Abstract: A semiconductor device in which an insulating material layer contains no reinforced fibers such as a glass cloth or a nonwoven cloth and which enables miniaturization of metal thin-film wiring layers, a reduction in the diameter of metal vias, and a reduction in interlayer thickness. The semiconductor device includes an insulating material layer including one or more semiconductor elements sealed with an insulating material containing no reinforced fibers, a plurality of metal thin-film wiring layers, metal vias that electrically connect the metal thin-film wiring layers together and electrodes of the semiconductor elements and the metal thin-film wiring layers together, and a warpage adjustment layer arranged on one principal surface of the insulating material layer to offset warpage of the insulating material layer to reduce warpage of the semiconductor device.

Abstract: A semiconductor device including: a support plate 1; a semiconductor chip 2 mounted on one principal surface of the support plate 1 via an adhesive layer, with the element circuit surface of the chip being directed upward; an insulation material layer 4 that seals the semiconductor chip 2 and the periphery of the semiconductor chip; openings formed on an electrode arranged on the element circuit surface of the semiconductor chip 2 in the insulation material layer 4; conductive portions 6 formed in the openings so as to be connected to the electrode of the semiconductor chip; a wiring layer 5 formed on the insulation material layer 4 so as to be connected to the conductive portions 6 and partially extending to the peripheral region of the semiconductor chip 2; and external electrodes 7 formed on the wiring layer 5.

Abstract: A stacked semiconductor package includes a first semiconductor package including a first circuit board and a first semiconductor device mounted on the first circuit board; a second semiconductor package including a second circuit board and a second semiconductor device mounted on the second circuit board, the second semiconductor package being stacked on the first semiconductor package; and a heat transfer member provided on the first semiconductor device and a part of the first circuit board, the part being around the first semiconductor device.

Abstract: A magnetic shielding package of a non-volatile magnetic memory element, including: a soft magnetic material support plate 12; a first insulating material layer 13 formed on the support plate; a non-volatile magnetic memory element 11 fixed on the first insulating material layer; a second insulating material layer 14 that encapsulates the memory element and the periphery thereof; in the second insulating material layer, a wiring layer 15, a soft magnetic layer 15b or 25 and a conductive portion 16 connecting an electrode of the circuit surface of the memory element and the wiring layer; and a magnetic shield part 17 containing a soft magnetic material arranged like a wall at a distance from a side surface of the memory element so as to surround the memory element side surface partially or entirely, the magnetic shield part being magnetically connected to the soft magnetic layer.

Abstract: The present invention is to provide a semiconductor device in which an insulating material layer contains no reinforced fibers such as a glass cloth or a nonwoven cloth and which enables miniaturization of metal thin-film wiring layers, a reduction in the diameter of metal vias, and a reduction in interlayer thickness. The semiconductor device includes an insulating material layer including one or more semiconductor elements sealed with an insulating material containing no reinforced fibers, a plurality of metal thin-film wiring layers, metal vias that electrically connect the metal thin-film wiring layers together and electrodes of the semiconductor elements and the metal thin-film wiring layers together, and a warpage adjustment layer arranged on one principal surface of the insulating material layer to offset warpage of the insulating material layer to reduce warpage of the semiconductor device.

Abstract: A magnetic shielding package of a non-volatile magnetic memory element, including: a soft magnetic material support plate 12; a first insulating material layer 13 formed on the support plate; a non-volatile magnetic memory element 11 fixed on the first insulating material layer; a second insulating material layer 14 that encapsulates the memory element and the periphery thereof; in the second insulating material layer, a wiring layer 15, a soft magnetic layer 15b or 25 and a conductive portion 16 connecting an electrode of the circuit surface of the memory element and the wiring layer; and a magnetic shield part 17 containing a soft magnetic material arranged like a wall with a distance from a side surface of the memory element so as to surround the memory element side surface partially or entirely, the magnetic shield part being magnetically connected to the soft magnetic layer.

Abstract: A manufacturing method for a semiconductor device of the present invention includes: preparing a semiconductor wafer including an electrode formed therein; electrically connecting a first semiconductor element formed in a semiconductor chip and the electrode formed in the semiconductor wafer; filling a gap between the semiconductor wafer and the semiconductor chip with a first insulating resin layer; forming a second insulating resin layer on the semiconductor wafer; grinding the second insulating resin layer and the semiconductor chip until a thickness of the semiconductor chip reaches a predetermined thickness; forming a first insulating layer on the second insulating resin layer and the semiconductor chip; forming a line on the first insulating layer connected with a conductive material filled an opening in the first insulating layer and the second insulating resin layer to expose the electrode; and grinding the semiconductor wafer until a thickness of the semiconductor wafer reaches a predetermined thickn

Abstract: A semiconductor package includes a support substrate arranged with a first aperture reaching a semiconductor device on a rear side, the semiconductor device is bonded via an adhesive to a surface of the support substrate, an insulating layer covering the semiconductor device, and wiring for connecting the semiconductor device and an external terminal through the insulating layer. The adhesive may form a part of the first aperture. In addition, a heat dissipation part may be arranged in the first aperture and a metal material may be filled in the first aperture.

