Abstract: The disclosure provides an infrared absorption material, a method for fabricating the same, and a thermal isolation structure employing the same. The infrared absorption material includes a tungsten bronze complex having a formula of M1xM2yWOz, wherein 0.6?x?0.8, 0.2?y?0.33, 0.8?x+y<1, and 2?z?3; M1 is Li, or Na; and, M2 is K, Rb, or Cs. In particular, the tungsten bronze complex consists of a cubic tungsten bronze (CTB) and a hexagonal tungsten bronze (HTB).

Abstract: A low-haze tin oxide film and a manufacturing method thereof are provided. The method includes: applying a mixed solution on a substrate and heating the substrate to form a tin oxide film. The mixed solution contains a tin source, an oxidizing agent, and a solvent.

Abstract: Provided is a metal oxide multi-layered structure for infrared blocking, which includes a first metal oxide film, a second metal oxide film, a third metal oxide film, and a metal nanoparticle layer. The third metal oxide film is disposed between the first metal oxide film and the second metal oxide film. The metal nanoparticle layer is disposed between the second metal oxide film and the third metal oxide film.

Abstract: The disclosure provides an infrared absorption material, a method for fabricating the same, and a thermal isolation structure employing the same. The infrared absorption material includes a tungsten bronze complex having a formula of M1xM2yWOz, wherein 0.6?x?0.8, 0.2?y?0.33, 0.8?x+y<1, and 2<z?3; M1 is Li, or Na; and, M2 is K, Rb, or Cs. In particular, the tungsten bronze complex consists of a cubic tungsten bronze (CTB) and a hexagonal tungsten bronze (HTB).

Abstract: The present disclosure provides a patterning process for an oxide film, including: covering a barrier layer composition on a substrate to form a patterned barrier layer, wherein the barrier layer composition includes an inorganic component and an organic binder with a weight ratio of 50-98:2-50; forming an oxide film on the patterned barrier layer and the substrate, wherein a thickness ratio (D1/D2) of the barrier layer (D1) to the oxide film (D2) is about 5-2000; and lifting off the barrier layer and the oxide film thereon, while leaving portions of the oxide film on the substrate.

Abstract: The invention provides a multilayered infrared light reflective structure. The multilayered infrared light reflective structure includes a transparent substrate. A doped oxide film is disposed on the transparent substrate. An oxide isolated layer is disposed on the doped oxide film, thereby allowing incident light to be incident from a top surface of the transparent substrate into the multilayered infrared light reflective structure.

Abstract: The present disclosure provides a patterning process for an oxide film, including: covering a barrier layer composition on a substrate to form a patterned barrier layer, wherein the barrier layer composition includes an inorganic component and an organic binder with a weight ratio of 50-98:2-50; forming an oxide film on the patterned barrier layer and the substrate, wherein a thickness ratio (D1/D2) of the barrier layer (D1) to the oxide film (D2) is about 5-2000; and lifting off the barrier layer and the oxide film thereon, while leaving portions of the oxide film on the substrate.

Abstract: A solar cell device is provided, including a transparent substrate, a transparent conductive layer disposed over the transparent substrate, a photovoltaic element formed over the composite transparent conductive layer, and an electrode layer disposed over the photovoltaic element. In one embodiment, the transparent conductive layer includes lithium and fluorine-co-doped tin oxides, and the lithium and fluorine-co-doped tin oxides includes a plurality of polyhedron grains, and the polyhedron grains have a polyhedron grain distribution density of 60-95%.

Abstract: A solar cell device is provided, including a transparent substrate, a transparent conductive layer disposed over the transparent substrate, a photovoltaic element formed over the composite transparent conductive layer, and an electrode layer disposed over the photovoltaic element. In one embodiment, the transparent conductive layer includes lithium and fluorine-co-doped tin oxides, and the lithium and fluorine-co-doped tin oxides have a lithium doping concentration of about 0.2˜2.3% and a fluorine doping concentration of about 0.1˜2.5%.

