A method of making a semiconductor device may include providing a large semiconductor die comprising conductive interconnects with a first encapsulant disposed over four side surfaces of the large semiconductor die, over the active surface of the large semiconductor die, and around the conductive interconnects. A first build-up interconnect structure may be formed over the large semiconductor die and over the first encapsulant. Vertical conductive interconnects may be formed over the first build-up interconnect structure and around an embedded device mount site. An embedded device comprising through silicon vias (TSVs) may be disposed over the embedded device mount site. A second encapsulant may be disposed over the build-up structure, and around at least five sides of the embedded device. A second build-up structure may be formed disposed over the planar surface and configured to be electrically coupled to the TSVs of the embedded device and the vertical conductive interconnects.

A package substrate includes; a conductive line extending in a first horizontal direction, a conductive pad on an upper surface of the package substrate and horizontally spaced apart from the conductive line in a second horizontal direction, and a protective layer covering the conductive line and including an opening selectively exposing a portion of the conductive pad. The opening has an elongated elliptical shape having a minor axis defined by a width extending in the first horizontal direction and a major axis defined by a length extending in the second horizontal direction.

A package structure includes a circuit substrate, a semiconductor package, a thermal interface material, a lid structure and a heat dissipation structure. The semiconductor package is disposed on and electrically connected to the circuit substrate. The thermal interface material is disposed on the semiconductor package. The lid structure is disposed on the circuit substrate and surrounding the semiconductor package, wherein the lid structure comprises a supporting part that is partially covering and in physical contact with the thermal interface material. The heat dissipation structure is disposed on the lid structure and in physical contact with the supporting part of the lid structure.

Described are solder stop features for electronic devices. An electronic device may include an electrically insulative substrate, a metallization on the electrically insulative substrate, a metal structure attached to a first main surface of the metallization via a solder joint, and a concavity formed in a sidewall of the metallization. The concavity is adjacent at least part of the solder joint and forms a solder stop. A first section of the metal structure is spaced apart from both the metallization and solder joint in a vertical direction that is perpendicular to the first main surface of the metallization. A linear dimension of the concavity in a horizontal direction that is coplanar with the metallization is at least twice the distance by which the first section of the metal structure is spaced apart from the first main surface of the metallization in the vertical direction. Additional solder stop embodiments are described.

A method for forming a pattern includes at least the following steps. A first material and a second material abutting the first material are provided. The first material and the second material have different radiation absorption rates. A blocking layer is formed over the first material and the second material. The blocking layer is globally irradiated with an electromagnetic radiation to allow part of the blocking layer to turn into a crosslinked portion. The remaining blocking layer forms a non-crosslinked portion. The non-crosslinked portion covers the second material. The non-crosslinked portion of the blocking layer is removed to expose the second material. A third material is formed over the exposed second material. The crosslinked portion of the blocking layer is removed.

Semiconductor packaging substrates and processing sequences are described. In an embodiment, a packaging substrate includes a build-up structure, and a patterned metal contact layer partially embedded within the build-up structure and protruding from the build-up structure. The patterned metal contact layer may include an array of surface mount (SMT) metal bumps in a chip mount area, a metal dam structure or combination thereof.

An electronic device module includes: a substrate; a sealing portion disposed on the substrate; at least one electronic device mounted on the substrate and embedded in the sealing portion; and a roof wiring at least partially disposed on a surface of the sealing portion and electrically connecting the substrate to the at least one electronic device or electrically connecting electronic devices, among the at least one electronic device, to each other. The roof wiring includes: a surface wiring disposed on one surface of the sealing portion; and at least one post wiring connecting the surface wiring to the substrate or to the at least one electronic device, and wherein at least a portion of a circumferential surface of the at least one post wiring is bonded to the surface wiring.

A module includes: a substrate having a first surface; a first component mounted on the first surface; a first sealing resin disposed to cover the first surface and the first component; a shield film covering at least a side surface of the first sealing resin; a first ground terminal mounted on the first surface; and a protruding portion formed to extend laterally at any position of the first ground terminal in a direction perpendicular to the first surface. The protruding portion is electrically connected to a portion of the shield film that covers the side surface of the first sealing resin.

Disclosed are semiconductor packages and their fabricating methods. A semiconductor package includes a semiconductor chip on a redistribution substrate. The redistribution substrate includes a base dielectric layer and upper coupling pads in the base dielectric layer. Top surfaces of the upper coupling pads are coplanar with a top surface of the base dielectric layer. The semiconductor chip includes a redistribution dielectric layer and redistribution chip pads in the redistribution dielectric layer. Top surfaces of the redistribution chip pads are coplanar with a top surface of the redistribution dielectric layer. The top surface of the redistribution dielectric layer is bonded to the top surface of the base dielectric layer. The redistribution chip pads are bonded to the upper coupling pads. The redistribution chip pads and the upper coupling pads include a same metallic material. The redistribution dielectric layer and the base dielectric layer include a photosensitive polymer layer.

A semiconductor package includes a substrate; a semiconductor chip on a first surface of the substrate; and a plurality of external connection terminals on a second surface of the substrate that is opposite to the first surface. The substrate includes a plurality of wirings configured to electrically connect the semiconductor chip and the plurality of external connection terminals. The plurality of wirings includes a first wiring, and the first wiring includes a first portion and a second portion connected to each other, the second portion overlapping an edge of the semiconductor chip in a vertical direction that is perpendicular to the first surface of the substrate. A second width of the second portion is greater than a first width of the first portion.