Abstract: A manufacturing method for a semiconductor device of the present invention includes: preparing a semiconductor wafer including an electrode formed therein; electrically connecting a first semiconductor element formed in a semiconductor chip and the electrode formed in the semiconductor wafer; filling a gap between the semiconductor wafer and the semiconductor chip with a first insulating resin layer; forming a second insulating resin layer on the semiconductor wafer; grinding the second insulating resin layer and the semiconductor chip until a thickness of the semiconductor chip reaches a predetermined thickness; forming a first insulating layer on the second insulating resin layer and the semiconductor chip; forming a line on the first insulating layer connected with a conductive material filled an opening in the first insulating layer and the second insulating resin layer to expose the electrode; and grinding the semiconductor wafer until a thickness of the semiconductor wafer reaches a predetermined thickn

Abstract: A stacked semiconductor package includes a first semiconductor package including a first circuit board and a first semiconductor device mounted on the first circuit board; a second semiconductor package including a second circuit board and a second semiconductor device mounted on the second circuit board, the second semiconductor package being stacked on the first semiconductor package; and a heat transfer member provided on the first semiconductor device and a part of the first circuit board, the part being around the first semiconductor device.

Abstract: The invention provides a semiconductor device low in height and having low heat resistance, and a method of manufacturing the semiconductor device.

Abstract: A semiconductor package includes a support substrate arranged with a first aperture reaching a semiconductor device on a rear side, the semiconductor device is bonded via an adhesive to a surface of the support substrate, an insulating layer covering the semiconductor device, and wiring for connecting the semiconductor device and an external terminal through the insulating layer. The adhesive may form a part of the first aperture. In addition, a heat dissipation part may be arranged in the first aperture and a metal material may be filled in the first aperture.

Abstract: Embodiments of the invention provide an interconnect substrate capable of improving the connection reliability and yield of a semiconductor device, a method of manufacturing the interconnect substrate, and a semiconductor device using the interconnect substrate. An interconnect substrate according to an embodiment of the invention includes: a substrate; an electrode pad formed over the substrate; an insulating film (solder resist film) formed over the substrate; an opening formed in the insulating film, in which the upper surface of the electrode pad is exposed on the bottom surface of the opening and a metal film formed over the upper surface of the electrode pad and side surface of the insulating film in the opening. At least a portion of the edge of an upper surface of the metal film is higher than the other portions of the upper surface of the metal film.

Abstract: Provided is a semiconductor device having a substrate, a semiconductor chip flip-chip mounted on the substrate, and a stacked film provided in a gap between the substrate and the semiconductor chip. The stacked film is composed of a protective film covering the surface of the substrate, and an underfill film formed between the solder resist film and the semiconductor chip. The protective film is roughened on the contact surface brought into contacting said underfill film.

Abstract: Embodiments of the invention provide an interconnect substrate capable of improving the connection reliability and yield of a semiconductor device, a method of manufacturing the interconnect substrate, and a semiconductor device using the interconnect substrate. An interconnect substrate according to an embodiment of the invention includes: a substrate; an electrode pad formed over the substrate; an insulating film (solder resist film) formed over the substrate; an opening formed in the insulating film, in which the upper surface of the electrode pad is exposed on the bottom surface of the opening; and a metal film formed over the upper surface of the electrode pad and side surface of the insulating film in the opening. At least a portion of the edge of an upper surface of the metal film is higher than the other portions of the upper surface of the metal film.

Abstract: A manufacturing method of a semiconductor device includes a first to fourth steps. The first step includes a step of determining an UBM (Under Bump Metal) radius of an UBM of a chip. The second step includes a step of determining a first curvature radius of a solder bump formed on the UBM. The third step includes a step of determining a SRO (Solider Resist Opening) radius of a SRO of a substrate such that a ratio of the SRO radius to the UMB radius is in a range from 0.8 to 1.2. The fourth step includes a step of determining a second curvature radius of a spare solder formed on an electrode in the SRO such that the second curvature radius is equal to or more than the first curvature radius.

Abstract: Provided is a semiconductor device having a substrate, a semiconductor chip flip-chip mounted on the substrate, and a stacked film provided in a gap between the substrate and the semiconductor chip. The stacked film is composed of a protective film covering the surface of the substrate, and an underfill film formed between the solder resist film and the semiconductor chip. The protective film is roughened on the contact surface brought into contacting said underfill film.

Abstract: A printed wiring board includes: a substrate main body; a solder resist layer provided on the substrate main body and having a first opening in which a part of the solder bump is formed; and a solder resist layer provided on the solder resist layer and having a second opening through which the solder bump is formed. The shape of the second opening is non-analogous to the shape of the first opening when viewed as plane-wise.

Abstract: An optical waveguide path coupling structure is realized without requiring highly accurate alignment.

Abstract: There is disclosed a fabrication method comprising: stacking and forming an Ni bond layer 3 and oxidation preventive layer 4 on a Cu interconnection layer 2 formed on the surface of a BGA package 1 in an electroless plating process; and applying a flux 5 to coat the oxidation preventive layer 4. Moreover, the method comprises: laying a Cu-added solder ball bump 6 onto the oxidation preventive layer 4; and performing a heat treatment in a temperature range of 190° C. to 220° C. to melt/bond the bump into the Ni bond layer 3. Sn and Cu in the Cu-added solder ball bump 6 rapidly react with Ni in the Ni bond layer 3 to form a diffusion inhibitive alloy layer 7. Subsequently, an electrode pad 10 on a mother board 9 which is a interconnection substrate is molten/bonded into the Cu-added solder ball bump 6, and a semiconductor device 8 is mounted on a mother board 9.