Abstract: Equipment is realized which is capable of increasing the frequency of use of a deposition mask of an organic EL element and the recycle of an adhesive agent by efficiently cleaning the deposition mask with little damage and efficiently collecting the adhesive agent. A pulse laser is irradiated to a deposition mask to separate the deposition agent from the deposition mask. The separated deposition agent is sucked by a suction nozzle, and the deposition agent is separated from air by a cyclone and deposited on a bottom of the cyclone. Thereafter, a first valve is opened to collect the deposition agent in a deposition agent collection section. Then a second valve is opened to move the deposition agent to a deposition agent refining section to be refined. A third valve is opened to store the refined deposition agent in a deposition agent storage section. The deposition mask may be cleaned without being damaged to collect the deposition agent with high efficiency.

Abstract: Equipment is realized which is capable of increasing the frequency of use of a deposition mask of an organic EL element and the recycle of an adhesive agent by efficiently cleaning the deposition mask with little damage and efficiently collecting the adhesive agent. A pulse laser is irradiated to a deposition mask to separate the deposition agent from the deposition mask. The separated deposition agent is sucked by a suction nozzle, and the deposition agent is separated from air by a cyclone and deposited on a bottom of the cyclone. Thereafter, a first valve is opened to collect the deposition agent in a deposition agent collection section. Then a second valve is opened to move the deposition agent to a deposition agent refining section to be refined. A third valve is opened to store the refined deposition agent in a deposition agent storage section. The deposition mask may be cleaned without being damaged to collect the deposition agent with high efficiency.

Abstract: A cleaning apparatus according to the present invention is provided with a brush drive mechanism which brings a brush being rotating closer to a substrate, measures electrical potentials generated on a plurality of conductor patterns formed on the substrate, by a contact and separation with/from tips of scrub materials of the brush being rotating, and controls a positioning of the brush by use of the measurement results. With the process as described above, it is possible to treat uniformly a surface to-be-cleaned for a large-sized substrate, with the cleaning brush. Consequently, it is possible to form a highly qualified transistor for liquid crystal display on the substrate having been cleaned, with enhancing yield.

Abstract: The present invention relates to a high-sensitivity defect inspection method, apparatus, and system adapted for the fine-structuring of patterns; wherein, in addition to a cleaning tank which chemically cleans a sample and rinses the sample, a defect inspection apparatus having a liquid-immersion element by which the interspace between the sample and the objective lens of an optical system is filled with a liquid, and a drying tank which dries the sample, the invention uses liquid-immersion transfer means from said cleaning tank through said liquid-immersion means of said defect inspection apparatus to said drying tank so that the sample is transferred in a liquid-immersed state from said cleaning tank to said liquid-immersion means.

Abstract: An amorphous silicon film is laser irradiated a plural number of times to make the film composed of a plurality of crystal grains while suppressing the formation of protrusions at the boundaries of the adjoining grains to realize a polycrystalline silicon thin film transistor having at least partly therein the clusters of grains, or the aggregates of at least two crystal grains, with preferred orientation in the plane (111), and having high electron mobility of 200 cm2/Vs or above.

Abstract: Where a thin film formed on a glass substrate is etched with a solution containing a fluoride, insoluble residues formed by the reaction of the solution with glass substrate components adhere to the back of the substrate to cause etching non-uniformity called roller marks. So, a solution is supplied directly to supporting members for supporting the glass substrate, or concentratedly to a region where the substrate and the supporting members come into contact and from a position opposite to the transporting direction of the substrate, or to both the supporting members and regions where the substrate and the supporting members come into contact. This enables the roller marks to be kept from forming, consequently making it possible to improve display quality of display devices.

Abstract: Agglomeration of a polycrystalline silicon film is eliminated at the time of obtaining a high quality polycrystalline silicon film by forming a silicon layer on an insulating film substrate and conducting long-term melting and re-crystallization. For this purpose, a layer or a plurality of layers of an underlayer UCL are provided on an insulating substrate GLS, the area near the surface in contact with a precursory silicon film PCF provided on this underlayer UCL is formed as an insulating film UCLP showing a film composition to improve the wettability of the melted silicon layer, and thereafter a high quality polycrystalline silicon film PSI is formed through elimination of agglomeration by melting of the precursory silicon film PCF using a laser beam LSR.

Abstract: The present invention relates to a high-sensitivity defect inspection method, apparatus, and system adapted for the fine-structuring of patterns; wherein, in addition to a cleaning tank which chemically cleans a sample and rinses the sample, a defect inspection apparatus having a liquid-immersion element by which the interspace between the sample and the objective lens of an optical system is filled with a liquid, and a drying tank which dries the sample, the invention uses liquid-immersion transfer means from said cleaning tank through said liquid-immersion means of said defect inspection apparatus to said drying tank so that the sample is transferred in a liquid-immersed state from said cleaning tank to said liquid-immersion means.

Abstract: An amorphous silicon film is laser irradiated a plural number of times to make the film composed of a plurality of crystal grains while suppressing the formation of protrusions at the boundaries of the adjoining grains to realize a polycrystalline silicon thin film transistor having at least partly therein the clusters of grains, or the aggregates of at least two crystal grains, with preferred orientation in the plane (111), and having high electron mobility of 200 cm2/Vs or above.

