Abstract: Film information about a thin film formed on the front surface of a semiconductor wafer, substrate information about the semiconductor wafer, and an installation angle of an upper radiation thermometer are set and input. Emissivity of the front surface of the semiconductor wafer formed with a multilayer film is calculated based on the various kinds of information. Further, a weighted average efficiency of the emissivity of the front surface of the semiconductor wafer is determined based on a sensitivity distribution of the upper radiation thermometer. Front surface temperature of the semiconductor wafer at the time of heat treatment is measured using the determined weighted average efficiency of the emissivity. The emissivity is determined based on the film information and the like, so that the front surface temperature of the semiconductor wafer can be accurately measured even when thin films are formed in multiple layers.

Abstract: A semiconductor wafer is preheated with a halogen lamp, and then is heated by irradiation with a flash of light emitted from a flash lamp. The preheating with the halogen lamp is continued for a short time even after the flash lamp turns off. A radiation thermometer measures a front surface temperature and a back surface temperature of the semiconductor wafer. A temperature integrated value is calculated by integration of temperatures of the semiconductor wafer measured during a period from a start of the flash irradiation to an end of the heating of the semiconductor wafer. It is determined that the semiconductor wafer is cracked at the time of flash irradiation when the calculated temperature integrated value deviates from a preset range between an upper limit value and a lower limit value.

Abstract: A semiconductor wafer is preheated with a halogen lamp, and then is heated by irradiation with a flash of light emitted from a flash lamp. The preheating with the halogen lamp is continued for a short time even after the flash lamp turns off. A radiation thermometer measures a front surface temperature and a back surface temperature of the semiconductor wafer. A temperature integrated value is calculated by integration of temperatures of the semiconductor wafer measured during a period from a start of the flash irradiation to an end of the heating of the semiconductor wafer. It is determined that the semiconductor wafer is cracked at the time of flash irradiation when the calculated temperature integrated value deviates from a preset range between an upper limit value and a lower limit value.

Abstract: A semiconductor wafer is heated by a flash of light emitted from a flash lamp after being preheated by a halogen lamp. Temperature of the semiconductor wafer immediately before the flash of light is emitted is measured by a lower radiation thermometer. At the time of irradiation with a flash of light, an upper radiation thermometer measures temperature increase of a front surface of the semiconductor wafer. Front surface temperature of the semiconductor wafer is calculated by adding the temperature increase of the front surface of the semiconductor wafer at the time of irradiation with a flash of light measured by the upper radiation thermometer to the back surface temperature of the semiconductor wafer measured by the lower radiation thermometer.

Abstract: Multiple theoretical reflectances determined by simulation for a silicon substrate with thin films of multiple types and thicknesses formed thereon are registered in association with the types and the thicknesses in a database. A carrier storing semiconductor wafers in a lot is transported into a heat treatment apparatus. A reflectance of a semiconductor wafer is measured by applying light to a surface of the semiconductor wafer. The theoretical reflectance of the semiconductor wafer is calculated from the measured reflectance thereof. A theoretical reflectance closely resembling the theoretical reflectance of the semiconductor wafer is extracted from among the multiple theoretical reflectances registered in the database, whereby the type and thickness of the thin film formed on the surface of the semiconductor wafer are specified. Treatment conditions for the semiconductor wafer are determined based on the specified type and thickness of the thin film.

Abstract: Film information about a thin film formed on the front surface of a semiconductor wafer, substrate information about the semiconductor wafer, and an installation angle of an upper radiation thermometer are set and input. Emissivity of the front surface of the semiconductor wafer formed with a multilayer film is calculated based on the various kinds of information. Further, a weighted average efficiency of the emissivity of the front surface of the semiconductor wafer is determined based on a sensitivity distribution of the upper radiation thermometer. Front surface temperature of the semiconductor wafer at the time of heat treatment is measured using the determined weighted average efficiency of the emissivity. The emissivity is determined based on the film information and the like, so that the front surface temperature of the semiconductor wafer can be accurately measured even when thin films are formed in multiple layers.

Abstract: A semiconductor wafer is heated by a flash of light emitted from a flash lamp after being preheated by a halogen lamp. Temperature of the semiconductor wafer immediately before the flash of light is emitted is measured by a lower radiation thermometer. At the time of irradiation with a flash of light, an upper radiation thermometer measures temperature increase of a front surface of the semiconductor wafer. Front surface temperature of the semiconductor wafer is calculated by adding the temperature increase of the front surface of the semiconductor wafer at the time of irradiation with a flash of light measured by the upper radiation thermometer to the back surface temperature of the semiconductor wafer measured by the lower radiation thermometer.

