Abstract: A device includes first and second semiconductor fins, first, second, third and fourth fin sidewall spacers, and first and second epitaxy structures. The first and second fin sidewall spacers are respectively on opposite sides of the first semiconductor fin. The third and fourth fin sidewall spacers are respectively on opposite sides of the second semiconductor fin. The first and third fin sidewall spacers are between the first and second semiconductor fins and have smaller heights than the second and fourth fin sidewall spacers. The first and second epitaxy structures are respectively on the first and second semiconductor fins and merged together.

Abstract: Methods for fabricating electrode structures on a substrate are presented. The fabrication method includes providing a substrate with a patterned metal layer thereon, defining an electrode area. A passivation glue is formed on the patterned metal layer. An electrode layer is formed in the electrode area. A filling process is performed to deposit nano metal oxides on the electrode layer to extensively fill the entire electrode area.

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: An embodiment of the invention provides a complex dye-sensitized photovoltaic apparatus including a conductive substrate, a counter electrode, a partition member, a photoelectric conversion layer, a first electrolyte, and a charge storage device or an electrochromic solution. A space is provided between the counter electrode and the conductive substrate. The partition member is disposed in the space, dividing the space into a first chamber and a second chamber. The photoelectric conversion layer is disposed on the conductive substrate in the first chamber filled with the first electrolyte, wherein the photoelectric conversion layer includes a porous semiconductor film and a dye absorbed on the porous semiconductor film. The photoelectric conversion layer and the conductive substrate form a working electrode. The charge storage device or the electrochromic solution is disposed in the second chamber.

Abstract: Disclosed is a method to manufacture an electrode. The metal oxide of different sizes (or metal oxide secondary particle of similar size) is formed on a transparent substrate by electrophoresis deposition. Subsequently, the metal oxide layer is compressed and dipped in dye to complete an electrode applied in a solar cell. Furthermore, the step of dipping the metal oxide in dye can be earlier than the electrophoresis deposition, thereby reducing the dipping period and dipping temperature.

Abstract: Methods for fabricating electrode structures on a substrate are presented. The fabrication method includes providing a substrate with a patterned metal layer thereon, defining an electrode area. A passivation glue is formed on the patterned metal layer. An electrode layer is formed in the electrode area. A filling process is performed to deposit nano metal oxides on the electrode layer to extensively fill the entire electrode area.

Abstract: Disclosed is a method to manufacture an electrode. The metal oxide of different sizes (or metal oxide secondary particle of similar size) is formed on a transparent substrate by electrophoresis deposition. Subsequently, the metal oxide layer is compressed and dipped in dye to complete an electrode applied in a solar cell. Furthermore, the step of dipping the metal oxide in dye can be earlier than the electrophoresis deposition, thereby reducing the dipping period and dipping temperature.