An electronic component includes a covered object, an electrode that covers the covered object and has an electrode side wall on the covered object, an inorganic insulating film that has an inner covering portion covering the electrode such as to expose the electrode side wall, and an organic insulating film that covers the electrode side wall.

A semiconductor device includes: a semiconductor element that includes an element main body having an element main surface and an element back surface facing opposite sides to each other in a thickness direction, and a first electrode arranged on the element main surface; an insulator that has an annular shape overlapping an outer peripheral edge of the first electrode when viewed in the thickness direction and is arranged over the first electrode and the element main surface; a first metal layer arranged over the first electrode and the insulator; and a second metal layer laminated on the first metal layer and overlapping both the first electrode and the insulator when viewed in the thickness direction.

Embossed solder masks for a semiconductor device assembly, and associated methods and systems are disclosed. In one embodiment, a package substrate includes the solder mask with non-planar features along a surface of the solder mask such that the area of the surface is increased. The non-planar features may correspond to concave recesses formed on the surface of the solder mask. Physical dimensions (e.g., widths, depths) and/or areal densities of the non-planar features of the embossed solder masks may vary based on local areas of the package substrate exclusive of conductive bumps. The non-planar features may be formed by pressing a mold having convex features against the surface of the solder mask. The solder mask may be heated while pressing the mold against the surface of the solder mask. In some embodiments, the mold includes regions lacking the convex features.

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 device includes an interconnect structure, a barrier multi-layer structure, an oxide layer, a pad metal layer, and a passivation layer. The barrier multi-layer structure is over the interconnect structure, the barrier multi-layer structure includes a first metal nitride layer and a second metal nitride layer over the first metal nitride layer. The oxide layer is over the barrier multi-layer structure, in which the oxide layer is an oxide of the second metal nitride layer of the barrier multi-layer structure. The pad metal layer is over the oxide layer. The passivation layer is in contact with the barrier multi-layer structure, the oxide layer, and the pad metal layer.

A semiconductor device includes a first die, a second die bonding to the first die thereby forming a bonding interface, and a pad of the first die and exposed from a polymeric layer of the first die. The semiconductor device further has a conductive material on the pad and extended from the pad in a direction parallel to a stacking direction of the first die and the second die. In the semiconductor device, the conductive material extended to a top surface, which is vertically higher than a backside of the second die, wherein the backside is a surface opposite to the bonding interface.

A semiconductor device includes an interconnect structure disposed over a first semiconductor die. The first semiconductor die includes a semiconductor substrate and a first conductive pad disposed over the semiconductor substrate, and the first conductive pad is covered by the interconnect structure. The semiconductor device also includes dielectric spacers surrounding the interconnect structure. An interface between the dielectric spacers and the interconnect structure is curved. The semiconductor device further includes a dielectric layer surrounding the dielectric spacers, and a second semiconductor die bonded to the dielectric layer and the interconnect structure. The second semiconductor die includes a second conductive pad, and the interconnect structure is covered by the second conductive pad.

Provided is a substrate structure, including: a substrate body having a conductive contact; an insulating layer formed on the substrate body with the conductive contact exposed therefrom; and an insulating protection layer formed on a portion of a surface of the insulating layer, and having a plurality of openings corresponding to the conductive contact, wherein at least one of the openings is disposed at an outer periphery of the conductive contact. Accordingly, the insulating protection layer uses the openings to dissipate and disperse residual stresses in a manufacturing process of high operating temperatures.

A stack including a dual-passivation is etched locally so as to reveal contact pads of an integrated circuit which are situated above a last metallization level of an interconnection part of the integrated circuit. This stack serves to protect the integrated circuit against a breakdown of at least one dielectric region, at least in part porous, separating two electrically conducting elements of the interconnection part of the integrated circuit. Such a breakdown may occur due to electrical conduction assisted by the presence of defects within the at least one dielectric region.

A method of hybridizing an FPA having an IR component and a ROIC component and interconnects between the two components, includes the steps of: providing an IR detector array and a Si ROIC; depositing a dielectric layer on both the IR detector array and on the Si ROIC; patterning the dielectric on both components to create openings to expose contact areas on each of the IR detector array and the Si ROIC; depositing indium to fill the openings on both the IR detector array and the Si ROIC to create indium bumps, the indium bumps electrically connected to the contact areas of the IR detector array and the Si ROIC respectively, exposed on a top surface of the IR detector array and the Si ROIC; activating exposed dielectric layers on the IR detector array and the Si ROIC in a plasma; and closely contacting the indium bumps of the IR detector array and the Si ROIC by bonding together the exposed dielectric surfaces of the IR detector array and the Si ROIC. Another exemplary method provides a pillar support of the indium bumps on the IR detector array rather than a full dielectric layer support. Another exemplary method includes a surrounding dielectric edge support between the IR detector array and the Si ROIC with the pillar supports.