A semiconductor device including a semiconductor substrate including an electrode; a wire connected to the electrode; a first insulating film including a first opening that partially exposes the wire; a base portion that is connected to a portion of the wire exposed via the first opening, and that includes a conductor including a recess corresponding to the first opening; and a solder film on a surface of the base portion. Solder included in the solder film is fused by a first heat treatment, and the recess is filled with the fused solder.

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.

Integrated circuit IC package with one or more IC dies including solder features that are thermally coupled to the IC. The thermally coupled solder features (e.g., bumps) may be electrically insulated from solder features electrically coupled to the IC, but interconnected with each other by one or more metallization layers within a plane of the IC package. An in-plane interconnected network of thermal solder features may improve lateral heat transfer, for example spreading heat from one or more hotspots on the IC die. An under-bump metallization (UBM) may interconnect two or more thermal solder features. A through-substrate via (TSV) metallization may interconnect two or more thermal solder features. A stack of IC dies may include thermal solder features interconnected by metallization within one or more planes of the stack.

An interconnection structure of a semiconductor chip may include an interconnection via, a lower pad, a conductive bump, and an upper pad. The interconnection via may be arranged in the semiconductor chip. The lower pad may be arranged on a lower end of the interconnection via exposed through a lower surface of the semiconductor chip. The conductive bump may be arranged on the lower pad. The upper pad may be arranged on an upper end of the interconnection via exposed through an upper surface of the semiconductor chip. The upper pad may have a width wider than a width of the interconnection via and narrower than a width of the lower pad. Thus, an electrical short between the conductive bumps may not be generated in the interconnection structure having a thin thickness.

A semiconductor device may include a semiconductor chip in an encapsulant. A first insulation layer may be disposed on the encapsulant and the semiconductor chip. A horizontal wiring and a primary pad may be disposed on the first insulation layer. A secondary pad may be disposed on the primary pad. A second insulation layer covering the horizontal wiring may be disposed on the first insulation layer. A solder ball may be disposed on the primary pad and the secondary pad. The primary pad may have substantially the same thickness as a thickness of the horizontal wiring.

A wafer level package, electronic device including the wafer level package, and fabrication methods are described that include forming a cantilever pillar design as a portion of the wafer level package and/or a segmented solder connection for preventing and reducing connection stress and increasing board level reliability. In implementations, the wafer level device that employs example techniques in accordance with the present disclosure includes at least a section of a processed semiconductor wafer including at least one integrated circuit die, a first dielectric layer disposed on the processed semiconductor wafer, a first pillar, a second pillar formed on the first pillar, a second dielectric layer formed on the first dielectric layer and surrounding a portion of the first pillar and the second pillar, and at least one solder ball disposed on the second pillar.

A semiconductor wafer has a plurality of semiconductor die with contact pads for electrical interconnect. An insulating layer is formed over the semiconductor wafer. A bump structure is formed over the contact pads. The bump structure has a buffer layer formed over the insulating layer and contact pad. A portion of the buffer layer is removed to expose the contact pad and an outer portion of the insulating layer. A UBM layer is formed over the buffer layer and contact pad. The UBM layer follows a contour of the buffer layer and contact pad. A ring-shaped conductive pillar is formed over the UBM layer using a patterned photoresist layer filled with electrically conductive material. A conductive barrier layer is formed over the ring-shaped conductive pillar. A bump is formed over the conductive barrier layer. The buffer layer reduces thermal and mechanical stress on the bump and contact pad.

A semiconductor device includes a semiconductor layer that has a main surface, an electrode pad that is formed on the main surface, a rewiring that has a first wiring surface connected to the electrode pad and a second wiring surface positioned on a side opposite to the first wiring surface and being roughened, the rewiring being formed on the main surface such as to be drawn out to a region outside the electrode pad, and a resin that covers the second wiring surface on the main surface and that seals the rewiring.

A semiconductor device may include a semiconductor chip in an encapsulant. A first insulation layer may be disposed on the encapsulant and the semiconductor chip. A horizontal wiring and a primary pad may be disposed on the first insulation layer. A secondary pad may be disposed on the primary pad. A second insulation layer covering the horizontal wiring may be disposed on the first insulation layer. A solder ball may be disposed on the primary pad and the secondary pad. The primary pad may have substantially the same thickness as a thickness of the horizontal wiring.

The present disclosure provides a method for forming a semiconductor package and a semiconductor package. The method comprises providing a semiconductor wafer with at least one semiconductor device formed thereon, the at least one semiconductor device comprising a plurality of metal bond pads formed on the semiconductor wafer. The method further comprises forming a first photoresist layer having a first opening directly above at least a portion of a first metal bond pad; forming a first metal feature of a first height in the first opening; removing the first photoresist layer; forming a second photoresist layer having a second opening directly above at least a portion of the second metal bond pad; forming a second metal feature of a second height in the second opening; and removing the second photoresist layer. Using the method, metal bumps having different heights and different sizes can be formed in a controlled manner.