Embodiments of this application disclose a hybrid bonding structure and a hybrid bonding method. The hybrid bonding structure includes a first chip and a second chip. A surface of the first chip includes a first insulation dielectric and a first metal, and a first gap area exists between the first metal and the first insulation dielectric. A surface of the second chip includes a second insulation dielectric and a second metal. A surface of the first metal is higher than a surface of the first insulation dielectric. Metallic bonding is formed after the first metal is in contact with the second metal, and the first metal is longitudinally and transversely deformed in the first gap area. Insulation dielectric bonding is formed after the first insulation dielectric is in contact with the second insulation dielectric.

A semiconductor device may include: a first semiconductor structure including a first conductive layer and four first bonding pads connected to the first conductive layer; and a second semiconductor structure including a second conductive layer and four second bonding pads connected to the second conductive layer, wherein the four first bonding pads are configured to be disposed to have respective centers each overlapping four intersections that are formed by two virtual first straight lines extending in parallel in a first direction and two virtual second straight lines extending in parallel in a second direction intersecting the first direction, where each of the four first bonding pads has four quadrants divided by the first straight line and the second straight line, and wherein, when the first semiconductor structure and the second semiconductor structure are normally aligned, the four second bonding pads are configured to be disposed to have respective centers that are displaced in directions from the respective centers of the four first bonding pads toward different quadrants.

This document discloses techniques, apparatuses, and systems for a semiconductor device with a polymer layer. A semiconductor assembly is described that includes two semiconductor dies. The first semiconductor die has a first active side with first circuitry and a first back side opposite the first active side. Contact pads and a layer of polymer material are disposed at the first back side such that the layer of polymer material includes openings that expose the contact pads. The second semiconductor die has second circuitry disposed at a second active side. Interconnect structures are also disposed at the second active side such that the interconnect structures extend into the openings and couple to contact pads. A passivation layer (e.g., dielectric material) is disposed at the second active side and directly bonded to the layer of polymer material to reliably couple the two semiconductor dies.

A package structure including a semiconductor die, an encapsulant, a redistribution structure, and a through insulating via is provided. The first redistribution structure includes an insulating layer and a circuit layer. The semiconductor die is disposed on the first redistribution structure. The semiconductor die includes a semiconductor base, through semiconductor vias, a dielectric layer, and bonding connectors. Through semiconductor vias penetrate through the semiconductor base. The dielectric layer is disposed on a backside of the semiconductor base. The dielectric layer of the semiconductor die is bonded with the insulating layer of the first redistribution structure. The bonding connectors are embedded in the dielectric layer and connected to the through semiconductor vias. The bonding connectors of the semiconductor die are bonded with bonding pads of the circuit layer. The encapsulant is disposed on the first redistribution structure and encapsulates the semiconductor die.

A bonding structure that may be used to form 3D-IC devices is formed using first oblong bonding pads on a first substrate and second oblong bonding pads one a second substrate. The first and second oblong bonding pads are laid crosswise, and the bond is formed. Viewed in a first cross-section, the first bonding pad is wider than the second bonding pad. Viewed in a second cross-section at a right angle to the first, the second bonding pad is wider than the first bonding pad. Making the bonding pads oblong and angling them relative to one another reduces variations in bonding area due to shifts in alignment between the first substrate and the second substrate. The oblong shape in a suitable orientation may also be used to reduce capacitive coupling between one of the bonding pads and nearby wires.

Embodiments of present invention provide a semiconductor structure. The semiconductor structure includes a first semiconductor wafer and a second semiconductor wafer; and a bonding structure between the first semiconductor wafer and the second semiconductor wafer, where the bonding structure includes a first coaxial pad embedded in a first dielectric layer and a second coaxial pad embedded in a second dielectric layer, and the first coaxial pad is substantially aligned with the second coaxial pad. In one embodiment, the first coaxial pad includes an inner pad of substantially rectangular shape and an outer pad of substantially rectangular ring shape surrounding the inner pad.

A semiconductor package includes a first redistribution wiring layer having a first region and a second region surrounding the first region, a semiconductor chip disposed on the first region of the first redistribution wiring layer, a sealing member covering the semiconductor chip on the first redistribution wiring layer, vertical conductive wires penetrating the sealing member on the second region of the first redistribution wiring layer, a second redistribution wiring layer disposed on the sealing member and including second redistribution wirings electrically connected to the vertical conductive wires, and bonding pads provided on an upper surface of the first redistribution wiring layer or a lower surface of the second redistribution wiring layer, each bonding pad having a concavo-convex pattern on an upper surface of the bonding pad. The vertical conductive wires are bonded to the concavo-convex patterns of the bonding pads, respectively.

Semiconductor package structures are provided. A semiconductor package structure includes a chip, a molding material surrounding the chip, a through-via extending from a first surface to a second surface of the molding material, and a first re-distribution layer (RDL) wire disposed on the second surface of the molding material and electrically separated from the through-via. The second surface is opposite to the first surface. A portion of the first RDL wire across the through-via has a first segment with a first width and a second segment with a second width different from the first width.

Semiconductor package structures are provided. A semiconductor package structure includes a chip, a molding material surrounding the chip, a through-via extending from a first surface to a second surface of the molding material, and a first re-distribution layer (RDL) wire disposed on the second surface of the molding material and electrically separated from the through-via. The second surface is opposite to the first surface. A portion of the first RDL wire across the through-via has a first segment with a first width and a second segment with a second width different from the first width.

A chip bonding method includes the following operations. A first chip is provided, which includes a first contact pad including a first portion lower than a first surface of a first substrate and a second portion higher than the first surface of the first substrate to form the stepped first contact pad. A second chip is provided, which includes a second contact pad including a third portion lower than a third surface of a second substrate and a fourth portion higher than the third surface of the second substrate to form the stepped second contact pad. The first chip and the second chip are bonded. The first portion of the first chip contacts with the fourth portion of the second chip, and the second portion of the first chip contacts with the third portion of the second chip.