A semiconductor package includes a semiconductor die including a semiconductor substrate, a strain-sensitive component located within or over a metallization layer of the semiconductor die, wherein a parameter of the strain-sensitive component exhibits a longitudinal shift due to a longitudinal strain and a transverse shift due to a transverse strain, and a mold compound covering the semiconductor die and the strain-sensitive component. The semiconductor package, including the semiconductor die and the mold compound, defines an orthogonal package-induced strain ratio on the strain-sensitive component on the semiconductor die surface. The strain-sensitive component is located such that the longitudinal shift due to package-induced strains offsets the transverse shift due to the package-induced strains.

The present technology relates to a semiconductor device, an imaging device, and a manufacturing apparatus, capable of providing a semiconductor substrate maintaining and improving insulating performance. A through hole that penetrates the semiconductor substrate, an electrode at the center of the through hole, and a space around the electrode are included. The through hole also penetrates an insulating film formed on the semiconductor substrate. A barrier metal is further included around the electrode. An insulating film is further included in the semiconductor substrate and the space. The semiconductor device has a multilayer structure, and the electrode connects wirings formed in different layers to each other. The present technology can be applied to, for example, an image sensor in which a logic circuit and a sensor circuit are laminated.

A semiconductor device includes a semiconductor element, a first lead including a mounting portion for the semiconductor element and a first terminal portion connected to the mounting portion, and a sealing resin covering the semiconductor element and a portion of the first lead. The mounting portion has a mounting-portion front surface and a mounting-portion back surface opposite to each other in a thickness direction, with the semiconductor element mounted on the mounting-portion front surface. The sealing resin includes a resin front surface, a resin back surface and a resin side surface connecting the resin front surface and the resin back surface. The mounting-portion back surface of the first lead is flush with the resin back surface. The first terminal portion includes a first-terminal-portion back surface exposed from the resin back surface, in a manner such that the first-terminal-portion back surface extends to the resin side surface.

According to one aspect, a semiconductor device includes: a buffer layer disposed on a front surface of a second semiconductor layer, and having at least one opening in plan view; and an electrode disposed over the second semiconductor layer and the buffer layer, and being in contact with the second semiconductor layer through the at least one opening, wherein the buffer layer has a higher Vickers hardness than the electrode, and a width w of each of the at least one opening satisfies w<W.sub.th, where s is a thickness of the buffer layer, t is a thickness of the electrode, and W.sub.th=2×(s×t−s.sup.2).sup.0.5 holds true.

Disclosed is a semiconductor device suppressed in decrease of reliability. The semiconductor device comprises an electrode pad portion (2) formed on the upper surface of a semiconductor substrate (1), a passivation layer (3) so formed on the upper surface of the semiconductor substrate (1) as to overlap a part of the electrode pad portion (2) and having a first opening portion (3a) where the upper surface of the electrode pad portion (2) is exposed, a barrier metal layer (5) formed on the electrode pad portion (2), and a solder bump (6) formed on the barrier metal layer (5). The barrier metal layer (5) is formed such that an outer peripheral end (5b) lies within the first opening portion (3a) of the passivation layer (3) when viewed in plan.

According to one embodiment, a semiconductor device includes a first chip with a first electrode and a second electrode and a second chip with a third electrode and a fourth electrode. The first and second chips are bonded to each other with the first electrode contacting the third electrode and the second electrode contacting the fourth electrode. A thickness of the first electrode in a first direction perpendicular to a bonding interface between the first chip and the second chip is less than a thickness of the second electrode in the first direction. A planar area of the first electrode at the bonding interface is greater than a planar area of the second electrode at the bonding interface.

There is a need to improve reliability of the semiconductor device. A semiconductor device includes a printed circuit board and a semiconductor chip mounted over the printed circuit board. The semiconductor chip includes a pad, an insulation film including an opening to expose part of the pad, and a pillar electrode formed over the pad exposed from the opening. The printed circuit board includes a terminal and a resist layer including an opening to expose part of the terminal. The pillar electrode of the semiconductor chip and the terminal of the printed circuit board are coupled via a solder layer. Thickness h.sub.1 of the pillar electrode is measured from the upper surface of the insulation film. Thickness h.sub.2 of the solder layer is measured from the upper surface of the resist layer. Thickness h.sub.1 is greater than or equal to a half of thickness h.sub.2 and is smaller than or equal to thickness h.sub.2.

In one embodiment, a semiconductor device includes a first insulator, a first pad provided in the first insulator, a second insulator provided on the first insulator, and a second pad provided on the first pad in the second insulator. Furthermore, the first insulator includes a first film that is in contact with the first pad and the second insulator, and a second film provided at an interval from the first pad and the second insulator, and including a portion provided at a same height as at least a portion of the first pad.

A bonding pad structure and a method thereof includes: a base metal layer formed on a substrate; first conductive vias arranged in a peripheral region of the base metal layer; an intermediate buffer layer formed above the base metal layer, the intermediate buffer layer spaced from and aligned with the base metal layer, the first conductive vias vertically connecting the base metal layer and the intermediate buffer layer; second conductive vias arranged in a peripheral region of the intermediate buffer layer; a surface bonding layer formed above the intermediate buffer layer, the surface bonding layer spaced from and aligned with the intermediate buffer layer, the second conductive vias vertically connecting the intermediate buffer layer and the surface bonding layer, the intermediate buffer layer comprising a mesh structure, and the first conductive vias and the second conductive vias not vertically aligned with a central region of the intermediate buffer layer.

A bonding pad structure and a method thereof includes: a base metal layer formed on a substrate; first conductive vias arranged in a peripheral region of the base metal layer; an intermediate buffer layer formed above the base metal layer, the intermediate buffer layer spaced from and aligned with the base metal layer, the first conductive vias vertically connecting the base metal layer and the intermediate buffer layer; second conductive vias arranged in a peripheral region of the intermediate buffer layer; a surface bonding layer formed above the intermediate buffer layer, the surface bonding layer spaced from and aligned with the intermediate buffer layer, the second conductive vias vertically connecting the intermediate buffer layer and the surface bonding layer, the intermediate buffer layer comprising a mesh structure, and the first conductive vias and the second conductive vias not vertically aligned with a central region of the intermediate buffer layer.