A chip on film package includes a base film, a chip and a heat-dissipation sheet. The base film includes a first surface. The chip is disposed on the first surface and having a chip length along a first axis of the chip. The heat-dissipation sheet includes a covering portion and a first extending portion connected to the covering portion and attached to first surface. The covering portion at least partially covers the chip and having a first length along the first axis. The first extending portion has a second length along the first axis substantially longer than the first length of the covering portion, and the covering portion exposes a side surface of the chip, wherein the side surface connects a top surface and a bottom surface of the chip.

A semiconductor device including a semiconductor chip and a heat dissipation unit (heat sink) is configured as follows. The heat dissipation unit (heat sink) includes a resin tape, and a fin constituted of a graphite sheet and protruding from the resin tape. The fin, including graphene, is disposed on the semiconductor chip such that the graphene is disposed in a direction crossing a surface of the semiconductor chip. The heat dissipation unit is a rolled body in which the graphite sheet and the resin tape are layered and rolled. Thus, by use of the graphene as a constituent material of the fin, thermal conductivity is improved, whereby a heat dissipation characteristic is improved. Furthermore, since the fin is protruded from the resin tape, an exposed area of the fin is increased, and accordingly, the heat dissipation characteristic can be improved.

A semiconductor module can comprise a fully molded base portion comprising a planar surface that further comprises a semiconductor die comprising contact pads, conductive pillars coupled to the contact pads and extending to the planar surface, and an encapsulant material disposed over the active surface, four side surfaces, and around the conductive pillars, wherein ends of the conductive pillars are exposed from the encapsulant material at the planar surface of the fully molded base portion. A build-up interconnect structure comprising a routing layer can be disposed over the fully molded base portion. A photo-imageable solder mask material can be disposed over the routing layer and comprise openings to form surface mount device (SMD) land pads electrically coupled to the semiconductor die and the conductive pillars. A SMD component can be electrically coupled to the SMD land pads with surface mount technology (SMT).

A semiconductor module can comprise a fully molded base portion comprising a planar surface that further comprises a semiconductor die comprising contact pads, conductive pillars coupled to the contact pads and extending to the planar surface, and an encapsulant material disposed over the active surface, four side surfaces, and around the conductive pillars, wherein ends of the conductive pillars are exposed from the encapsulant material at the planar surface of the fully molded base portion. A build-up interconnect structure comprising a routing layer can be disposed over the fully molded base portion. A photo-imageable solder mask material can be disposed over the routing layer and comprise openings to form surface mount device (SMD) land pads electrically coupled to the semiconductor die and the conductive pillars. A SMD component can be electrically coupled to the SMD land pads with surface mount technology (SMT).

The present disclosure is directed to semiconductor packages, and methods for making them, which includes a substrate with a top surface and a bottom surface, a substrate recess in the bottom surface of the substrate, a first device positioned over the top surface of the substrate, which has the first device at least partially overlapping the substrate recess, a mold material in the substrate recess, which has the mold material overlapping the bottom surface of the substrate adjacent to the substrate recess, a second device positioned in the substrate recess, and a plurality of interconnect vias in the substrate, which has at least one of the plurality interconnect vias coupled to the first and second devices to provide a direct signal connection therebetween that minimizes signal latency.

A method of manufacturing a package that includes providing an electronic component that includes a dielectric layer as a base and a semiconductor die attached on top of the dielectric layer. The semiconductor die having an active area with monolithically integrated circuit elements. Encapsulating the dielectric layer and the semiconductor die by an encapsulant. The encapsulant is a mold compound having different material properties than the dielectric layer, and the dielectric layer includes a polymer.

A method of making a semiconductor package can include placing a single layer dielectric film on a temporary carrier substrate. A plurality of semiconductor die can be placed directly on the first surface of the single layer dielectric film. The single layer dielectric film can be cured to lock the plurality of semiconductor die in place on the single layer dielectric film. The plurality of semiconductor die can be encapsulated while directly on the single layer dielectric film with an encapsulant. The single layer dielectric film can be patterned utilizing a mask-less patterning technique to form a via hole after removing the temporary carrier substrate. A conductive layer can be formed directly on, substantially parallel to, and extending across, the second surface of the patterned single layer dielectric film, within the vial hole, and over the plurality of semiconductor die.

A method of making a semiconductor package can include placing a single layer dielectric film on a temporary carrier substrate. A plurality of semiconductor die can be placed directly on the first surface of the single layer dielectric film. The single layer dielectric film can be cured to lock the plurality of semiconductor die in place on the single layer dielectric film. The plurality of semiconductor die can be encapsulated while directly on the single layer dielectric film with an encapsulant. The single layer dielectric film can be patterned utilizing a mask-less patterning technique to form a via hole after removing the temporary carrier substrate. A conductive layer can be formed directly on, substantially parallel to, and extending across, the second surface of the patterned single layer dielectric film, within the vial hole, and over the plurality of semiconductor die.

A semiconductor module can comprise a fully molded base portion comprising a planar surface that further comprises a semiconductor die comprising contact pads, conductive pillars coupled to the contact pads and extending to the planar surface, and an encapsulant material disposed over the active surface, four side surfaces, and around the conductive pillars, wherein ends of the conductive pillars are exposed from the encapsulant material at the planar surface of the fully molded base portion. A build-up interconnect structure comprising a routing layer can be disposed over the fully molded base portion. A photo-imageable solder mask material can be disposed over the routing layer and comprise openings to form surface mount device (SMD) land pads electrically coupled to the semiconductor die and the conductive pillars. A SMD component can be electrically coupled to the SMD land pads with surface mount technology (SMT).

A semiconductor module can comprise a fully molded base portion comprising a planar surface that further comprises a semiconductor die comprising contact pads, conductive pillars coupled to the contact pads and extending to the planar surface, and an encapsulant material disposed over the active surface, four side surfaces, and around the conductive pillars, wherein ends of the conductive pillars are exposed from the encapsulant material at the planar surface of the fully molded base portion. A build-up interconnect structure comprising a routing layer can be disposed over the fully molded base portion. A photo-imageable solder mask material can be disposed over the routing layer and comprise openings to form surface mount device (SMD) land pads electrically coupled to the semiconductor die and the conductive pillars. A SMD component can be electrically coupled to the SMD land pads with surface mount technology (SMT).