a semiconductor material by preheating a wafer for laser annealing and gas immersion laser doping by a laser source. A long wave length fiber laser having a Gaussian or similar profile is applied in a full-width ribbon beam across an incident wafer. Preferably the wavelength is greater than 1 ?m (micron) and preferably a Yb doped fiber laser is used. The process is performed in a suitable environment which may include doping species. The process ensures the temperature gradient arising during processing does not exceed a value that results in fracture of the wafer while also reducing the amount of laser radiation required to achieve controlled surface melting, recrystallization and cooling.

Abstract: Processes for curing silicon based low k dielectric materials generally includes exposing the silicon based low k dielectric material to ultraviolet radiation in an inert atmosphere having an oxidant in an amount of about 10 to about 500 parts per million for a period of time and intensity effective to cure the silicon based low k dielectric material so to change a selected one of chemical, physical, mechanical, and electrical properties and combinations thereof relative to the silicon based low k dielectric material prior to the ultraviolet radiation exposure. Also disclosed herein are silicon base low k dielectric materials substantially free of sub-oxidized SiO species.

Abstract: A method for fabricating a semiconductor device, comprising: forming n-channel field-effect transistors on a silicon substrate; forming a first insulating film covering the field-effect transistors; shrinking the first insulating film; forming a second insulating film over the first insulating film; and shrinking the second insulating film, wherein the forming an insulating film covering the field-effect transistors and the shrinking the insulating film are repeated a plurality of time.

Abstract: A method, system and scan lens for use therein are provided for high-speed, laser-based, precise laser trimming at least one electrical element along a trim path. The method includes generating a pulsed laser output with a laser, the output having one or more laser pulses at a repetition rate. A fast rise/fall time, pulse-shaped q-switched laser or an ultra-fast laser may be used. Beam shaping optics may be used to generate a flat-top beam profile. Each laser pulse has a pulse energy, a laser wavelength within a range of laser wavelengths, and a pulse duration. The wavelength is short enough to produce desired short-wavelength benefits of small spot size, tight tolerance, high absorption and reduced or eliminated heat-affected zone (HAZ) along the trim path, but not so short so as to cause microcracking. In this way, resistance drift after the trimming process is reduced.

Abstract: An SOI substrate having a single crystal semiconductor layer the surface of which has high planarity is manufactured. A semiconductor substrate is doped with hydrogen to form a damaged region containing a large amount of hydrogen. After a single crystal semiconductor substrate and a supporting substrate are bonded to each other, the semiconductor substrate is heated to separate the single crystal semiconductor substrate in the damaged region. While a heated high-purity nitrogen gas is sprayed on a separation surface of a single crystal semiconductor layer which is separated from the single crystal semiconductor substrate and irradiation with a microwave is performed from the back side of the supporting substrate, the separation surface is irradiated with a laser beam. The single crystal semiconductor layer is melted by irradiation with the laser beam, so that the surface of the single crystal semiconductor layer is planarized and re-single-crystallization thereof is performed.

Abstract: A light emitting device having a high degree of light extraction efficiency includes a substrate, and a light emitting structure disposed on one surface of the substrate, the substrate having an internal reformed region where the index of refraction differs from the remainder the substrate. The ratio of the depth of the reformed region (distance between the other surface of the substrate and the reformed region) to the thickness of the substrate is in a range of between 1/8 and 9/11.

Abstract: A method and apparatus for forming a crystalline semiconductor layer on a substrate are provided. A semiconductor layer is formed by vapor deposition. A pulsed laser melt/recrystallization process is performed to convert the semiconductor layer to a crystalline layer. Laser, or other electromagnetic radiation, pulses are formed into a pulse train and uniformly distributed over a treatment zone, and successive neighboring treatment zones are exposed to the pulse train to progressively convert the deposited material to crystalline material.

Abstract: The present invention generally relates to methods of controlling UV lamp output to increase irradiance uniformity. The methods generally include determining a baseline irradiance within a chamber, determining the relative irradiance on a substrate corresponding to a first lamp and a second lamp, and determining correction or compensation factors based on the relative irradiances and the baseline irradiance. The lamps are then adjusted via closed loop control using the correction or compensation factors to individually adjust the lamps to the desired output. The lamps may optionally be adjusted to equal irradiances prior to adjusting the lamps to the desired output. The closed loop control ensures process uniformity from substrate to substrate. The irradiance measurement and the correction or compensation factors allow for adjustment of lamp set points due to chamber component degradation, chamber component replacement, or chamber cleaning.

