Abstract: A glass body according to the present invention includes a first glass plate including a first surface and a second surface, and a first film region including a first Low-E film that is formed on at least a portion of at least one of the first surface and the second surface of the first glass plate, and the first film region has radio wave transmittance.

Abstract: Provided is a glass panel capable of, even after elapse of a long period, reliably sealing a suction hole and keeping a gap in an airtight state. A suction hole sealing metal material 15 has a first protruding portion 15a formed on an atmospheric side around a suction hole 4, and a second protruding portion 15b formed on a gap side around the suction hole 4, and as seen in a thickness direction of the glass plates 1A, 1B, a first contour 16a which is an outermost edge of a first adhesion surface portion S1 where the first protruding portion 15a is in contact with an atmospheric-side surface 17A of the glass plate 1A, and a second contour 16b which is an outermost edge of a second adhesion surface portion S2 where the second protruding portion 15b is in contact with a gap-side surface 17B of the glass plate 1A, are on an outer side of a third contour 16c which is a gap-side hole edge of the suction hole 4.

Abstract: Provided is a glass panel capable of, even after elapse of a long period, reliably sealing a suction hole and keeping a gap in an airtight state. A suction hole sealing metal material 15 has a first protruding portion 15a formed on an atmospheric side around a suction hole 4, and a second protruding portion 15b formed on a gap side around the suction hole 4, and as seen in a thickness direction of the glass plates 1A, 1B, a first contour 16a which is an outermost edge of a first adhesion surface portion S1 where the first protruding portion 15a is in contact with an atmospheric-side surface 17A of the glass plate 1A, and a second contour 16b which is an outermost edge of a second adhesion surface portion S2 where the second protruding portion 15b is in contact with a gap-side surface 17B of the glass plate 1A, are on an outer side of a third contour 16c which is a gap-side hole edge of the suction hole 4.

Abstract: The reduced pressure double glazed glass panel of the present invention includes an outside glass sheet, an inside glass sheet, and a gap portion that are joined together, with the gap portion being formed between the glass sheets and sealed under reduced pressure. Here, the outside glass sheet has a first glass surface disposed to face the outdoor space and a second glass surface disposed to face the gap portion. A Low-E film is formed on the second glass surface. The following relations hold: (Emissivity of Low-E film ?)?0.067; 31%?(Solar reflectance on First glass surface RG(solar))?40%; (48?RG(solar))%?(Solar absorptance on First glass surface AG(solar))?17%; (AG(solar))?{18.3?(0.07×RG(solar))+(20×?)}%; (Solar heat gain coefficient SHGC)?0.50; and (Thermal transmittance U value)?1.2 W/m2·K or less.

Abstract: The reduced pressure double glazed glass panel of the present invention includes an outside glass sheet, an inside glass sheet, and a gap portion that are joined together, with the gap portion being formed between the glass sheets and sealed under reduced pressure. Here, the outside glass sheet has a first glass surface disposed to face the outdoor space and a second glass surface disposed to face the gap portion. A Low-E film is formed on the second glass surface. The following relations hold: (Emissivity of Low-E film ?)?0.067; 31%?(Solar reflectance on First glass surface RG(solar))?40%; (48?RG(solar))%?(Solar absorptance on First glass surface AG(solar))?17%; (AG(solar))?{18.3?(0.07×RG(solar))+(20×?)}%; (Solar heat gain coefficient SHGC)?0.50; and (Thermal transmittance U value)?1.2 W/m2·K or less.

Abstract: An antibacterial substrate of the present invention includes a substrate and a plurality of antibacterial metal islands formed on the surface of the substrate. The antibacterial metal islands are exposed to an external atmosphere. The average value of contact angles between the substrate and the respective antibacterial metal islands is 90 degrees or less, as measured on the basis of results of surface observation with a scanning electron microscope.

Abstract: The present invention provides a glass member including a photocatalyst layer and a heat reflecting layer, the glass member having high photocatalytic activity and exhibiting a low reflectance and a colorless or pale blue reflection color tone or a bluish green or green reflection color tone. The glass member is produced by laminating an antistripping layer made of silicon oxide or the like, a crystalline undercoat layer made of zirconium oxide or the like and a photocatalyst layer made of titanium oxide or the like on the other surface of a glass substrate having a heat reflecting layer formed on one surface thereof.

Abstract: A member having high photocatalytic activity and multiple glass using the member are provided. A photocatalyst layer (TiO2) is formed on the surface of a substrate (glass sheet) through the intermediary of a crystalline undercoat layer (ZrO2), and no dead layer is substantially present between the photocatalyst layer and the undercoat layer. Also, provision of an amorphous layer between the substrate and the undercoat layer prevents peeling or defects between the photocatalyst layer and the substrate. In particular, by adjusting the thickness of each layer within a specific range, it is possible to obtain an article having a film configuration in which the optical feature of a reflection color, small variation of the reflectance, and a photocatalytic function are combined.

Abstract: The present invention provides a method for forming a titanium compound film on a substrate by a sputtering process by use of, in place of a conventional metallic titanium target, a titanium target containing a metal (such as tin or zinc) having two or more times higher sputtering yield in an argon atmosphere than titanium; an article coated with a titanium compound film; and a sputtering target for use in the film coating. The content of tin or zinc in the titanium target containing tin or zinc is preferably in the range of 1 to 45 at %, and further a third metal may be added. These can remove drawbacks in that the film has a low film formation rate and a high output power cannot be applied due to the occurrence of arcing in forming a titanium compound film on the surface of a substrate, such as plate-shaped glass, by a reactive sputtering process.

Abstract: A method for forming a zirconium compound film on a substrate by a sputtering process using a zirconium target which contains a metal (such as tin or zinc) of which the sputtering yield in an argon atmosphere is more than twice that of zirconium in place of a conventional metallic zirconium target. An article coated with the zirconium compound film and a sputtering target used for coating the film are provided. It is desirable that the content of the metal be 1-45 at %, but a third metal can be added thereto.

Abstract: A method for forming a zirconium compound film on a substrate by a sputtering process using a zirconium target which contains a metal (such as tin or zinc) of which the sputtering yield in an argon atmosphere is more than twice that of zirconium in place of a conventional metallic zirconium target. An article coated with the zirconium compound film and a sputtering target used for coating the film are provided. It is desirable that the content of the metal be 1-45 at %, but a third metal can be added thereto.

Abstract: A method for forming a zirconium compound film on a substrate by a sputtering process using a zirconium target which contains a metal (such as tin or zinc) of which the sputtering yield in an argon atmosphere is more than twice that of zirconium in place of a conventional metallic zirconium target. An article coated with the zirconium compound film and a sputtering target used for coating the film are provided. It is desirable that the content of the metal be 1-45 at %, but a third metal can be added thereto.