Abstract: An amorphous silicon film is laser irradiated a plural number of times to make the film composed of a plurality of crystal grains while suppressing the formation of protrusions at the boundaries of the adjoining grains to realize a polycrystalline silicon thin film transistor having at least partly therein the clusters of grains, or the aggregates of at least two crystal grains, with preferred orientation in the plane (111), and having high electron mobility of 200 cm2/Vs or above.

Abstract: A cleaning apparatus according to the present invention is provided with a brush drive mechanism which brings a brush being rotating closer to a substrate, measures electrical potentials generated on a plurality of conductor patterns formed on the substrate, by a contact and separation with/from tips of scrub materials of the brush being rotating, and controls a positioning of the brush by use of the measurement results. With the process as described above, it is possible to treat uniformly a surface to-be-cleaned for a large-sized substrate, with the cleaning brush. Consequently, it is possible to form a highly qualified transistor for liquid crystal display on the substrate having been cleaned, with enhancing yield.

Abstract: Where a thin film formed on a glass substrate is etched with a solution containing a fluoride, insoluble residues formed by the reaction of the solution with glass substrate components adhere to the back of the substrate to cause etching non-uniformity called roller marks. So, a solution is supplied directly to supporting member for supporting the glass substrate, or concentratedly to region where the substrate and the supporting member come into contact and from a position opposite to the transporting direction of the substrate, or to both the supporting members and regions where the substrate and the supporting members come into contact. This enables the roller marks to be kept from forming, consequently making it possible to improve display quality of display devices.

Abstract: An amorphous silicon film is laser irradiated a plural number of times to make the film composed of a plurality of crystal grains while suppressing the formation of protrusions at the boundaries of the adjoining grains to realize a polycrystalline silicon thin film transistor having at least partly therein the clusters of grains, or the aggregates of at least two crystal grains, with preferred orientation in the plane (111), and having high electron mobility of 200 cm2/Vs or above.

Abstract: An amorphous silicon film is laser irradiated a plural number of times to make the film composed of a plurality of crystal grains while suppressing the formation of protrusions at the boundaries of the adjoining grains to realize a polycrystalline silicon thin film transistor having at least partly therein the clusters of grains, or the aggregates of at least two crystal grains, with preferred orientation in the plane (111), and having high electron mobility of 200 cm2/Vs or above.

Abstract: Disclosed is a polysilicon film adapted for use in a liquid crystal display, and method of manufacturing such film. In manufacturing the film, a native oxide layer formed on a surface of an amorphous silicon film is completely removed by a hydrofluoric acid solution, followed by immersing in an H2O2 solution to newly form an extremely thin oxide layer, prior to a crystallizing processing performed by a laser beam irradiation. The crystallizing processing forms a polysilicon film formed of crystal grains Preferentially oriented on the (111) plane in a direction parallel to the substrate surface, an average crystal grain size being not larger than 300 nm, the standard deviation of the grain sizes being not larger than 30% of the average grain size, and the standard deviation of the roughness being not larger than 10% of the average grain size.

Abstract: An amorphous silicon film is laser irradiated a plural number of times to make the film composed of a plurality of crystal grains while suppressing the formation of protrusions at the boundaries of the adjoining grains to realize a polycrystalline silicon thin film transistor having at least partly therein the clusters of grains, or the aggregates of at least two crystal grains, with preferred orientation in the plane (111), and having high electron mobility of 200 cm2/Vs or above.

Abstract: An amorphous silicon film is laser irradiated a plural number of times to make the film composed of a plurality of crystal grains while suppressing the formation of protrusions at the boundaries of the adjoining grains to realize a polycrystalline silicon thin film transistor having at least partly therein the clusters of grains, or the aggregates of at least two crystal grains, with preferred orientation in the plane (111), and having high electron mobility of 200 cm2/Vs or above.

Abstract: At a time of cleaning a plate-like part such as a wafer or the like while rotating, for the purpose of reducing a contamination, a damage and an unevenness of process of the plate-like part which are caused by an amount of charged electricity of the plate-like part, chuck pins (chuck members) 201 which chuck the plate-like part 1 such as the wafer or the like and upper and lower cleaning plates 101 and 121 which oppose to the plate-like part 1 are constituted by a resin material containing carbon powders, and a desired potential difference is applied to a portion between the plate-like part and the cleaning plates by a voltage control unit 601 which is provided in an outer portion.

Abstract: An amorphous silicon film is laser irradiated a plural number of times to make the film composed of a plurality of crystal grains while suppressing the formation of protrusions at the boundaries of the adjoining grains to realize a polycrystalline silicon thin film transistor having at least partly therein the clusters of grains, or the aggregates of at least two crystal grains, with preferred orientation in the plane (111), and having high electron mobility of 200 cm2/Vs or above.

Abstract: Disclosed is a polysilicon film having high crystal orientation, low in nonuniformity in the crystal grain sizes, having the surface protrusion suppressed and, thus, adapted for use in a liquid crystal display. For manufacturing such an excellent polysilicon film, a native oxide layer formed on a surface of the amorphous silicon film is completely removed by using a hydrofluoric acid solution, followed by immersing the amorphous silicon film in an H2O2 solution for a short time so as to newly form an extremely thin oxide layer on the surface of the amorphous silicon film, prior to a crystallizing processing performed by a laser beam irradiation.