A package structure includes a bottom plate, a semiconductor package, a top plate, a screw and an anti-loosening coating. The semiconductor package is disposed over the bottom plate. The top plate is disposed over the semiconductor package, and includes an internal thread in a screw hole of the top plate. The screw penetrates through the bottom plate, the semiconductor package and the top plate, and includes an external thread. The external thread of the screw is engaged to the internal thread of the top plate, and the anti-loosening coating is adhered between the external thread and the internal thread.

A package structure includes a bottom plate, a semiconductor package, a top plate, a screw and an anti-loosening coating. The semiconductor package is disposed over the bottom plate. The top plate is disposed over the semiconductor package, and includes an internal thread in a screw hole of the top plate. The screw penetrates through the bottom plate, the semiconductor package and the top plate, and includes an external thread. The external thread of the screw is engaged to the internal thread of the top plate, and the anti-loosening coating is adhered between the external thread and the internal thread.

A composite substrate includes a submount substrate of an alternating pattern of electrically insulative portions, pieces, layers or segments and electrically conductive portions, pieces, layers or segments, and a shaft, back or plate for supporting the alternating pattern of electrically insulative portions and electrically conductive portions. An active device having a P-N junction can be mounted on the submount substrate. The electrically insulative portions, pieces, layers or segments can be formed from diamond while the electrically conductive portions, pieces, layers or segments can be formed from a metal or metal alloy.

A composite substrate includes a submount substrate of an alternating pattern of electrically insulative portions, pieces, layers or segments and electrically conductive portions, pieces, layers or segments, and a shaft, back or plate for supporting the alternating pattern of electrically insulative portions and electrically conductive portions. An active device having a P-N junction can be mounted on the submount substrate. The electrically insulative portions, pieces, layers or segments can be formed from diamond while the electrically conductive portions, pieces, layers or segments can be formed from a metal or metal alloy.

The present invention provides a conductive bonded assembly utilizing particles of Ni or an Ni alloy as conductive particles so as to enable firing under non-pressing conditions and further realize an excellent bonding strength, electron migration characteristic, and ion migration characteristic. The conductive bonded assembly of the present invention is a conductive bonded assembly of an electronic component which has a first bondable member (for example, electrode material), a second bondable member (for example, a semiconductor device on an Si or SiC substrate), and a conductive bonding layer bonding these bondable members together, where the bonding layer is an Ni sintered body formed by a sintered body of Ni particles which has a porosity of 30% or less, and, further, can be obtained by heating and sintering the Ni particles at the time of firing where the Ni sintered bonding layer is formed.

A substrate with an electronic component embedded therein includes: a core structure having a cavity; a metal layer disposed on a bottom surface of the cavity of the core structure; and an electronic component disposed on the metal layer in the cavity of the core structure. The substrate with the electronic component embedded therein has an excellent heat dissipation effect.

A substrate with an electronic component embedded therein includes: a core structure having a cavity; a metal layer disposed on a bottom surface of the cavity of the core structure; and an electronic component disposed on the metal layer in the cavity of the core structure. The substrate with the electronic component embedded therein has an excellent heat dissipation effect.

A semiconductor device package includes a substrate, a heat-generating component positioned on a surface of the substrate, and an encapsulant at least partially covering the heat-generating component and having an outer surface. A first heat-conducting layer is disposed between the encapsulant and the first heat-generating component. One or more pillars are in contact with the first heat-conducting layer and extend to the outer surface of the encapsulant and contact a second heat-conducting layer disposed on the outer surface of the encapsulant.

A semiconductor device package includes a substrate, a heat-generating component positioned on a surface of the substrate, and an encapsulant at least partially covering the heat-generating component and having an outer surface. A first heat-conducting layer is disposed between the encapsulant and the first heat-generating component. One or more pillars are in contact with the first heat-conducting layer and extend to the outer surface of the encapsulant and contact a second heat-conducting layer disposed on the outer surface of the encapsulant.

A power module substrate with a Ag underlayer of the invention includes: a circuit layer that is formed on one surface of an insulating layer; and a Ag underlayer that is formed on the circuit layer, in which the Ag underlayer is composed of a glass layer that is formed on the circuit layer side and a Ag layer that is formed by lamination on the glass layer, and regarding the Ag underlayer, in a Raman spectrum obtained by a Raman spectroscopy with incident light made incident from a surface of the Ag layer on a side opposite to the glass layer, when a maximum value of intensity in a wavenumber range of 3,000 cm.sup.−1 to 4,000 cm.sup.−1 indicated by I.sub.A, and a maximum value of intensity in a wavenumber range of 450 cm.sup.−1 to 550 cm.sup.−1 is indicated by I.sub.B, I.sub.A/I.sub.B is 1.1 or greater.