Abstract: The present invention discloses a low-temperature co-precipitation method for fabricating TCO powders, which comprises steps: respectively dissolving two or more metals/metal salts in solvents to obtain metal ion solutions; mixing the metal ion solutions to form a precursor solution having a specified composition; enabling a co-precipitation reaction at a temperature lower than 45° C. via adding precipitant in two stages, controlling the temperature of precipitation reactions and undertaking aging processes; flushing, filtering, drying and calcining the precipitates to obtain TCO powders having a specified composition and improved quality.

Abstract: The disclosure provides a white inorganic coating composition, and a device employing a coating made of the composition. The white inorganic coating composition includes a first inorganic material with a refractive index of less than 1.6, a second inorganic material with a refractive index of more than 2.3, and an inorganic blue pigment.

Abstract: The invention provides a multilayered infrared light reflective structure. The multilayered infrared light reflective structure includes a transparent substrate. A doped oxide film is disposed on the transparent substrate. An oxide isolated layer is disposed on the doped oxide film, thereby allowing incident light to be incident from a top surface of the transparent substrate into the multilayered infrared light reflective structure.

Abstract: A chlorine, fluorine and lithium co-doped transparent conductive film is provided, including chlorine, fluorine and lithium co-doped tin oxides, wherein the chlorine, fluorine and lithium co-doped tin oxides have a chlorine ion doping concentration not greater than 5 atom %, a fluorine ion doping concentration not greater than 5 atom %, and a lithium ion doping concentration not greater than 5 atom %.

Abstract: A solar cell device is provided, including a transparent substrate, a transparent conductive layer disposed over the transparent substrate, a photovoltaic element formed over the composite transparent conductive layer, and an electrode layer disposed over the photovoltaic element. In one embodiment, the transparent conductive layer includes lithium and fluorine-co-doped tin oxides, and the lithium and fluorine-co-doped tin oxides have a lithium doping concentration of about 0.2˜2.3% and a fluorine doping concentration of about 0.1˜2.5%.

Abstract: A solar cell device is provided, including a transparent substrate, a transparent conductive layer disposed over the transparent substrate, a photovoltaic element formed over the composite transparent conductive layer, and an electrode layer disposed over the photovoltaic element. In one embodiment, the transparent conductive layer includes lithium and fluorine-co-doped tin oxides, and the lithium and fluorine-co-doped tin oxides includes a plurality of polyhedron grains, and the polyhedron grains have a polyhedron grain distribution density of 60-95%.

Abstract: A solar cell device is provided, including a transparent substrate, a composite transparent conductive layer disposed over the transparent substrate, a photovoltaic element formed over the composite transparent conductive layer, and an electrode layer disposed over the photovoltaic element. In one embodiment, the composite transparent conductive layer includes a first transparent conductive layer and a second transparent conductive layer sequentially stacked over the transparent substrate, and the first transparent conductive layer is made of lithium and fluorine-codoped tin oxide and the second transparent conductive layer is made of a material selected from a group consisting of zinc oxide and titanium dioxide.

Abstract: A chlorine, fluorine and lithium co-doped transparent conductive film is provided, including chlorine, fluorine and lithium co-doped tin oxides, wherein the chlorine, fluorine and lithium co-doped tin oxides have a chlorine ion doping concentration not greater than 5 atom %, a fluorine ion doping concentration not greater than 5 atom %, and a lithium ion doping concentration not greater than 5 atom %.

Abstract: The invention, firstly, SnCl4 and SbCl3 are collected as raw materials and all dissolved into water and hydrochloric acid with precipitation. Secondly, NaOH or NH40H can be used for adjusting the pH value. Then, aging, water-washing, filtering and drying process are all carried out. The additive also can be put into and sintering process is applied. Furthermore, washing and drying process are used for obtaining the crystalline nano-level acicular ATO composition powder.