Abstract: A first electrode film is electrically connected to a source region of a semiconductor substrate, and disposed over a main surface of the semiconductor substrate. A second electrode film is electrically connected to a gate electrode, and disposed over the main surface. A third electrode film is disposed over the main surface away from the first electrode film. A protective dielectric film is disposed over the main surface, covers only a portion of each of the first electrode film and the second electrode film and covers at least portion of the third electrode film, and is made of a thermosetting resin. The main surface has a peripheral region and an inner region enclosed by the peripheral region, and the protective dielectric film has a peripheral portion covering the peripheral region and has a first inner portion crossing the inner region and covering at least portion of the third electrode film.

Abstract: A method includes: forming an n-type diffusion layer as a second-conductivity-type semiconductor layer on a first-conductivity-type crystalline semiconductor substrate; and forming an anti-reflective film by a CVD method to extend from a light receiving surface side to a side surface of the semiconductor substrate, by placing the semiconductor substrate on a mount in a film forming chamber with a back surface brought into contact with the mount, evacuating and decompressing the film forming chamber, and supplying source gas into the film forming chamber. In the film formation, a tray has a through hole, and the anti-reflective film is formed on the surface of the semiconductor substrate excluding the contact surface by bringing the semiconductor substrate into close contact with the contact surface by causing the through hole to have a negative pressure relative to the pressure in the film forming chamber by the evacuation.

Abstract: A method includes: forming an n-type diffusion layer as a second-conductivity-type semiconductor layer on a first-conductivity-type crystalline semiconductor substrate; and forming an anti-reflective film by a CVD method to extend from a light receiving surface side to a side surface of the semiconductor substrate, by placing the semiconductor substrate on a mount in a film forming chamber with a back surface brought into contact with the mount, evacuating and decompressing the film forming chamber, and supplying source gas into the film forming chamber. In the film formation, a tray has a through hole, and the anti-reflective film is formed on the surface of the semiconductor substrate excluding the contact surface by bringing the semiconductor substrate into close contact with the contact surface by causing the through hole to have a negative pressure relative to the pressure in the film forming chamber by the evacuation.

Abstract: A first electrode film is electrically connected to a source region of a semiconductor substrate, and disposed over a main surface of the semiconductor substrate. A second electrode film is electrically connected to a gate electrode, and disposed over the main surface. A third electrode film is disposed over the main surface away from the first electrode film. A protective dielectric film is disposed over the main surface, covers only a portion of each of the first electrode film and the second electrode film and covers at least portion of the third electrode film, and is made of a thermosetting resin. The main surface has a peripheral region and an inner region enclosed by the peripheral region, and the protective dielectric film has a peripheral portion covering the peripheral region and has a first inner portion crossing the inner region and covering at least portion of the third electrode film.

Abstract: A method includes: forming an n-type diffusion layer as a second-conductivity-type semiconductor layer on a first-conductivity-type crystalline semiconductor substrate; and forming an anti-reflective film by a CVD method to extend from a light receiving surface side to a side surface of the semiconductor substrate, by placing the semiconductor substrate on a mount in a film forming chamber with a back surface brought into contact with the mount, evacuating and decompressing the film forming chamber, and supplying source gas into the film forming chamber. In the film formation, a tray has a through hole, and the anti-reflective film is formed on the surface of the semiconductor substrate excluding the contact surface by bringing the semiconductor substrate into close contact with the contact surface by causing the through hole to have a negative pressure relative to the pressure in the film forming chamber by the evacuation.

Abstract: A cleaning method of a film forming device capable of suppressing generation of static electricity is provided. The cleaning method of the film forming device includes the steps of humidifying surroundings of the film forming device; opening said film forming device to an atmosphere; and removing a deposit inside said film forming device.

Abstract: Manufacturing conditions are saved in a first storage unit. The manufacturing conditions are transmitted from the first storage unit to a second storage unit to be stored in the second storage unit. A product is manufactured based on the manufacturing conditions stored in the second storage unit. After the product is manufactured, the manufacturing conditions are erased from the second storage unit. Thus, maintenance and inspection can be easily performed, and leak of information about the manufacturing conditions can be prevented.