Abstract: Process and system for processing a thin film sample, as well as at least one portion of the thin film structure are provided. Irradiation beam pulses can be shaped to define at least one line-type beam pulse, which includes a leading portion, a top portion and a trailing portion, in which at least one part has an intensity sufficient to at least partially melt a film sample. Irradiating a first portion of the film sample to at least partially melt the first portion, and allowing the first portion to resolidify and crystallize to form an approximately uniform area therein. After the irradiation of the first portion of the film sample, irradiating a second portion using a second one of the line-type beam pulses to at least partially melt the second portion, and allowing the second portion to resolidify and crystallize to form an approximately uniform area therein.

Abstract: Process and system for processing a thin film sample, as well as at least one portion of the thin film structure are provided. Irradiation beam pulses can be shaped to define at least one line-type beam pulse, which includes a leading portion, a top portion and a trailing portion, in which at least one part has an intensity sufficient to at least partially melt a film sample. Irradiating a first portion of the film sample to at least partially melt the first portion, and allowing the first portion to resolidify and crystallize to form an approximately uniform area therein. After the irradiation of the first portion of the film sample, irradiating a second portion using a second one of the line-type beam pulses to at least partially melt the second portion, and allowing the second portion to resolidify and crystallize to form an approximately uniform area therein.

Abstract: Process and system for processing a thin film sample, as well as at least one portion of the thin film structure are provided. Irradiation beam pulses can be shaped to define at least one line-type beam pulse, which includes a leading portion, a top portion and a trailing portion, in which at least one part has an intensity sufficient to at least partially melt a film sample. Irradiating a first portion of the film sample to at least partially melt the first portion, and allowing the first portion to resolidify and crystallize to form an approximately uniform area therein. After the irradiation of the first portion of the film sample, irradiating a second portion using a second one of the line-type beam pulses to at least partially melt the second portion, and allowing the second portion to resolidify and crystallize to form an approximately uniform area therein.

Abstract: In a silicon crystallization method, a pulse is delivered from each of two excimer lasers. The duration of one of the pulses is extended in a pulse-duration extender to a duration significantly longer than that of that of the other. The extended-duration and other pulses are delivered along a common path. The other pulse temporally overlaps the extended-duration pulse after delivery of the extended-duration pulse begins. The silicon is preheated by the extended-duration before being melted by the combined pulses during the temporal overlap period.

Abstract: A method of processing a polycrystalline film on a substrate includes generating laser pulses, directing the laser pulses through a mask to generate patterned laser beams, each having a length l?, a width w?, and a spacing between adjacent beams d?; irradiating a region of the film with the patterned beams, said beams having an intensity sufficient to melt and to induce crystallization of the irradiated portion of the film, wherein the film region is irradiated n times; and after irradiation of each film portion, translating the film and/or the mask, in the x- and y-directions. The distance of translation in the y-direction is about l?/n??, where ? is a value selected to overlap the beamlets from one irradiation step to the next. The distance of translation in the x-direction is selected such that the film is moved a distance of about ?? after n irradiations, where ??=w?+d?.

Abstract: A method of processing a polycrystalline film on a substrate includes generating a plurality of laser beam pulses, positioning the film on a support capable of movement in at least one direction, directing the plurality of laser beam pulses through a mask to generate patterned laser beams; each of said beams having a length l?, a width w? and a spacing between adjacent beams d?, irradiating a region of the film with the patterned beams, said beams having an intensity that is sufficient to melt an irradiated portion of the film to induce crystallization of the irradiated portion of the film, wherein the film region is irradiated n times; and after irradiation of each film portion, translating either the film or the mask, or both, a distance in the x- and y-directions, where the distance of translation in the y-direction is in the range of about 1?/n-?, where ? is a value selected to form overlapping the beamlets from the one irradiation step to the next, and where the distance of translation in the x-direction

Abstract: Methods of making a polycrystalline silicon thin-film transistor having a uniform microstructure. One exemplary method requires receiving a polycrystalline silicon thin film having a grain structure which is periodic in at least a first direction, and placing at least portions (410, 420) of one or more thin-film transistors on the received film such that they are tilted relative to the periodic structure of the thin film.