Abstract: Methods and substrates for laser annealing are disclosed. The substrate includes a target region to be annealed and a plurality of reflective interfaces. The reflective interfaces cause energy received by the substrate to resonate within the target region. The method includes emitting energy toward the substrate with a laser, receiving the energy with the substrate, and reflecting the received energy with a plurality of reflective interfaces embedded in the substrate to generate a resonance within the target region.

Abstract: A laser annealing method for executing laser annealing by irradiating a semiconductor film formed on a surface of a substrate with a laser beam, the method including the steps of, generating a linearly polarized rectangular laser beam whose cross section perpendicular to an advancing direction is a rectangle with an electric field directed toward a long-side direction of the rectangle or an elliptically polarized rectangular laser beam having a major axis directed toward a long-side direction, causing the rectangular laser beam to be introduced to the surface of the substrate, and setting a wavelength of the rectangular laser beam to a length which is about a desired size of a crystal grain in a standing wave direction.

Abstract: A device is intended for a laser lift-off method to sever at least one layer from a carrier. The device includes a laser that generates pulsed laser radiation and at least one beam splitter. The laser radiation is divided into at least two partial beams by the at least one beam splitter. The partial beams are superimposed in an irradiation plane, the irradiation plane being provided such that a major side of the carrier remote from the layer is arranged therein. At the irradiation plane, an angle (?) between the at least two partial beams is at least 1.0°.

Abstract: Provided is an organic EL display manufacturing method which has: a step wherein an organic EL panel having a substrate and organic EL elements arranged in matrix on the substrate is prepared, and each organic EL element is permitted to have a pixel electrode disposed on the substrate, an organic layer disposed on the pixel electrode, a transparent counter electrode disposed on the organic layer, a sealing layer disposed on the transparent counter electrode, and a color filter disposed on the sealing layer; a step of detecting a defective portion on the organic layer in the organic EL element; and a step of breaking the transparent counter electrode in a region on the defective portion of the transparent counter electrode by irradiating the region on the defective portion with a laser beam. The laser beam is radiated by being tilted with respect to the normal line on the display surface of the organic EL panel.

Abstract: An apparatus for heat treating semiconductor wafers is disclosed. The apparatus includes a heating device which contains an assembly linear lamps for emitting light energy onto a wafer. The linear lamps can be placed in various configurations. In accordance with the present invention, tuning devices which are used to adjust the overall irradiance distribution of the light energy sources are included in the heating device. The tuning devices can be, for instance, are lamps or lasers.

Abstract: A method for manufacturing is: forming an insulating film over a substrate; forming an amorphous semiconductor film over the insulating film; forming over the amorphous semiconductor film, a silicon nitride film in which a film thickness is equal to or more than 200 nm and equal to or less than 1000 nm, equal to or less than 10 atomic % of oxygen is included, and a relative proportion of nitrogen to silicon is equal to or more than 1.3 and equal to or less than 1.5; irradiating the amorphous semiconductor film with a continuous-wave laser light or a laser light with repetition rate of equal to or more than the wave length of 10 MHz transmitting the silicon nitride film to melt and later crystallize the amorphous semiconductor film to form a crystalline semiconductor film.

Abstract: In some embodiments of the invention, encapsulated semiconducting nanomaterials are described. In certain embodiments the nanostructures described are semiconducting nanomaterials encapsulated with ordered carbon shells. In some aspects a method for producing encapsulated semiconducting nanomaterials is disclosed. In some embodiments applications of encapsulated semiconducting nanomaterials are described.

Abstract: Embodiments of the invention relate to methods and apparatus for laser drilling holes in a silicon substrate during the fabrication of back contact solar cells, such as emitter-wrap-through (EWT) solar cells. In one embodiment, the method and apparatus use a short focal length flat field lens and a dynamic scanning technique to accomplish single pulse drilling in the silicon substrate. The method and apparatus result in increased speed and quality of holes in an EWT solar cell substrate as compared to conventional apparatus and processes.

Abstract: According to one embodiment, a resin removal method is provided. In the resin removal method, near-field light is generated in a local area of a pattern concave-convex portion on a pattern master used for imprinting by irradiating the pattern master with ultraviolet light in an ashing gas atmosphere which removes resin attached to the pattern master. Then, the resin is removed from the pattern master by using the ashing gas and the near-field light.

Abstract: A selective crystallization method includes placing a first substrate including first crystallization regions on a second substrate including second crystallization regions such that the first crystallization regions and the second crystallization regions are arranged alternately, and crystallizing the alternately-arranged first crystallization regions and the second crystallization regions with a laser beam. A laser crystallization apparatus can be used in the selective crystallization method.

