A method for manufacturing a photoelectric conversion device, that includes: forming a laminate structure of a substrate, a transparent electrode, an active layer produced by wet-coating, and a counter electrode, stacked in this order; and thereafter forming a cavity by: (a) pressing an adhesive material just against a defect formed on the surface of said counter electrode, and then peeling off said adhesive material together with said defect and the peripheral part thereof; or (b) sucking a defect formed on the surface of said counter electrode, so as to remove said defect and the peripheral part thereof, where said cavity penetrates through the counter electrode and unreached to the transparent electrode.

Exemplary support assemblies may include an electrostatic chuck body defining a substrate support surface. The assemblies may include a support stem coupled with the electrostatic chuck body. The assemblies may include a heater embedded within the electrostatic chuck body. The assemblies may also include an electrode embedded within the electrostatic chuck body between the heater and the substrate support surface. The substrate support assemblies may be characterized by a leakage current through the electrostatic chuck body of less than or about 4 mA at a temperature of greater than or about 500 C. and a voltage of greater than or about 600 V.

A filter device includes a plurality of coils of which central axes are spaced apart from one another and in parallel to one another and a plurality of ground members spaced apart from one another and extending in parallel to the central axes of the coils outside of the coils. Each of the coils is spaced apart from another coil closest thereto by a first distance. Each of the ground members is spaced apart from a coil closest thereto by a second distance. The number of ground members spaced apart from each of the coils by the second distance is the same.

A wafer placement apparatus includes a disc-shaped ceramic plate having an upper surface as a wafer placement surface and in which an electrode is embedded; a disc-shaped cooling plate provided on a lower surface, opposite the wafer placement surface, of the ceramic plate; and a resin adhesive-sheet layer with which a bonding surface as the lower surface of the ceramic plate and a bonding surface as an upper surface of the cooling plate are bonded to each other, wherein at least one of the bonding surface of the ceramic plate and the bonding surface of the cooling plate has a surface roughness Ra that is higher in an outer part of the bonding surface than in an inner part of the bonding surface.

Disclosed is a method for constructing a micro-LED display module. The method includes: retaining micro-LED chips in a matrix on a chip retaining member; picking up the micro-LED chips on the chip retaining member and transferring the picked up micro-LED chips to a planar carrier member; pressing the micro-LED chips on the planar carrier member against a mount substrate; and heating solders disposed on the mount substrate above the melting point of the solders simultaneously with the pressing of the micro-LED chips against the mount substrate to bond the micro-LED chips to the mount substrate. The mount substrate is sucked by a suction chuck during heating of the solders.

Even when a stiffener is omitted, the semiconductor device which can prevent the generation of twist and distortion of a wiring substrate is obtained. As for a semiconductor device which has a wiring substrate, a semiconductor chip by which the flip chip bond was made to the wiring substrate, and a heat spreader adhered to the back surface of the semiconductor chip, and which omitted the stiffener for reinforcing a wiring substrate and maintaining the surface smoothness of a heat spreader, a wiring substrate has a plurality of insulating substrates in which a through hole whose diameter differs, respectively was formed, and each insulating substrate contains a glass cloth.

A semiconductor device comprises: a ceramic substrate having conductor layers on both surfaces thereof; a semiconductor element joined to the upper surface conductor layer of the ceramic substrate; a frame member arranged on the upper surface conductor layer so as to surround a side surface of the semiconductor element; and an electrode, which is joined to an upper portion of the semiconductor element via a second fixing layer, and has fitting portions on a side surface of the electrode. On an inner wall of the frame member, fitting portions to be fitted to the fitting portions of the electrode and four positioning portions extending from the inner wall of the frame member to the side surfaces of the electrode are formed.

A component-manufacturing tool includes a frame body and a holding film covering an opening, wherein the frame body includes a first frame and a second frame; the holding film includes a base layer and a holding layer provided on one surface of the base layer, and the holding film is sandwiched and held between the first frame and the second frame in a stretched state; and a ratio R.sub.E1 (=E(100)/E(25)) of an elastic modulus E(100 C.) of the base layer to an elastic modulus E(25 C.) of the base layer is 0.2R.sub.E11, and E(25) is 35 MPa or more and 3500 MPa or less. A component-manufacturing method includes a component holding step of holding components to the holding layer of the component-manufacturing tool; and a chucking step of chucking and fixing the holding film, to which holds the components, to a surface of a heated chuck table.

A method includes forming a device structure, the method including forming a first redistribution structure over and electrically connected to a semiconductor device, forming a molding material surrounding the first redistribution structure and the semiconductor device, forming a second redistribution structure over the molding material and the first redistribution structure, the second redistribution structure electrically connected to the first redistribution structure, attaching an interconnect structure to the second redistribution structure, the interconnect structure including a core substrate, the interconnect structure electrically connected to the second redistribution structure, forming an underfill material on sidewalls of the interconnect structure and between the second redistribution structure and the interconnect structure.

A method for manufacturing a photoelectric conversion device, that includes: forming a laminate structure of a substrate, a transparent electrode, an active layer produced by wet-coating, and a counter electrode, stacked in this order; and thereafter forming a cavity by: (a) pressing an adhesive material just against a defect formed on the surface of said counter electrode, and then peeling off said adhesive material together with said defect and the peripheral part thereof; or (b) sucking a defect formed on the surface of said counter electrode, so as to remove said defect and the peripheral part thereof, where said cavity penetrates through the counter electrode and unreached to the transparent electrode.