Abstract: A method of producing a thin film transistor comprises irradiating a resist on a glass base plate with a ray from a light source through a mask and, thereafter, developing the resist to form contact holes, using an i-ray as the ray.

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: A crystallization method includes wavefront-dividing an incident light beam into a plurality of light beams, condensing the wavefront-divided light beams in a corresponding phase shift portion of a phase shift mask or in the vicinity of the phase shift portion to form a light beam having an light intensity distribution of an inverse peak pattern in which a light intensity is minimum in a point corresponding to the phase shift portion of the phase shift mask, and irradiating a polycrystalline semiconductor film or an amorphous semiconductor film with the light beam having the light intensity distribution to produce a crystallized semiconductor film.

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: A method of manufacturing a thin-film semiconductor device substrate includes a step of forming a non-single crystalline semiconductor thin film on a base layer, and an annealing step of irradiating the non-single crystalline semiconductor thin film with an energy beam to enhance crystallinity of a non-single crystalline semiconductor constituting the non-single crystalline semiconductor thin film. The annealing step includes simultaneously irradiating the non-single crystalline semiconductor thin film with a plurality of energy beams to form a plurality of unit regions each including at least one irradiated region irradiated with the energy beam and at least one non-irradiated region that is not irradiated with the energy beam.

Abstract: A crystallization apparatus includes an optical illumination system to illuminate a phase shift mask and which irradiates an amorphous semiconductor film with a light beam having an inverse peak type light intensity distribution including a minimum light intensity in a point corresponding to a phase shift portion of the phase shift mask to produce a crystallized semiconductor film. A wavefront dividing element is disposed on a light path between the optical illumination system and the phase shift mask. The wavefront dividing element wavefront-divides the light beam supplied from the optical illumination system into a plurality of light beams, and condenses the wavefront-divided light beams in the corresponding phase shift portion or in the vicinity of the portion.

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 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 method of manufacturing a thin-film semiconductor device substrate includes a step of forming a non-single crystalline semiconductor thin film on a base layer, and an annealing step of irradiating the non-single crystalline semiconductor thin film with an energy beam to enhance crystallinity of a non-single crystalline semiconductor constituting the non-single crystalline semiconductor thin film. The annealing step includes simultaneously irradiating the non-single crystalline semiconductor thin film with a plurality of energy beams to form a plurality of unit regions each including at least one irradiated region irradiated with the energy beam and at least one non-irradiated region that is not irradiated with the energy beam.

Abstract: A laser anneal apparatus is provided with a laser source; a homogenizing optical system disposed in an optical path of laser light emitted from the laser source to homogenize an intensity distribution of the laser light in a section which is perpendicular to the optical path; a phase shifter disposed in the optical path of the laser light passed through the homogenizing optical system to produce an intensity distribution pattern of the laser light in the section which is perpendicular to the optical path; a photoreceptor device disposed in the optical path of the laser light passed through the phase shifter to intercept a part of the laser light and to measure a quantity of the intercepted laser light; and an image-forming optical system disposed in the optical path of the laser light passed through the photoreceptor device to focus the laser light on a substrate to be treated.

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 crystallization apparatus includes a mask and an illumination system which illuminates the mask with a light beam, the light beam from the illumination system becoming a light beam having a light intensity distribution with an inverse peak pattern when transmitted through the mask, and irradiating a polycrystal semiconductor film or an amorphous semiconductor film, thereby generating a crystallized semiconductor film. The mask includes a light absorption layer having light absorption characteristics according to the light intensity distribution with the inverse peak pattern.

Abstract: A semiconductor device includes a non-single-crystal semiconductor film, a support substrate that supports the non-single-crystal semiconductor film, and an active device having a part of the non-single-crystal semiconductor film as a channel region. In particular, the channel region has an oxygen concentration not higher than 1×1018 atoms/cm3 and a carbon concentration not higher than 1×1018 atoms/cm3.