Abstract: A thermal processing apparatus and method in which a first laser source, for example, a CO2 emitting at 10.6 ?m is focused onto a silicon wafer as a line beam and a second laser source, for example, a GaAs laser bar emitting at 808 nm is focused onto the wafer as a larger beam surrounding the line beam. The two beams are scanned in synchronism in the direction of the narrow dimension of the line beam to create a narrow heating pulse from the line beam when activated by the larger beam. The energy of GaAs radiation is greater than the silicon bandgap energy and creates free carriers. The energy of the CO2 radiation is less than the silicon bandgap energy so silicon is otherwise transparent to it, but the long wavelength radiation is absorbed by the free carriers.

Abstract: A method is provided for detecting laser optical paths in integrated circuit (IC) packages. The method provides an IC die encapsulated as a package in a compound of glass spheres and epoxy. Power is supplied to the IC. The IC is scanned with a laser. Typically, a laser wavelength is used that is minimally absorbed by the glass spheres in the epoxy compound of the IC package, and changes in current to the IC are detected. A detected current change is cross-referenced against a scanned IC package surface region. This process identifies an optical pathway underlying the scanned IC package surface region. In some aspects, this process leads to the identification of a glass sphere-collecting package structure underlying the optical pathway. Examples of a glass sphere-collecting structure might include an inner lead wire, lead frame edge, or die edge.

Abstract: An assembly method is disclosed that includes providing a substrate, securing a first semiconductor device on a first surface thereof, and superimposing at least a second semiconductor device at least partially over the first semiconductor device. An outer peripheral portion of the second semiconductor device overhangs both the first semiconductor device and the substrate. Discrete conductive elements are placed between the outer peripheral portion of the second semiconductor device and a second surface of the substrate. Intermediate portions of the discrete conductive elements pass outside of a side surface of the substrate. Assemblies and packaged semiconductor devices that are formed in accordance with the method are also disclosed.

Abstract: An optical device wafer processing method including a protective plate attaching step of attaching a transparent protective plate through a double-sided adhesive tape to the front side of a sapphire substrate constituting an optical device wafer, the double-sided adhesive tape being composed of a sheet capable of blocking ultraviolet radiation and adhesive layers formed on both sides of the sheet, wherein the adhesive force of each adhesive layer can be reduced by applying ultraviolet radiation; a sapphire substrate grinding step of grinding the back side of the sapphire substrate; a modified layer forming step of applying a laser beam to the sapphire substrate from the back side thereof to thereby form a modified layer in the sapphire substrate along each street; a protective plate removing step of removing the protective plate in the condition where the double-sided adhesive tape is left on the sapphire substrate; and a wafer dividing step of breaking the sapphire substrate along each street where the modif

Abstract: A device processing method for improving the die strength of a device divided from a semiconductor wafer. The device processing method includes a chamfering step of applying a pulsed laser beam having an absorption wavelength to the device along the periphery of the device to thereby chamfer the periphery of the device, wherein the pulse width of the pulsed laser beam to be applied in the chamfering step is set to 2 ns or less, and the peak energy density is set in the range of 5 to 200 GW/cm2.

Abstract: A carbon nanotube forming method including providing a target substrate to be processed, a catalytic metal layer being formed on a surface of the target substrate; producing catalytic fine metal particles whose surfaces are oxidized by action of an oxygen plasma on the catalytic metal layer at a temperature T1; and activating the oxidized surfaces of the catalytic fine metal particles by reducing the oxidized surfaces of the catalytic fine metal particles by action of a hydrogen plasma on the catalytic fine metal particles at a temperature T2 higher than the temperature T1. The method further includes growing a carbon nanotube on the activated catalytic fine metal particles by thermal CVD at a temperature T3.

Abstract: Provided is a forming device and method making it possible to obtain a low-temperature polysilicon film in which the size of crystal grains fluctuates minimally, and is uniform. A mask has laser-light-blocking areas and laser-light-transmission areas arranged in the form of a grid such that the light-blocking areas and transmission areas are not adjacent to one another. Laser light is directed by the microlenses through the masks to planned channel-area-formation areas. The laser light transmitted by the transmission areas is directed onto an a-Si:H film, annealing and polycrystallzing the irradiated parts thereof. The mask is then removed, and when the entire planned channel-area-formation area is irradiated with laser light, the already-polycrystallized area, having a higher melting point, does not melt, while the area in an amorphous state melts and solidifies, leading to polycrystallization.

