An epoxy resin composition, comprising an epoxy resin, a curing agent, a curing accelerator, an inorganic filler, and a carboxylic acid compound that satisfies at least one selected from the group consisting of the following A, B and C below: A: having at least one carboxy group and at least one hydroxy group; B: having at least two carboxy groups; and C: having a structure in which two carboxy groups are condensed by dehydration.

A semiconductor package includes a first sub-semiconductor package, an interposer substrate, and a second sub-semiconductor package that are sequentially stacked. The first sub-semiconductor package includes a first package substrate, a first semiconductor device, and a first mold member that are sequentially stacked, and the interposer substrate includes at least one hole. The first mold member includes: a mold main portion which covers the first semiconductor device; a mold connecting portion extended from the mold main portion and inserted into the at least one hole; and a mold protruding portion extended from the mold connecting portion to cover a top surface of the interposer substrate outside the at least one hole. The mold main portion, the mold connecting portion, and the mold protruding portion constitute a single object.

A method includes forming a dielectric layer over a carrier, forming a plurality of bond pads in the dielectric layer, and performing a planarization to level top surfaces of the dielectric layer and the plurality of bond pads with each other. A device die is bonded to the dielectric layer and portions of the plurality of bond pads through hybrid bonding. The device die is encapsulated in an encapsulating material. The carrier is then demounted from the device die and the dielectric layer.

A semiconductor module includes: a semiconductor element; a first lead frame including a first portion on which the semiconductor element is mounted; a sealing member sealing the semiconductor element and the first portion; and a heat dissipation member which is integrated with the sealing member and dissipates heat generated in the semiconductor element. The heat dissipation member is insulated from the semiconductor element and the first portion by the sealing member. Therefore, the semiconductor module that is applicable to vertical semiconductor elements and ensures electrical insulation between the semiconductor element and the heat dissipation member when implementing the semiconductor module onto a circuit board, can be provided.

A heat dissipation structure including: a printed circuit board; a first heat-generating element; a second heat-generating element; and a cured product of a thermally conductive curable liquid resin composition, the printed circuit board having a first surface and a second surface that is opposite to the first surface, the first heat-generating element being placed on the first surface, the second heat-generating element being placed on the second surface, the first heat-generating element generating an equal or greater amount of heat than the second heat-generating element, the second heat-generating element being surrounded by the cured product, the first heat-generating element being surrounded by a layer that has a lower thermal conductivity than the cured product.

Disclosed herein is an electronic circuit package includes a substrate having a power supply pattern, a first electronic component mounted on a first region of a front surface of the substrate, a mold resin that covers the front surface of the substrate so as to embed the first electronic component therein and has a concave portion above the first region, a magnetic film selectively provided in the concave portion, and a first metal film that is connected to the power supply pattern and covers the mold resin.

An electronic device includes a substrate, at least one electronic element on the substrate, a heat dissipating pad on the substrate in thermal contact with the at least one electronic element, and including an encapsulated phase change material therein, and a bracket covering the substrate, the at least one electronic element and the heat dissipating pad.

A stress shield for a plastic integrated circuit package is disclosed. A shield plate is attached by an adhesive to a top surface of an integrated circuit die such that the shield plate covers less than all of the top surface and leaves bond pads exposed. A molding material is applied over the shield plate and the integrated circuit die. The shield plate shields the integrated circuit die from stresses imparted by the molding material.

The present invention concerns a method for forming a metal layer for electromagnetic shielding and thermal management of active components, preferably by wet chemical metal plating, using an adhesion promotion layer on the layer of molding compound and forming at least one metal layer on the adhesion promotion layer or forming at least one metal layer on the adhesion promotion layer by wet chemical metal plating processes.

The present invention relates to a curable heat radiation composition which includes two types of fillers with different compressive breaking strengths (except when the two types of fillers are the same substance) and a thermosetting resin, the compressive breaking strength ratio of the two types of fillers [compressive breaking strength of a filler (A) with a higher compressive breaking strength/compressive breaking strength of a filler (B) with a lower compressive breaking strength] being 5 to 1,500, the compressive breaking strength of the filler (A) being 100 to 1,500 MPa, and the compressive breaking strength of the filler (B) being 1.0 to 20 MPa, an adhesive sheet using the composition and a method for producing the same. An aluminum nitride is preferable as the filler (A) and hexagonal boron nitride agglomerated particles are preferable as the filler (B).