Abstract: An auxiliary excitation light source unit 50 is a portable one having a size capable of being held by one hand. The auxiliary excitation light source unit 50 includes an auxiliary excitation light source 51 including a high-power LED in a casing 57. The auxiliary excitation light source 51 emits near-infrared light that is excitation light adapted for exciting indocyanine green and whose wavelength is 760 nm. In front of the auxiliary excitation light source 51, a lowpass filter 53 for blocking light having a wavelength corresponding to the wavelength of fluorescence emitted from indocyanine green is disposed.

Abstract: The present invention comprises a light modulation optical system having a first element which forms a desired light intensity gradient distribution to an incident light beam and a second element which forms a desired light intensity minimum distribution with an inverse peak shape to the same, and an image formation optical system which is provided between the light modulation optical system and a substrate having a polycrystal semiconductor film or an amorphous semiconductor film, wherein the incident light beam to which the light intensity gradient distribution and the light intensity minimum distribution are formed is applied to the polycrystal semiconductor film or the amorphous semiconductor film through the image formation optical system, thereby crystallizing a non-crystal semiconductor film. The pattern of the first element is opposed to the pattern of the second element.

Abstract: Exact alignment of a recrystallized region, which is to be formed in an amorphous or polycrystalline film, is facilitated. An alignment mark is formed, which is usable in a step of forming an electronic device, such as a thin-film transistor, in the recrystallized region. In addition, in a step of obtaining a large-grain-sized crystal-phase semiconductor from a semiconductor film, a mark structure that is usable as an alignment mark in a subsequent step is formed on the semiconductor film in the same exposure step. Thus, the invention includes a light intensity modulation structure that modulates light and forms a light intensity distribution for crystallization, and a mark forming structure that modulates light and forms a light intensity distribution including a pattern with a predetermined shape, and also forms a mark indicative of a predetermined position on a crystallized region.

Abstract: A crystallization apparatus is provided. The crystallization apparatus includes a visible light source capable of obtaining high energy density output therein. A visible light irradiation system is formed by a plurality of visible laser beam sources arranged in a two-dimensional array. The visible light irradiation system includes a light intensity distribution forming apparatus for patterning light intensity distribution of a plurality of visible laser beams emitted by each visible laser beam source, and an imaging optical system for imaging the light having the light intensity distribution patterned by the light intensity distribution forming apparatus onto an irradiated region on the processed substrate. The visible laser beams emitted by a plurality of solid lasers or semiconductor lasers are overlapped in the light intensity distribution forming apparatus that satisfies an imaging position relationship in an optical axis with respect to the processed substrate.

Abstract: A crystallization apparatus is provided. In the crystallization apparatus, a light intensity distribution formed by a light modulation device or a metal aperture and transferred to a processed substrate can be visualized. The crystallization apparatus has an ultraviolet (UV) irradiation system and a visible light irradiation system. The UV irradiation system irradiates pulses of laser beam in the UV range to the processed substrate. The visible light irradiation system continuously irradiates a visible light laser beam on the same irradiated region on the processed substrate. In a melted region resulted from the uniform irradiation of the laser beam in the UV range, the light intensity distribution of the visible laser beam is used to form crystal growth. The crystallization apparatus irradiates pulses of the laser beam in the UV range to melt the processed substrate, and continuously irradiates the visible light laser beam to crystallize the processed substrate.

Abstract: Exact alignment of a recrystallized region, which is to be formed in an amorphous or polycrystalline film, is facilitated. An alignment mark is formed, which is usable in a step of forming an electronic device, such as a thin-film transistor, in the recrystallized region. In addition, in a step of obtaining a large-grain-sized crystal-phase semiconductor from a semiconductor film, a mark structure that is usable as an alignment mark in a subsequent step is formed on the semiconductor film in the same exposure step. Thus, the invention includes a light intensity modulation structure that modulates light and forms a light intensity distribution for crystallization, and a mark forming structure that modulates light and forms a light intensity distribution including a pattern with a predetermined shape, and also forms a mark indicative of a predetermined position on a crystallized region.

