A package structure is provided. The package structure includes a substrate and a semiconductor chip over the substrate. The package structure also includes a protective film laterally surrounding the semiconductor chip. The package structure further includes an underfill element between the semiconductor chip and the protective film. A portion of the underfill element is directly below the protective film.

A structure includes an Sn layer or an Sn alloy layer formed above a substrate, and an under barrier metal formed between the substrate and the Sn layer or Sn alloy layer. The under barrier metal is an Ni alloy layer containing Ni, and at least one selected from W, Ir, Pt, Au, and Bi, and can sufficiently inhibit generation of an intermetallic compound through a reaction, caused due to metal diffusion of a metal contained in the substrate, between the metal and Sn contained in the Sn layer or Sn alloy layer.

A semiconductor device includes first, second and third stacked chips with a first, second and third substrate, respectively, at least three first, second and third logical circuits, respectively, and at least two first, second and third vias, respectively, and a fourth chip stacked on the third chip having a fourth substrate, and at least three fourth logical circuits. First and second ones of the first to third logical circuits of the first to fourth chips are each configured to perform a first and second logical operation, respectively, on a first and second address input signal, respectively, received at the respective chip to thereby output a first and second address output signal, respectively. Third ones are each configured to activate the respective chip based on at least the second address output signal transmitted within the respective chip.

A semiconductor chip having at least two electrical contact points which are arranged on a main surface of the semiconductor chip is disclosed, a metallic reservoir layer being applied over the entire surface over or on the electrical contact point. A diffusion barrier layer is applied in direct contact on the metallic reservoir layer, the diffusion barrier layer being arranged offset with respect to the metallic reservoir layer, so that the metallic reservoir layer is partially freely accessible. In this case, the diffusion barrier layer forms an adhesion surface for a solder and/or a first solder component of the solder and/or a second solder component of the solder. Methods for connecting a semiconductor chip to a connection carrier are also given.

Semiconductor devices and methods of manufacturing are provided, wherein a first passivation layer is deposited over a top redistribution structure; a second passivation layer is deposited over the first passivation layer; and a first opening is formed through the second passivation layer. After the forming the first opening, the first opening is reshaped into a second opening; a third opening is formed through the first passivation layer; and filling the second opening and the third opening with a conductive material.

In one example, an electronic device includes an electronic component including a first side, a second side opposite to the first side, a lateral side connecting the first side to the second side, bond pads adjacent to the first side, and a passivation layer over the first side and including openings exposing the bond pads. A redistribution structure is over the passivation layer and the bond pads. The redistribution structure includes a conductive structure coupled to the bond pads and a dielectric structure. The conductive structure includes outward terminals. External interconnects are coupled to the outward terminals and a protection layer covers the lateral side of the electronic component. Other examples and related methods are also disclosed herein.

A semiconductor chip may include: a semiconductor substrate; a through silicon via that vertically penetrates the semiconductor substrate; an integrated device layer on a first surface of the semiconductor substrate and including integrated devices; a multi-wiring layer on the integrated device layer and including layers of wires; an upper metal layer on the multi-wiring layer and connected to the wires; and a lower metal layer on a second surface of the semiconductor substrate. The semiconductor substrate may include a lower bump area on the second surface of the semiconductor substrate, the lower bump area including bump pads thereon, and the lower metal layer may be on a periphery of the lower bump area.

Various aspects of the present disclosure generally relate to integrated circuit devices, and to a conductive structure with multiple support pillars. A device includes a die including a contact pad. The device also includes a conductive structure. The conductive structure includes multiple support pillars coupled to the die, a bridge coupled to each of the multiple support pillars, and a cap pillar coupled to the bridge opposite the multiple support pillars. The device further includes a solder cap coupled to the cap pillar. The solder cap is electrically connected to the contact pad via the cap pillar, the bridge, and at least one of the multiple support pillars.

This disclosure relates to embodiments that include an apparatus that may comprise a first layer including a first plurality of active devices, a second layer including a second plurality of active devices, and/or a third layer including a plurality of passive devices and disposed between the first and the second layers. An active device of the first plurality of active devices and an active device of the second plurality of active devices may influence a state of charge of a passive device of the plurality of passive devices.

An offset interposer includes a land side including land-side ball-grid array (BGA) and a package-on-package (POP) side including a POP-side BGA. The land-side BGA includes two adjacent, spaced-apart land-side pads, and the POP-side BGA includes two adjacent, spaced-apart POP-side pads that are coupled to the respective two land-side BGA pads through the offset interposer. The land-side BGA is configured to interface with a first-level interconnect. The POP-side BGA is configured to interface with a POP substrate. Each of the two land-side pads has a different footprint than the respective two POP-side pads.