The present disclosure describes a bonded semiconductor structure and a method of forming the bonded semiconductor structure. The bonded semiconductor structure includes first and second substrates bonded with a bonding structure. The bonding structure provides high thermal conductivity and high bonding strength between the first and second substrates. The bonding structure includes bonding layers and adhesion layers, with the bonding layers including titanium oxide and the adhesion layers including titanium nitride. The method includes forming a first adhesion layer on the first substrate and a second adhesion layer on the second substrate. The method also includes forming a first bonding layer on the first adhesion layer and a second bonding layer on the second adhesion layer. The method further includes bonding the first and second substrates by bonding the first and second bonding layers together.

An electrically non-conducting film (109) comprising an oligomer comprising an arylene or heteroarylene repeating unit is disposed between a chip (105), e.g. a flip-chip, and a functional layer (101), e.g. a printed circuit board, electrically connected to the chip by electrically conducting interconnects (107). The oligomer may be crosslinked.

Representative techniques provide process steps for forming a microelectronic assembly, including preparing microelectronic components such as dies, wafers, substrates, and the like, for bonding. One or more surfaces of the microelectronic components are formed and prepared as bonding surfaces. The microelectronic components are stacked and bonded without adhesive at the prepared bonding surfaces.

A method for manufacturing sinter bonding film, includes: preparing a resin formulation; preparing a metal filler mixture; mixing the resin formulation and the metal filler mixture, thereby preparing a paste for film manufacturing; and manufacturing a sinter bonding film by using the paste for film manufacturing. The metal filler mixture includes a metal powder and a reducing agent, copper metal (Cu) corresponds to respective particles in the metal powder, and the surface of the respective particles in the metal powder undergoes acid treatment or non-treatment.

A semiconductor device assembly is provided. The assembly includes a package substrate which has a tunneled interconnect structure. The tunneled interconnect structure has a solder-wettable surface, an interior cavity, and at least one microvia extending from the surface to the cavity. The assembly further includes a semiconductor device disposed over the substrate and a solder joint coupling the device and the substrate. The joint comprises the solder between the semiconductor device and the interconnect structure, which includes the solder on the surface, the solder in the microvia, and the solder within the interior cavity.

A method for treating a semiconductor structure includes: forming the semiconductor structure which includes a carrier substrate, a device substrate, a semiconductor device formed on the device substrate, and a bonding layer formed to bond the semiconductor device with the carrier substrate, the device substrate having an upper surface which is faced upwardly, and which is opposite to the semiconductor device; and directing a chemical fluid to impinge the upper surface of the device substrate so as to remove an edge portion of the device substrate.

A method of forming an interconnection includes: providing an electronic component having a first main face and a first metallic layer disposed on the first main face; providing an electric component having a second main face and a second metallic layer disposed on the second main face, at least one of the first or second metallic layers including an oxide layer provided on a main face thereof; disposing a reducing agent on one or both of the electronic component and the electric component such that the reducing agent is enabled to remove the oxide layer; and connecting the electronic component to the electric component by directly connecting the first metallic layer of the electronic component with the second metallic layer of the electric component by applying pressure and heat.

A semiconductor device includes a semiconductor element having a surface on which a first electrode and a second electrode are disposed, a conductor plate having a surface facing the surface of the semiconductor element and electrically connected to the first electrode, an insulating layer disposed on the surface of the conductor plate and covers a part of the surface of the conductor plate, and a conductor circuit pattern disposed on the insulating layer. The conductor circuit pattern has at least one conductor line electrically connected to the semiconductor element. The at least one conductor line includes a conductor line electrically connected to the second electrode.

Provided is a non-electroconductive flux capable of enhancing productivity and impact resistance of a connected structure to be obtained and suppressing occurrence of solder flash. The non-electroconductive flux according to the present invention contains an epoxy compound, an acid anhydride curing agent, and an organophosphorus compound.

A semiconductor device includes a dielectric layer disposed over a substrate and having a top surface; a top metal layer disposed within a portion of the dielectric layer and extending to the top surface of the dielectric layer; a first passivation layer disposed over the top surface of the dielectric layer; a redistribution layer (RDL) disposed over the first passivation layer, the RDL including an un-etched portion having a first thickness; and a second passivation layer disposed over the RDL, the second passivation layer having a second thickness over the un-etched portion of the RDL that is 40% or more of the first thickness.