Abstract: The present invention is directed to a crystallization apparatus including an illumination system to illuminate a phase shift mask, which converts a light beam from the illumination system into a light beam that has a light intensity distribution of an inverse peak pattern having a minimum intensity in an area corresponding to a phase shift portion of the phase shift mask. The crystallization apparatus further includes an optical member to form on a predetermined plane a light intensity distribution of a concave pattern, which has a light intensity that is minimum in an area corresponding to the phase shift portion and increases toward the circumference of that area based on the light from the illumination system, and an image-forming optical system to set a surface of the polycrystalline semiconductor film or the amorphous semiconductor film or its conjugate plane and the predetermined plane to an optical conjugate relationship.

Abstract: An amorphous silicon layer is deposited on a glass substrate via an underlayer insulating film, and further a light-emitting layer is inserted between the glass substrate and the underlayer insulating film in a partial region on the glass substrate. To measure light intensity distribution of laser light applied to the amorphous silicon layer, the laser light is applied to the light-emitting layer from the surface of a substrate to be treated. The light intensity distribution of the light emitted from the light-emitting layer is two-dimensionally imaged using an optical image pickup system from the back surface of the substrate to be treated, and measured using an image pickup device. The light intensity distribution of the laser light in the face to be treated is obtained from the light intensity distribution of the emission measured in this manner.

Abstract: A crystallization apparatus includes an illumination system which applies illumination light for crystallization to a non-single-crystal semiconductor film, and a phase shifter which includes first and second regions disposed to form a straight boundary and transmitting the illumination light from the illumination system by a first phase retardation therebetween, and phase-modulates the illumination light to provide a light intensity distribution having an inverse peak pattern that light intensity falls in a zone of the non-single-crystal semiconductor film containing an axis corresponding to the boundary. The phase shifter further includes a small region which extends into at least one of the first and second regions from the boundary and transmits the illumination light by a second phase retardation with respect to the at least one of the first and second regions.

Abstract: A crystallization apparatus includes an illumination optical system to illuminate a phase shift mask and which irradiates an amorphous semiconductor film with a light beam having an intensity distribution of an inverse peak type having a smallest light intensity in a point corresponding to a phase shift portion of the phase shift mask to generate a crystallized semiconductor film. A convergence/divergence element is disposed on a light path between the illumination optical system and phase shift mask. The convergence/divergence element converts the light beam supplied from the illumination optical system into a light beam having an upward concave intensity distribution in which the light intensity is lowest in the phase shift portion and in which the light intensity increases as distant from the phase shift portion to irradiate the phase shift mask.

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 light irradiation apparatus includes a light modulation element which has a phase modulation area having at least one basic pattern for modulating a light beam, an illumination system which illuminates the phase modulation area of the light modulation element with a light beam, and an image formation optical system which causes a light beam on an irradiation target surface a light intensity distribution having an inverse-peak-shaped pattern formed based on the light beam phase-modulated by the phase modulation element to fall on an irradiation target object. Dimensions of the basic pattern are not greater than a point spread function range of the image formation optical system converted in terms of the light modulation element. The phase modulation area is configured in such a manner that a phase distribution in a light complex amplitude distribution on the irradiation target surface becomes a saw-tooth-like distribution along a line segment in a lateral direction.

Abstract: A crystallization apparatus includes an illumination system which applies illumination light for crystallization to a non-single-crystal semiconductor film, and a phase shifter which includes first and second regions disposed to form a straight boundary and transmitting the illumination light from the illumination system by a first phase retardation therebetween, and phase-modulates the illumination light to provide a light intensity distribution having an inverse peak pattern that light intensity falls in a zone of the non-single-crystal semiconductor film containing an axis corresponding to the boundary. The phase shifter further includes a small region which extends into at least one of the first and second regions from the boundary and transmits the illumination light by a second phase retardation with respect to the at least one of the first and second regions.