The present application provides a semiconductor structure and a forming method thereof. The method of forming the semiconductor structure includes: providing a semiconductor chip and a substrate; forming, on the substrate, a first covering film covering a metal pad and a surface of the substrate, a plurality of up-narrow and down-wide openings being formed in the first covering film, and a bottom of each of the up-narrow and down-wide openings correspondingly exposing a surface of the metal pad; and flipping the semiconductor chip onto the substrate, such that a solder bump on a metal pillar is correspondingly located in the up-narrow and down-wide opening, and the solder bump fill the up-narrow and down-wide opening.

A package comprising a substrate and an integrated device coupled to the substrate. The substrate includes a core layer comprising a first surface and a second surface; at least one first dielectric layer coupled to the first surface of the core layer; at least one second dielectric layer coupled to the second surface of the core layer; at least one core interconnect that extends through the core layer and at least one dielectric layer from the at least first dielectric layer and/or the at least one second dielectric layer; a plurality of high-density interconnects comprising a first minimum width and a first minimum spacing; and a plurality of interconnects comprising a second minimum width and a second minimum spacing. The second minimum width is greater than the first minimum width. The second minimum spacing is greater than the first minimum spacing.

A semiconductor device including a semiconductor die, a first conductive pad, a second conductive pad, a first connector structure and a second connector structure is provided. The first conductive pad is disposed on the semiconductor die, wherein the first conductive pad has a first lateral dimension. The second conductive pad is disposed on the semiconductor die, wherein the second conductive pad has a second lateral dimension. The first connector structure is disposed on the first conductive pad, wherein the first connector structure has a third lateral dimension greater than the first lateral dimension. The second connector structure is disposed on the second conductive pad, wherein the second connector structure has a fourth lateral dimension smaller than the second lateral dimension.

A semiconductor package includes a first sub-package and a second sub-package. The first sub-package is stacked atop the second sub-package. Each of the first sub-package and the second sub-package includes at least two first semiconductor dies, a second semiconductor die, a plurality of molding pieces, a bond-pad layer, a plurality of redistribution layers (RDLs) and a plurality of bumps. The bumps of the first sub-package are attached to the bond-pad layer of the second sub-package.

In accordance with some embodiments of the present disclosure, a packaged semiconductor device includes a first package structure, at least one outer conductive bump, a second package structure, a sealing material, and an electromagnetic interference (EMI) shielding layer. The first package structure has a first cut edge. The outer conductive bump is disposed on the first package structure and has a second cut edge. The second package structure is jointed onto the first package structure. The sealing material is disposed on the first package structure, surrounds the second package structure, and covers the outer conductive bump. The sealing material has a third cut edge. The EMI shielding layer contacts the first cut edge, the second cut edge and the third cut edge. The EMI shielding layer is electrically connected with the outer conductive bump.

A semiconductor device having an electrode type of the ball grid array (BGA) and a process of forming the electrode are disclosed. The electrode insulating film, a seed layer on the insulating film, a mound metal on the insulating film and an interconnection on the seed layer. The mound metal surrounds the seed layer without forming any gap therebetween. The interconnection, which is formed by electroless plating, is apart from the insulating film with the mound metal as an extension barrier for the plating.

A semiconductor device has a temporary carrier. A semiconductor die is oriented with an active surface toward, and mounted to, the temporary carrier. An encapsulant is deposited with a first surface over the temporary carrier and a second surface, opposite the first surface, is deposited over a backside of the semiconductor die. The temporary carrier is removed. A portion of the encapsulant in a periphery of the semiconductor die is removed to form an opening in the first surface of the encapsulant. An interconnect structure is formed over the active surface of the semiconductor die and extends into the opening in the encapsulant layer. A via is formed and extends from the second surface of the encapsulant to the opening. A first bump is formed in the via and electrically connects to the interconnect structure.

A semiconductor device has a conductive via in a first surface of a substrate. A first interconnect structure is formed over the first surface of the substrate. A first bump is formed over the first interconnect structure. The first bump is formed over or offset from the conductive via. An encapsulant is deposited over the first bump and first interconnect structure. A portion of the encapsulant is removed to expose the first bump. A portion of a second surface of the substrate is removed to expose the conductive via. The encapsulant provides structural support and eliminates the need for a separate carrier wafer when thinning the substrate. A second interconnect structure is formed over the second surface of the substrate. A second bump is formed over the first bump. A plurality of semiconductor devices can be stacked and electrically connected through the conductive via.

According to example configurations herein, an apparatus comprises a die and a host substrate. The die can include a first transistor and a second transistor. A surface of the die includes multiple conductive elements disposed thereon. The multiple conductive elements on the surface are electrically coupled to respective nodes of the first transistor and the second transistor. Prior to assembly, the first transistor and second transistor are electrically isolated from each other. During assembly, the surface of the die including the respective conductive elements is mounted on a facing of the host substrate. Accordingly, a die including multiple independent transistors can be flipped and mounted to a respective host substrate such as printed circuit board, lead frame, etc.

The present disclosure provides a semiconductor chip including a semiconductor substrate having a front surface and a rear surface which faces away from the front surface. The semiconductor chip includes a fixed metal layer formed over the front surface of the semiconductor substrate, and having first metal lines formed in the fixed metal layer. The semiconductor chip includes a configurable metal layer formed over the fixed metal layer to have one surface which faces the fixed metal layer and the other surface which faces away from the one surface, and having second metal lines formed in the configurable metal layer such that at least one end of the second metal lines disposed on the one surface are respectively connected with the first metal lines and other ends of the second metal lines facing away from the at least one end are disposed at predetermined positions on the other surface.