Abstract: A crystallization apparatus of the present invention irradiates a non-single-crystal semiconductor film with a luminous flux having a predetermined light intensity distribution to crystallize the film, and comprises a phase modulation device comprising a plurality of unit areas which are arranged in a certain period and which mutually have substantially the same pattern, and an optical image forming system disposed between the phase modulation device and the non-single-crystal semiconductor film. The unit area of the phase modulation device has a reference face having a certain phase, a first area disposed in the vicinity of a center of each unit area and having a first phase difference with respect to the reference face, and a second area disposed in the vicinity of the first area and having substantially the same phase difference as that of the first phase difference with respect to the reference face.

Abstract: A light irradiation apparatus includes a light modulation element which has a phase step having a phase difference substantially different from 180°, an illumination optical system which illuminates the light modulation element, and an image formation optical system which forms, on an irradiation surface, a light intensity distribution based on a light beam phase-modulated by the light modulation element. The illumination optical system illuminates the light modulation element with an illumination light beam inclined in a direction normal to a step line of the phase step.

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 method of manufacturing a semiconductor device includes irradiating a region to be crystallized of a non-monocrystalline semiconductor film with laser beam modulated by an optical modulator to have light intensity distribution having a minimum light intensity line or minimum light intensity spot to crystallize the region, and heating the crystallized region by irradiating light from a flash lamp onto the crystallized region.

Abstract: A crystallizing method of causing a phase shifter to phase-modulate a laser beam whose wavelength is 248 nm or 300 nm or more from an excimer laser unit into a laser beam with a light intensity profile having a plurality of inverted triangular peak patterns in cross section and of irradiating the pulse laser beam onto a substrate to be crystallized for crystallization. The substrate to be crystallized is such that one or more silicon oxide films which present absorption properties to the laser beam and differ in the relative proportions of Si and O are provided on a laser beam incident face.

Abstract: Disclosed are apparatus for forming a semiconductor film having an excellent crystallinity from a non-single crystal semiconducting layer formed on a base layer made of an insulating material. The apparatus includes a light source, a homogenizer for homogenizing an intensity distribution of the emitted light, an amplitude-modulation means for performing the amplitude-modulation such that the amplitude of the light, of which the intensity distribution is homogenized, is increased in the direction of the relative motion of the light to the base layer, an optional light projection optical system for projecting the amplitude-modulated light onto the surface of the non-single crystal semiconductor such that a predetermined irradiation energy can be obtained, a phase shifter for providing a low temperature point in the surface irradiated by the light, and a substrate stage to move the light relative to the substrate thereby enabling scanning in the X and Y axis.

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 method for producing a thin film semiconductor device is described. In the method, a thin film layer of non-single-crystalline semiconductor, which is deposited on a base layer of glass, is processed to an island-shaped thin film layer at the time prior to the layer irradiation step. The laser irradiation to the thin film layer of non-single-crystalline semiconductor is carried out after forming an insulation film layer and a gate electrode over the island-shaped thin film layer, by using the gate electrode as the irradiation mask, whereby the center area of the island-shaped thin film layer masked by the gate electrode is crystallized, and simultaneously, the both side areas thereof which is not masked by the gate electrode are annealed. Next, a source electrode and a drain electrode is formed in the annealed areas. The implantation of impurity ion may be carried out either before or after the laser irradiation.

Abstract: Methods for forming a single crystal semiconductor thin film layer from a non-single crystal layer includes directing a light source having a homogenized intensity distribution and a modulated amplitude towards the non-single crystal layer, and relatively moving the light with respect to the layer wherein the amplitude of the conditioned light is preferably increased in the direction of relative motion of the light to the layer. Preferred methods also include multiple light exposures in overlapping series to form ribbon-shaped single crystal regions, and providing a low temperature point in the semiconductor layer to generate a starting location for single crystalization.

Abstract: A light application apparatus includes an optical modulation element provided with a plurality of phase steps, a light beam which is entered into the optical modulation element being phase-modulated by the phase steps and exits from the optical modulation element as a light beam having a first light intensity distribution. An optical system is arranged between the optical modulation element and an predetermined plane. The optical system divides the phase-modulated light beam into at least two light fluxes having second and third light intensity distributions and different optical characteristics from each other, and projects a light beam including the divided two light fluxes, the light intensity distributions of the projected light fluxes being combined with each other, so that the projected light beam has a fourth light intensity distribution with an inverse peak shape on the predetermined plane and enters the predetermined plane.