Abstract: A laser processing method for a semiconductor wafer including a groove forming step of applying a pulsed laser beam having an absorption wavelength to the semiconductor wafer along a division line formed on the semiconductor wafer to thereby form a laser processed groove along the division lines on the semiconductor wafer, wherein the pulse width of the pulsed laser beam to be applied in the groove forming step is set to 2 ns or less, and the peak energy density is set in the range of 5 to 200 GW/cm2.

Abstract: A method of dicing a semiconductor wafer includes forming a layer stack on a first main surface of a substrate. The layer stack and a portion of the substrate are etched according to a pattern defining an intended dicing location to obtain a trench structure. The substrate is irradiated with a laser beam to locally modify the substrate between a bottom of the trench structure and a second main surface of the substrate opposite to the first main surface.

Abstract: A method provides forming a photovoltaic (PV) cell. The PV cell may be, e.g. a heterojunction with intrinsic thin layer (HIT) cell. The method includes forming a crystalline semiconductor layer over a substrate. The crystalline semiconductor layer is heated above a melting temperature of the semiconductor. A portion of the crystalline semiconductor layer is thereby converted to a quenched amorphous semiconductor layer.

Abstract: The present invention provides a semiconductor device formed over an insulating substrate, typically a semiconductor device having a structure in which mounting strength to a wiring board can be increased in an optical sensor, a solar battery, or a circuit using a TFT, and which can make it mount on a wiring board with high density, and further a method for manufacturing the same. According to the present invention, in a semiconductor device, a semiconductor element is formed on an insulating substrate, a concave portion is formed on a side face of the semiconductor device, and a conductive film electrically connected to the semiconductor element is formed in the concave portion.

Abstract: A method for manufacturing a semiconductor device includes forming a hard mask pattern and a spacer at both sides of the hard mask pattern. The method also includes forming a spacer pattern, so that the spacer remains in one direction to form a spacer pattern, forming a photoresist pattern having a pad type overlapping a side of the spacer pattern, and etching an underlying layer, with the photoresist pattern and the spacer pattern as a mask, to form an isolated pattern. The method improves resolution and process margins to obtain a highly-integrated transistor.

Abstract: A mask for crystallizing a semiconductor layer includes a plurality of first main-slit portions, a plurality of second main-slit portions, upper slit portion and lower slit portion. The first main-slit portions extend along an inclined direction with respect to a first direction. The second main-slit portions are spaced apart from the first main-slit portions. The upper slit portion is disposed on the first main-slit portions along a second direction to be parallel to the first main-slit portions, and extends partway over the second main-slit portions to be longer than the first main-slit portions. The lower slit portion is disposed under the second main-slit portions along the second direction to be parallel to the second main-slit portions, and extends partway under the first main-slit portions to be longer than the second main-slit portions.

Abstract: The present invention is a system and method for laser-assisted singulation of light emitting electronic devices manufactured on a substrate, having a processing surface and a depth extending from the processing surface. It includes providing a laser processing system having a picosecond laser having controllable parameters; controlling the laser parameters to form light pulses from the picosecond laser, to form a modified region having a depth which spans about 50% of the depth and substantially including the processing surface of the substrate and having a width less than about 5% of the region depth; and, singulating the substrate by applying mechanical stress to the substrate thereby cleaving the substrate into said light emitting electronic devices having sidewalls formed at least partially in cooperation with the linear modified regions.

Abstract: One embodiment of the present invention provides a semiconductor device manufacturing method, including: performing a laser spike annealing, by irradiating light, whose wavelength is 10 ?m to 11 ?m, onto a semiconductor substrate including: an active area; a circuit pattern; and a dummy pattern formed at a position, whose distance from an end of the active area is equal to or more than 10 ?m and equal to or less than 11 ?m, at a pitch equal to or more than 10 nm and equal to or less than 510 nm, while setting an angle formed between an arrangement direction of the dummy pattern and a projection direction of the light to be equal to or more than 0° and equal to or less than 30°.

Abstract: A wafer of light emitting diodes (LEDs) is laser scribed to produce a laser scribing cut. Then, the wafer is cleaned, for example by wet etching, to reduce scribe damage. Then, electrical contact layers for the LEDs are formed on the wafer that has been cleaned. Alternatively, the scribing cut may be produced by multiple etches before contact formation. Related LEDs are also described.

Abstract: A method for irradiating semiconductor material is provided which includes selecting a region of a semiconductor layer surface, irradiating the region with an excimer laser which has a beam spot size, and adjusting the beam spot size to match the selected region size. Further, an apparatus for irradiating semiconductor material is provided. The apparatus includes an excimer laser for irradiating a selected region of a semiconductor layer surface, the laser has a laser beam spot size, and a system for adjusting the laser beam spot size to match the selected region size.