Abstract: The present invention comprises a light modulation optical system having a first element which forms a desired light intensity gradient distribution to an incident light beam and a second element which forms a desired light intensity minimum distribution with an inverse peak shape to the same, and an image formation optical system which is provided between the light modulation optical system and a substrate having a polycrystal semiconductor film or an amorphous semiconductor film, wherein the incident light beam to which the light intensity gradient distribution and the light intensity minimum distribution are formed is applied to the polycrystal semiconductor film or the amorphous semiconductor film through the image formation optical system, thereby crystallizing a non-crystal semiconductor film. The pattern of the first element is opposed to the pattern of the second element.

Abstract: The present invention comprises a light modulation optical system having a first element which forms a desired light intensity gradient distribution to an incident light beam and a second element which forms a desired light intensity minimum distribution with an inverse peak shape to the same, and an image formation optical system which is provided between the light modulation optical system and a substrate having a polycrystal semiconductor film or an amorphous semiconductor film, wherein the incident light beam to which the light intensity gradient distribution and the light intensity minimum distribution are formed is applied to the polycrystal semiconductor film or the amorphous semiconductor film through the image formation optical system, thereby crystallizing a non-crystal semiconductor film. The pattern of the first element is opposed to the pattern of the second element.

Abstract: A generation method of a light intensity distribution uses a first light modulation element and a second light modulation element which are arranged to be apart from each other by a distance D and face each other in parallel to optically modulate a light beam which enters the light modulation elements, thereby generating a light intensity distribution on a target surface. The first light modulation element has a pattern formed by repeating a basic unit having a pitch P. The distance D is set to a distance with which the light intensity distribution generated on the predetermined surface is not changed even if a relative position of the first light modulation element and the second light modulation element is shifted in a plane direction.

Abstract: A crystallization apparatus is provided. In the crystallization apparatus, a light intensity distribution formed by a light modulation device or a metal aperture and transferred to a processed substrate can be visualized. The crystallization apparatus has an ultraviolet (UV) irradiation system and a visible light irradiation system. The UV irradiation system irradiates pulses of laser beam in the UV range to the processed substrate. The visible light irradiation system continuously irradiates a visible light laser beam on the same irradiated region on the processed substrate. In a melted region resulted from the uniform irradiation of the laser beam in the UV range, the light intensity distribution of the visible laser beam is used to form crystal growth. The crystallization apparatus irradiates pulses of the laser beam in the UV range to melt the processed substrate, and continuously irradiates the visible light laser beam to crystallize the processed substrate.

Abstract: A crystallization apparatus is provided. The crystallization apparatus includes a visible light source capable of obtaining high energy density output therein. A visible light irradiation system is formed by a plurality of visible laser beam sources arranged in a two-dimensional array. The visible light irradiation system includes a light intensity distribution forming apparatus for patterning light intensity distribution of a plurality of visible laser beams emitted by each visible laser beam source, and an imaging optical system for imaging the light having the light intensity distribution patterned by the light intensity distribution forming apparatus onto an irradiated region on the processed substrate. The visible laser beams emitted by a plurality of solid lasers or semiconductor lasers are overlapped in the light intensity distribution forming apparatus that satisfies an imaging position relationship in an optical axis with respect to the processed substrate.

Abstract: In a laser processing method and a laser processing apparatus which irradiate a processing target body with a laser beam pulse-oscillated from a laser beam source, a processing state is monitored by a photodetector, and the laser beam source is again subjected to oscillation control on the moment when erroneous laser irradiation is detected, thereby performing laser processing. Further, in a laser crystallization method and a laser crystallization apparatus using a pulse-oscillated excimer laser, a homogenizing optical system, an optical element and a half mirror are arranged in an optical path, light from the half mirror is detected by a photodetector, and a light intensity insufficient irradiation position is again irradiated with a laser beam to perform crystallization when the detection value does not fall within a range of a predetermined specified value.

Abstract: A manufacturing method of an electronic device includes positioning a processed substrate with respect to a substrate stage of a crystallization apparatus and supporting it with at least one positioning mark previously provided on the processed substrate being used as a references, applying a modulated light beam to a predetermined area of the processed substrate supported by the substrate stage and crystallizing the area, and forming at least one circuit element in the crystallized area of the processed substrate subjected to positioning with the positioning mark being used as a reference.