Abstract: A method for producing a thin film semiconductor device is described. In the method, a thin film layer of non-single-crystalline semiconductor, which is deposited on a base layer of glass, is processed to an island-shaped thin film layer at the time prior to the layer irradiation step. The laser irradiation to the thin film layer of non-single-crystalline semiconductor is carried out after forming an insulation film layer and a gate electrode over the island-shaped thin film layer, by using the gate electrode as the irradiation mask, whereby the center area of the island-shaped thin film layer masked by the gate electrode is crystallized, and simultaneously, the both side areas thereof which is not masked by the gate electrode are annealed. Next, a source electrode and a drain electrode is formed in the annealed areas. The implantation of impurity ion may be carried out either before or after the laser irradiation.

Abstract: A thin film transistor includes a one conductive type semiconductor layer; a source region and a drain region which are separately provided in the semiconductor layer; and a gate electrode provided above or below the semiconductor layer with an insulating film interposed therebetween, wherein the width of the junction face between the source region and the channel which is provided between the source region and drain region, is different from the width of the junction face between the above channel region and the drain region.

Abstract: The semiconductor device according to the present invention has a semiconductor layer having not smaller than two types of crystal grains different in size within a semiconductor circuit on a same substrate.

Abstract: A thin film semiconductor device includes a gate electrode insulator formed through high-heat oxidization of a semiconductor film. The high-heat oxidization of semiconductor film is carried out, in the process of crystallization or recrystallization of non-single-crystalline semiconductor thin film on a base layer, by irradiating predetermined areas of the thin film which is implanted with oxygen ion before irradiation, to convert such areas to oxidized areas, and these areas are processed to gate electrode insulators of electric circuit units in the thin film semiconductor device.

Abstract: A thin film semiconductor device and a method for producing it are described. In the thin film layer of semiconductor of the device, a plurality of large size single-crystalline grains of semiconductor are formed in a regulated configuration, and each of single crystalline grains is equipped with one unit of electric circuit having a gate electrode, a source electrode and drain electrode. Such regulated arrangement of large size single-crystalline grains in the semiconductor layer is realized by a process including a step of irradiating the layer of amorphous or polycrystalline semiconductor with energy beam such as excimer laser so that maximum irradiation intensity points and minimum irradiation intensity points are arranged regulatedly. The device can have a high mobility such as about 500 cm2/V sec.

Abstract: The semiconductor device according to the present invention has a semiconductor layer having not smaller than two types of crystal grains different in size within a semiconductor circuit on a same substrate.

Abstract: A crystallization apparatus includes an illumination system which illuminates a phase-shift mask and an image-forming optical system arranged in an optical path between the phase-shift mask and a semiconductor film. The semiconductor film is irradiated with a light beam having a light intensity distribution of inverted peak patterns whose light intensity is the lowest in portions corresponding to phase shift sections to form a crystallized semiconductor film. The image-forming optical system is located to optically conjugate the phase-shift mask and the semiconductor film and has an aberration corresponding to the given wavelength range to form a light intensity distribution of inverted peak patterns with no swell of intensity in the middle portion.

Abstract: A thin-film semiconductor substrate includes an insulative substrate, an amorphous semiconductor thin film that is formed on the insulative substrate, and a plurality of alignment marks that are located on the semiconductor thin film and are indicative of reference positions for crystallization.

Abstract: There are provided a crystallization method which can design laser beam having a light intensity and a distribution optimized on an incident surface of a substrate, form a desired crystallized structure while suppressing generation of any other undesirable structure area and satisfy a demand for low-temperature processing, a crystallization apparatus, a thin film transistor and a display apparatus. When crystallizing a non-single-crystal semiconductor thin film by irradiating laser beam thereto, irradiation light beam to the non-single-crystal semiconductor thin film have a light intensity with a light intensity distribution which cyclically repeats a monotonous increase and a monotonous decrease and a light intensity which melts the non-single-crystal semiconductor. Further, at least a silicon oxide film is provided on a laser beam incident surface of the non-single-crystal semiconductor film.

Abstract: A thin film semiconductor device and a method for producing it are described. In the thin film layer of semiconductor of the device, a plurality of large size single-crystalline grains of semiconductor are formed in a regulated configuration, and each of single crystalline grains is equipped with one unit of electric circuit having a gate electrode, a source electrode and drain electrode. Such regulated arrangement of large size single-crystalline grains in the semiconductor layer is realized by a process including a step of irradiating the layer of amorphous or polycrystalline semiconductor with energy beam such as excimer laser so that maximum irradiation intensity points and minimum irradiation intensity points are arranged regulatedly. The device can have a high mobility such as about 500 cm2/V sec.