Abstract: A method and apparatus for implanting a semiconductor substrate with boron clusters. A substrate is implanted with octadecaborane by plasma immersion or ion beam implantation. The substrate surface is then annealed to completely dissociate and activate the boron clusters. The annealing may take place by melting the implanted regions or by a sub-melt annealing process.

Abstract: A method for irradiating a plate (104) using multiple co-located radiation sources (108-1,108-2,108-3,108-4) includes that each of the multiple co-located radiation sources (108-1,108-2,108-3,108-4) is responsible for irradiating one of a plurality of bounded sub-regions (110-1,110-2,110-3,110-4) in the plate (104). As a result, sub-regions of the plate (104) that are to be irradiated receive relatively even, relatively well-defined radiation from the multiple co-located radiation sources (108-1,108-2,108-3,108-4). An apparatus performs the method, and a solar cell is produced using the method. The method and the apparatus can be applied in laser doping and laser cutting.

Abstract: A method for fabricating semiconductor components includes the steps of providing a semiconductor substrate having a circuit side, a back side and integrated circuits and circuitry on the circuit side; thinning the substrate from the back side to a selected thickness; laser processing the back side of the thinned substrate to form at least one lasered feature on the back side; and dicing the substrate into a plurality of components having the lasered feature. The lasered feature can cover the entire back side or only selected areas of the back side, and can be configured to change electrical properties, mechanical properties or gettering properties of the substrate. A semiconductor component includes a thinned semiconductor substrate having a back side and a circuit side containing integrated circuits and associated circuitry. The semiconductor component also includes at least one lasered feature on the back side configured to provide selected electrical or physical characteristics for the substrate.

Abstract: A laser processing method comprises a laser light converging step of converging a laser light at a sheet-like object to be processed made of silicon so as to form a modified region within the object, and an etching step of anisotropically etching the object so as to thin the object to a target thickness and advancing the etching selectively along the modified region so as to form the object with a through hole tilted with respect to a thickness direction of the object after the laser light converging step, wherein the laser light converging step forms a first modified region as the modified region in a part corresponding to the through hole in the object and a second modified region as the modified region extending parallel to the thickness direction and joining with the first modified region in a part to be removed upon thinning by the anisotropic etching in the object, and wherein the etching step advances the etching selectively along the second modified region and then along the first modified region whil

Abstract: A crystallization apparatus, which uses sequential lateral solidification (SLS) and crystallizes an amorphous silicon layer formed on a substrate, includes a laser generating device, a first optical system, a second optical system, and a path switching member. The laser generating device is configured to emit a laser beam. The first optical system is configured to process the laser beam emitted from the laser generating device and to irradiate the processed laser beam onto the substrate. The second optical system is parallel to the first optical system and is configured to process the laser beam emitted from the laser generating device and to irradiate the processed laser beam onto the substrate. The path switching member is configured to switch a path of the laser beam emitted from the laser generating device and to alternately distribute the laser beam to the first and second optical systems.

Abstract: Disclosed are a method for fabricating a flexible electronic device using laser lift-off and an electronic device fabricated thereby. More particularly, disclosed are a method for fabricating a flexible electronic device using laser lift-off allowing for fabrication of a flexible electronic device in an economical and stable way by separating a device such as a secondary battery fabricated on a sacrificial substrate using laser, and an electronic device fabricated thereby.

Abstract: An embodiment is a method and apparatus to fabricate a flat panel display. A poly-last structure is formed for a display panel using an amorphous silicon or amorphous silicon compatible process. The poly-last structure has a channel silicon precursor. The display panel is formed from the poly-last structure using a polysilicon specific or polysilicon compatible process.

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: Provided herein are methods and systems for scribing solar cell structures to create isolated solar cells. According to various embodiments, the methods involve scanning an excimer laser beam along a scribe line of a solar cell structure to ablate electrically active layers of the structure. A photomask having variable transmittance is disposed between the beam source and the solar cell structure. The transmittance is calibrated to produce variable fluence levels such that a stepped scribed profile is obtained. In certain embodiments, a front contact/absorber/back contact stack is removed along a portion of the scribe line, while a front contact/absorber stack is simultaneously removed along a parallel portion, with the back contact layer unremoved. In this manner, the scribe electrically isolates solar cells on either side of the scribe line, while providing a contact point to the back contact layer of one of the solar cells for subsequent cell-cell interconnection.