The present application discloses a method for fabricating a semiconductor device with graphene layers The method includes providing a substrate; forming a first passivation layer above the substrate; forming a redistribution layer on the first passivation layer; forming a first adjustment layer on the redistribution layer; forming a pad layer on the first adjustment layer; forming a second adjustment layer between the pad layer and the first adjustment layer; forming a second passivation layer on the first passivation layer; wherein the first adjustment layer and the second adjustment layer are formed of graphene.

The present disclosure provides an integrated circuit (IC) structure. The IC structure includes a semiconductor substrate; an interconnection structure formed on the semiconductor substrate; and a redistribution layer (RDL) metallic feature formed on the interconnection structure. The RDL metallic feature further includes a barrier layer disposed on the interconnection structure; a diffusion layer disposed on the barrier layer, wherein the diffusion layer includes metal and oxygen; and a metallic layer disposed on the diffusion layer.

The present disclosure provides an integrated circuit (IC) structure. The IC structure includes a semiconductor substrate; an interconnection structure formed on the semiconductor substrate; and a redistribution layer (RDL) metallic feature formed on the interconnection structure. The RDL metallic feature further includes a barrier layer disposed on the interconnection structure; a diffusion layer disposed on the barrier layer, wherein the diffusion layer includes metal and oxygen; and a metallic layer disposed on the diffusion layer.

A method of forming a conductive material on a semiconductor device. The method comprises removing at least a portion of a conductive pad within an aperture in a dielectric material over a substrate. The method further comprises forming a seed material at least within a bottom of the aperture and over the dielectric material, forming a protective material over the seed material within the aperture, and forming a conductive pillar in contact with the seed material through an opening in the protective material over surfaces of the seed material within the aperture. A method of forming an electrical connection between adjacent semiconductor devices, and a semiconductor device, are also described.

A method of forming a conductive material on a semiconductor device. The method comprises removing at least a portion of a conductive pad within an aperture in a dielectric material over a substrate. The method further comprises forming a seed material at least within a bottom of the aperture and over the dielectric material, forming a protective material over the seed material within the aperture, and forming a conductive pillar in contact with the seed material through an opening in the protective material over surfaces of the seed material within the aperture. A method of forming an electrical connection between adjacent semiconductor devices, and a semiconductor device, are also described.

A method of manufacturing a bonded body in which a first body and a second body are bonded using a glass paste. The glass paste includes a crystallized glass frit (A) and a solvent (B). A remelting temperature of the crystallized glass frit (A) is higher than a crystallization temperature thereof which is higher than a glass transition temperature thereof. The method includes: applying the glass paste on at least one of the first and second bodies, bonding the first and second bodies by interposing the glass paste therebetween, heating the bonded first and second bodies to a temperature that is not lower than the crystallization temperature and lower than the remelting temperature of the crystallized glass frit (A), and obtaining the bonded body by cooling the bonded first and second bodies to a temperature that is not higher than the glass transition temperature of the crystallized glass frit.

A method of forming a conductive material on a semiconductor device. The method comprises removing at least a portion of a conductive pad within an aperture in a dielectric material over a substrate. The method further comprises forming a seed material at least within a bottom of the aperture and over the dielectric material, forming a protective material over the seed material within the aperture, and forming a conductive pillar in contact with the seed material through an opening in the protective material over surfaces of the seed material within the aperture. A method of forming an electrical connection between adjacent semiconductor devices, and a semiconductor device, are also described.

A method of forming a conductive material on a semiconductor device. The method comprises removing at least a portion of a conductive pad within an aperture in a dielectric material over a substrate. The method further comprises forming a seed material at least within a bottom of the aperture and over the dielectric material, forming a protective material over the seed material within the aperture, and forming a conductive pillar in contact with the seed material through an opening in the protective material over surfaces of the seed material within the aperture. A method of forming an electrical connection between adjacent semiconductor devices, and a semiconductor device, are also described.

A die and a substrate are provided. The die comprises at least one integrated circuit chip, and the substrate comprises first and second subsets of conductive pillars extending at least partially therethrough. Each of the first subset of conductive pillars comprises a protrusion bump pad protruding from a surface of the substrate, and the second subset of conductive pillars each partially form a trace recessed within the surface of the substrate. The die is coupled to the substrate via a plurality of conductive bumps each extending between one of the protrusion bump pads and the die.

A method for manufacturing semiconductor devices is provided. A protection layer is conformally deposited over a passivation layer such that the protection layer has a protrusion pattern that protrudes from a top surface of the protection layer. Further, a post-passivation interconnect structure (PPI) is conformally formed on the protection layer such that the PPI structure includes a landing pad region, a protrusion pattern conformal to the protrusion pattern of the protection layer, and a connection line electrically connected to the conductive pad. A solder bump is then placed on the landing pad region in contact with the protrusion pattern of PPI structure. A semiconductor device with bump stop structure is also provided. The protrusion pattern of the PPI structure serves as a bump stop that constrains a ball shift in the placement of the solder bump over the landing pad.