A method includes placing an electronic die and a photonic die over a carrier, with a back surface of the electronic die and a front surface of the photonic die facing the carrier. The method further includes encapsulating the electronic die and the photonic die in an encapsulant, planarizing the encapsulant until an electrical connector of the electronic die and a conductive feature of the photonic die are revealed, and forming redistribution lines over the encapsulant. The redistribution lines electrically connect the electronic die to the photonic die. An optical coupler is attached to the photonic die. An optical fiber attached to the optical coupler is configured to optically couple to the photonic die.

A semiconductor package includes a semiconductor substrate, a conductive pad on the semiconductor substrate, a redistribution line conductor, a coating insulator, and an aluminum oxide layer. The redistribution line conductor is electrically connected to the conductive pad. The coating insulator covers the redistribution line conductor and partially exposes the redistribution line conductor. The aluminum oxide layer is provided below the coating insulator and extends along a top surface of the redistribution line conductor, and the aluminum oxide layer is in contact with the redistribution line conductor.

The present disclosure provides a method for fabricating a semiconductor device including providing a first semiconductor die, forming a connection dielectric layer above the first semiconductor die, forming a first bottom protection layer in the connection dielectric layer, forming a first conductive plate on the first bottom protection layer, and forming a first top protection layer on the first conductive plate. The first bottom protection layer and the first top protection layer are formed of manganese-zinc ferrite, nickel-zinc ferrite, cobalt ferrite, strontium ferrite, barium ferrite, lithium ferrite, lithium-zinc ferrite, single crystal yttrium iron garnet, or gallium substituted single crystal yttrium iron garnet.

Multichip package manufacturing process is disclosed to form external pins at one side or each side of die-bonding area of package carrier board and to bond first IC and second IC to die-bonding area in stack. First IC and second IC each comprise transistor layer with core circuits, plurality of metal layers, plurality of VIA layers and solder pad layer. During production of first IC, design of at least one metal layer, VIA layer and dummy pads can be modified according to change of design of second IC. After chip probing, die sawing and bonding, wire bonding, packaging and final test are performed to package the package carrier board, first IC and second IC into automotive multichip package, achieving purpose of first IC only need to modify at least one layer or more than one layer to cooperate with second IC design change to carry out multichip packaging process.

A chip package including an integrated circuit component, a thermal conductive layer, an insulating encapsulant and a redistribution circuit structure is provided. The integrated circuit component includes an amorphous semiconductor portion located at a back surface thereof. The thermal conductive layer covers the amorphous semiconductor portion of the integrated circuit component, wherein thermal conductivity of the thermal conductive layer is greater than or substantially equal to 10 W/mK. The insulating encapsulant laterally encapsulates the integrated circuit component and the thermal conductive layer. The redistribution circuit structure is disposed on the insulating encapsulant and the integrated circuit component, wherein the redistribution circuit structure is electrically connected to the integrated circuit component.

Exemplary embodiments for redistribution layers of integrated circuit components are disclosed. The redistribution layers of integrated circuit components of the present disclosure include one or more arrays of conductive contacts that are configured and arranged to allow a bonding wave to displace air between the redistribution layers during bonding. This configuration and arrangement of the one or more arrays minimize discontinuities, such as pockets of air to provide an example, between the redistribution layers during the bonding.

In some embodiments, an integrated chip (IC) is provided. The IC includes a metallization structure disposed over a semiconductor substrate, where the metallization structure includes an interconnect structure disposed in an interlayer dielectric (ILD) structure. A passivation layer is disposed over the metallization structure, where an upper surface of the interconnect structure is at least partially disposed between opposite inner sidewalls of the passivation layer. A sidewall spacer is disposed along the opposite inner sidewalls of the passivation layer, where the sidewall spacer has rounded sidewalls. A conductive structure is disposed on the passivation layer, the rounded sidewalls of the sidewall spacer, and the upper surface of the interconnect structure.

This application provides a chip apparatus, including a die, a first bond pad, a second bond pad, and a first solder pad. The first bond pad and the second bond pad are disposed on an upper surface of the die. A first power module and a second power module are disposed in the die. The first power module is coupled to the first bond pad. The second power module is coupled to the second bond pad. The first solder pad is separately coupled to an external power supply of the chip apparatus, the first bond pad, and the second bond pad. According to the foregoing technical solution, isolation between different power modules is improved, and noise transmitted on a power supply path can be better filtered out. This improves power supply noise performance of the chip apparatus.

A multi-pin wafer level chip scale package is achieved. One or more solder pillars and one or more solder blocks are formed on a silicon wafer wherein the one or more solder pillars and the one or more solder blocks all have a top surface in a same horizontal plane. A pillar metal layer underlies the one or more solder pillars and electrically contacts the one or more solder pillars with the silicon wafer through an opening in a polymer layer over a passivation layer. A block metal layer underlies the one or more solder blocks and electrically contacts the one or more solder pillars with the silicon wafer through a plurality of via openings through the polymer layer over the passivation layer wherein the block metal layer is thicker than the pillar metal layer.

A semiconductor package includes a first die; a first redistribution structure over the first die, the first redistribution structure being conterminous with the first die; a second die over the first die, a first portion of the first die extending beyond a lateral extent of the second die; a conductive pillar over the first portion of the first die and laterally adjacent to the second die, the conductive pillar electrically coupled to first die; a molding material around the first die, the second die, and the conductive pillar; and a second redistribution structure over the molding material, the second redistribution structure electrically coupled to the conductive pillar and the second die.