Abstract: A semiconductor wafer is preheated with a halogen lamp, and then is heated by irradiation with a flash of light emitted from a flash lamp. The preheating with the halogen lamp is continued for a short time even after the flash lamp turns off. A radiation thermometer measures a front surface temperature and a back surface temperature of the semiconductor wafer. A temperature integrated value is calculated by integration of temperatures of the semiconductor wafer measured during a period from a start of the flash irradiation to an end of the heating of the semiconductor wafer. It is determined that the semiconductor wafer is cracked at the time of flash irradiation when the calculated temperature integrated value deviates from a preset range between an upper limit value and a lower limit value.

Abstract: Multiple theoretical reflectances determined by simulation for a silicon substrate with thin films of multiple types and thicknesses formed thereon are registered in association with the types and the thicknesses in a database. A carrier storing semiconductor wafers in a lot is transported into a heat treatment apparatus. A reflectance of a semiconductor wafer is measured by applying light to a surface of the semiconductor wafer. The theoretical reflectance of the semiconductor wafer is calculated from the measured reflectance thereof. A theoretical reflectance closely resembling the theoretical reflectance of the semiconductor wafer is extracted from among the multiple theoretical reflectances registered in the database, whereby the type and thickness of the thin film formed on the surface of the semiconductor wafer are specified. Treatment conditions for the semiconductor wafer are determined based on the specified type and thickness of the thin film.

Abstract: [Object] To provide a method of treating osteoporosis by PTH that has excellent safety and high efficacy. To provide a method for inhibiting/preventing bone fractures by PTH that has excellent safety. And to provide a drug to do this. [Means of Achievement] A drug containing PTH as the active ingredient, characterized in that a unit dose of PTH of 100 to 200 units is administered weekly in the above method.

Abstract: [Object] To provide a method of treating osteoporosis by PTH that has excellent safety and high efficacy. To provide a method for inhibiting/preventing bone fractures by PTH that has excellent safety. And to provide a drug to do this. [Means of Achievement] A drug containing PTH as the active ingredient, characterized in that a unit dose of PTH of 100 to 200 units is administered weekly in the above method.

Abstract: A method of treating osteoporosis by PTH that has excellent safety and high efficacy is disclosed, along with a method for inhibiting/preventing bone fractures by PTH that has excellent safety, as well as providing a drug to do this. A drug containing PTH as the active ingredient is disclosed, characterized in that a unit dose of PTH of 100 to 200 units is administered weekly in the above method.

Abstract: A susceptor for holding a semiconductor wafer when flash heating is performed by exposing the semiconductor wafer to a flash of light from flash lamps is formed with a recessed portion of a concave configuration having an outer diameter greater than the diameter of the semiconductor wafer, as seen in plan view. When the susceptor is viewed from above, the concave configuration of the recessed portion is greater in plan view size than the semiconductor wafer. The susceptor formed with the recessed portion holds the semiconductor wafer in such a manner that an inner wall surface of the recessed portion supports a peripheral portion of the semiconductor wafer. As a result, a gap filled with a layer of gas is formed between the lower surface of the semiconductor wafer and the upper surface of the susceptor, to prevent a crack in the semiconductor wafer when the semiconductor wafer is exposed to a flash of light from the flash lamps.

Abstract: After the maintenance of a heat treatment apparatus, a susceptor and a heating plate are moved upwardly and a nitrogen gas flow from an inlet toward an outlet passage is produced prior to heat treating a semiconductor wafer. In this state, flash lamps are turned on to cause momentary expansion and contraction of the gas in a chamber, thereby scattering particles deposited on a bottom plate, etc. The scattered particles are removed by the nitrogen gas passing through a bottom portion of the chamber and discharged through the outlet passage. The particles are easily removed due to the flash lamps being turned on a predetermined number of times at fixed time intervals while folowing the nitrogen gas. The heat treatment apparatus has a light-emission characteristic and easily removes the particles in the chamber.

Abstract: After the maintenance of a heat treatment apparatus, a susceptor and a heating plate are moved upwardly and a flow of nitrogen gas from an inlet passage toward an outlet passage is produced prior to the heat treatment of a semiconductor wafer. In this state, flash lamps are turned on to cause the momentary expansion and contraction of the gas in a chamber, thereby scattering particles deposited on a bottom plate and the like. The scattered particles are removed by the flow of nitrogen gas passing through a bottom portion of the chamber and discharged outwardly through the outlet passage. The particles in the chamber are easily removed only by turning on the flash lamps a predetermined number of times at fixed time intervals while producing such a flow of nitrogen gas. This provides the heat treatment apparatus of a light-emission type and a method of cleaning the heat treatment apparatus capable of easily removing the particles in the chamber.