Abstract: A manufacturing method of an electronic device includes positioning a processed substrate with respect to a substrate stage of a crystallization apparatus and supporting it with at least one positioning mark previously provided on the processed substrate being used as a references, applying a modulated light beam to a predetermined area of the processed substrate supported by the substrate stage and crystallizing the area, and forming at least one circuit element in the crystallized area of the processed substrate subjected to positioning with the positioning mark being used as a reference.

Abstract: In a laser processing method and a laser processing apparatus which irradiate a processing target body with a laser beam pulse-oscillated from a laser beam source, a processing state is monitored by a photodetector, and the laser beam source is again subjected to oscillation control on the moment when erroneous laser irradiation is detected, thereby performing laser processing. Further, in a laser crystallization method and a laser crystallization apparatus using a pulseoscillated excimer laser, a homogenizing optical system, an optical element and a half mirror are arranged in an optical path, light from the half mirror is detected by a photodetector, and a light intensity insufficient irradiation position is again irradiated with a laser beam to perform crystallization when the detection value does not fall within a range of a predetermined specified value.

Abstract: The present invention comprises a light modulation optical system having a first element which forms a desired light intensity gradient distribution to an incident light beam and a second element which forms a desired light intensity minimum distribution with an inverse peak shape to the same, and an image formation optical system which is provided between the light modulation optical system and a substrate having a polycrystal semiconductor film or an amorphous semiconductor film, wherein the incident light beam to which the light intensity gradient distribution and the light intensity minimum distribution are formed is applied to the polycrystal semiconductor film or the amorphous semiconductor film through the image formation optical system, thereby crystallizing a non-crystal semiconductor film. The pattern of the first element is opposed to the pattern of the second element.

Abstract: In a laser processing method and a laser processing apparatus which irradiate a processing target body with a laser beam pulse-oscillated from a laser beam source, a processing state is monitored by a photodetector, and the laser beam source is again subjected to oscillation control on the moment when erroneous laser irradiation is detected, thereby performing laser processing. Further, in a laser crystallization method and a laser crystallization apparatus using a pulse-oscillated excimer laser, a homogenizing optical system, an optical element and a half mirror are arranged in an optical path, light from the half mirror is detected by a photodetector, and a light intensity insufficient irradiation position is again irradiated with a laser beam to perform crystallization when the detection value does not fall within a range of a predetermined specified value.

Abstract: The present invention comprises a light modulation optical system having a first element which forms a desired light intensity gradient distribution to an incident light beam and a second element which forms a desired light intensity minimum distribution with an inverse peak shape to the same, and an image formation optical system which is provided between the light modulation optical system and a substrate having a polycrystal semiconductor film or an amorphous semiconductor film, wherein the incident light beam to which the light intensity gradient distribution and the light intensity minimum distribution are formed is applied to the polycrystal semiconductor film or the amorphous semiconductor film through the image formation optical system, thereby crystallizing a non-crystal semiconductor film. The pattern of the first element is opposed to the pattern of the second element.

Abstract: A knife edge is disposed at a height corresponding to a section on which a sectional image (light intensity distribution) is picked up in such a manner as to intercept a part of the section of the laser light. The knife edge is irradiated with the laser light, and the sectional image of the laser light is enlarged with an image forming optics, and is picked up by a CCD. While picking up the sectional image in this manner, focusing of the image forming optics is performed. Next, the knife edge is retracted from the optical path of the laser light, the laser light is allowed to enter the CCD via the image forming optics, and the sectional image of the laser light is picked up.

Abstract: A generation method of a light intensity distribution uses a first light modulation element and a second light modulation element which are arranged to be apart from each other by a distance D and face each other in parallel to optically modulate a light beam which enters the light modulation elements, thereby generating a light intensity distribution on a target surface. The first light modulation element has a pattern formed by repeating a basic unit having a pitch P. The distance D is set to a distance with which the light intensity distribution generated on the predetermined surface is not changed even if a relative position of the first light modulation element and the second light modulation element is shifted in a plane direction.