A semiconductor package includes a plurality of semiconductor chips on a substrate. The semiconductor chips include a first semiconductor chip, a second semiconductor chip, and a third semiconductor chip that are sequentially stacked on the substrate. The semiconductor package further includes a plurality of non-conductive layers between the substrate and the first semiconductor chip and between adjacent semiconductor chips among the semiconductor chips. The semiconductor chips include smaller widths as a distance from the substrate increases. Each of the non-conductive layers includes an extension protruding outward from a side surface of an overlying one of the semiconductor chips.

A chip package including a heat-dissipating device, a first thermal interface material layer disposed on the heat-dissipating device, a patterned circuit layer disposed on the first thermal interface material layer, a chip disposed on the patterned circuit layer and electrically connected to the patterned circuit layer, and an insulating encapsulant covering the chip, the patterned circuit layer, and the first thermal interface material layer is provided. The first thermal interface material layer has a thickness between 100 μm and 300 μm. The first thermal interface material layer is located between the patterned circuit layer and the heat-dissipating device.

A semiconductor device includes a solder supporting material above a substrate. The semiconductor device also includes a solder on the solder supporting material. The semiconductor device further includes selective laser annealed or laser ablated portions of the solder and underlying solder supporting material to form a semiconductor device having 3D features.

A semiconductor arrangement includes a lower semiconductor chip, an upper semiconductor chip arranged over an upper main side of the lower semiconductor chip, a metallization layer arranged on the upper main side of the lower semiconductor chip, and a bonding material which fastens the upper semiconductor chip on the lower semiconductor chip. The metallization layer includes a structure with increased roughness in comparison with the rest of the metallization layer, the structure being arranged along a contour of the upper semiconductor chip.

A method and structure for packaging a semiconductor device are provided. In an embodiment a first substrate is bonded to a second substrate, which is bonded to a third substrate. A thermal interface material is placed on the second substrate prior to application of an underfill material. A ring can be placed on the thermal interface material, and an underfill material is dispensed between the second substrate and the third substrate. By placing the thermal interface material and ring prior to the underfill material, the underfill material cannot interfere with the interface between the thermal interface material and the second substrate, and the thermal interface material and ring can act as a physical barrier to the underfill material, thereby preventing overflow.

A semiconductor package includes a first chip, an insulating protection layer, a second chip, a plurality of second conductive bumps and an underfill. The insulating protection layer is disposed on a first active surface of the first chip and includes a concave. Projections of a plurality of first inner pads and a plurality of first outer pads of the first chip projected on the insulating protection layer are located in the concave and out of the concave, respectively. The second chip is flipped on the concave and includes a plurality of second pads. Each of the first inner pads is electrically connected to the corresponding second pad through the corresponding second conductive bump. The underfill is disposed between the concave and the second chip and covers the second conductive bumps.

A method comprises forming a plurality of interconnect structures including a dielectric layer, a metal line and a redistribution line over a carrier, attaching a semiconductor die on a first side of the plurality of interconnect structures, forming an underfill layer between the semiconductor die and the plurality of interconnect structures, mounting a top package on the first side the plurality of interconnect structures, wherein the top package comprises a plurality of conductive bumps, forming an encapsulation layer over the first side of the plurality of interconnect structures, wherein the top package is embedded in the encapsulation layer, detaching the carrier from the plurality of interconnect structures and mounting a plurality of bumps on a second side of the plurality of interconnect structures.

A circuit board and a smart card module and a smart card employing the circuit board are provided. The circuit board includes a substrate and a pad region provided on the substrate. The pad region is configured for mounting an electronic component, and comprises a plurality of pads spaced from each other and traces connected to their respective pads. At least one of the pads has an arc edge. In the present invention, the distance between the pads is easy to be controlled during fabrication, and the stability of the adhesion between the chip and pad region is enhanced.

A structure including a photonic integrated circuit die, an electric integrated circuit die, a semiconductor dam, and an insulating encapsulant is provided. The photonic integrated circuit die includes an optical input/output portion and a groove located in proximity of the optical input/output portion, wherein the groove is adapted for lateral insertion of at least one optical fiber. The electric integrated circuit die is disposed over and electrically connected to the photonic integrated circuit die. The semiconductor dam is disposed over the photonic integrated circuit die. The insulating encapsulant is disposed over the photonic integrated circuit die and laterally encapsulates the electric integrated circuit die and the semiconductor dam.

A semiconductor device includes an insulated circuit board in which a metal layer is formed on one surface of an insulating board and a semiconductor element having a polygonal shape when viewed in a plan view that is bonded to the metal layer via a bonding material. The metal layer of the insulated circuit board has a recess that exposes the insulating board at a position corresponding to at least one corner of the semiconductor element.