An electronic package structure includes a first electronic component, a first thermal conductive structure and a second thermal conductive structure. The first thermal conductive structure is disposed over the first electronic component. The second thermal conductive structure is disposed between the first electronic component and the first thermal conductive structure. A first heat transfer rate of the second thermal conductive structure along a first direction from the first electronic component to the first thermal conductive structure is greater than a second heat transfer rate of the second thermal conductive structure along a second direction nonparallel with the first direction from the first electronic component to an element other than the first thermal conductive structure.

An electronic device includes a support board having a mounting face and an integrated circuit chip mounted on the mounting face. An encapsulation block embeds the integrated circuit chip, the encapsulation block extending above the integrated circuit chip and around the integrated circuit chip on the mounting face of the support board. The encapsulation block includes a front face with a hole passing through the encapsulation block to uncovering at least part of an electrical contact. A layer made of an electrically conducting material fills the hole to make electrical connection to the electrical contact and further extends over the front face of the encapsulation block.

A component such as an interposer or microelectronic element can be fabricated with a set of vertically extending interconnects of wire bond structure. Such method may include forming a structure having wire bonds extending in an axial direction within one of more openings in an element and each wire bond spaced at least partially apart from a wall of the opening within which it extends, the element consisting essentially of a material having a coefficient of thermal expansion (CTE) of less than 10 parts per million per degree Celsius (ppm/ C.). First contacts can then be provided at a first surface of the component and second contacts provided at a second surface of the component facing in a direction opposite from the first surface, the first contacts electrically coupled with the second contacts through the wire bonds.

Techniques are disclosed herein for creating over and under interconnects. Using techniques described herein, over and under interconnects are created on an IC. Instead of creating signaling interconnects and power/ground interconnects on a same side of a chip assembly, the signaling interconnects can be placed on an opposing side of the chip assembly as compared to the power interconnects.

A semiconductor device package includes an electronic device, a conductive frame and a first molding layer. The conductive frame is disposed over and electrically connected to the electronic device, and the conductive frame includes a plurality of leads. The first molding layer covers the electronic device and a portion of the conductive frame, and is disposed between at least two adjacent ones of the leads.

A semiconductor package structure includes a substrate, and a package preform. The substrate includes a plurality of conductive tracing wires. The package preform includes a semiconductor chip and a plurality of binding wires. The semiconductor chip includes a plurality of welding spots, and the welding spots are electrically connected with corresponding conductive tracing wires by the binding wires. Each binding wire comprises a carbon nanotube composite wire, the carbon nanotube composite wire includes a carbon nanotube wire and a metal layer. The carbon nanotube wire consists of a plurality of carbon nanotubes spirally arranged along an axial direction an axial direction of the carbon nanotube wire.

A manufacturing method of a POP structure including at least the following steps is provided. A first package structure is formed and a second package structure is formed on the first package structure. The first package structure includes a circuit carrier and a die disposed on the circuit carrier. Forming the first package structure includes providing a conductive interposer on the circuit carrier, encapsulating the conductive interposer by an encapsulant and removing a portion of the encapsulant and the plate of the conductive interposer. The conductive interposer includes a plate, a plurality of conductive pillars and a conductive protrusion respectively extending from the plate to the circuit carrier and the die. The conductive protrusion disposed on the die, and the conductive pillars are electrically connected to the circuit carrier. The second package structure is electrically connected to the first package structure through the conductive interposer.

A package structure and a manufacturing method thereof are provided. The package structure includes a circuit carrier, a substrate, a die, a plurality of conductive wires and an encapsulant. The substrate is disposed on the circuit carrier and includes a plurality of openings. The die is disposed between the circuit carrier and the substrate. The conductive wires go through the openings of the substrate to electrically connect between the substrate and the circuit carrier. The encapsulant is disposed on the circuit carrier and encapsulates the die, the substrate and the conductive wires.

A manufacturing method of a package-on package structure including at least the following steps is provided. A die is bonded on a first circuit carrier. A spacer is disposed on the die. The spacer and the first circuit carrier are connected through a plurality of conductive wires. An encapsulant is formed to encapsulate the die, the spacer and the conductive wires. A thickness of the encapsulant is reduced until at least a portion of each of the conductive wires is removed to form a first package structure. A second package structure is stacked on the first package structure. The second package structure is electrically connected to the conductive wires.

A chip package structure including a substrate, a first chip, a frame, a plurality of first conductive connectors, a first encapsulant, and a package is provided. The first chip is disposed on the substrate. The first chip has an active surface and a back surface opposite to the active surface, and the active surface faces the substrate. The frame is disposed on the back surface of the first chip and the frame has a plurality of openings. The first conductive connectors are disposed on the substrate and the first conductive connectors are disposed in correspondence to the openings. The first encapsulant is disposed between the substrate and the frame and encapsulates the first chip. The package is disposed on the frame and is electrically connected to the substrate via the first conductive connectors.