According to an embodiment, a temperature of an inside of a furnace is set to fall within a range of a reduction temperature or more of a carboxylic acid and less than a melting temperature of a solder bump, and the inside is concurrently set to have a first carboxylic acid gas concentration. Thereafter, the temperature of the inside is raised up to the melting temperature, and the inside is concurrently set to have a second carboxylic acid gas concentration. The second carboxylic acid gas concentration is lower than the first carboxylic acid gas concentration, and is a concentration containing a minimum amount of carboxylic acid gas defined to achieve reduction on an oxide film of the solder bump. The inside has the second carboxylic acid gas concentration at least at a time when the temperature of the inside reaches the melting temperature.

A bonding device for bonding an electronic element includes an engaging component. The engaging component has a first surface and a second surface opposite to the first surface. The engaging component includes a plurality of recesses at the second surface. The plurality of recesses are configured to cover a plurality of projections of an electronic element. The engaging component is coupled to a heating component.

A nanowire bonding interconnect for fine-pitch microelectronics is provided. Vertical nanowires created on conductive pads provide a debris-tolerant bonding layer for making direct metal bonds between opposing pads or vias. Nanowires may be grown from a nanoporous medium with a height between 200-1000 nanometers and a height-to-diameter aspect ratio that enables the nanowires to partially collapse against the opposing conductive pads, creating contact pressure for nanowires to direct-bond to opposing pads. Nanowires may have diameters less than 200 nanometers and spacing less than 1 μm from each other to enable contact or direct-bonding between pads and vias with diameters under 5 μm at very fine pitch. The nanowire bonding interconnects may be used with or without tinning, solders, or adhesives. A nanowire forming technique creates a nanoporous layer on conductive pads, creates nanowires within pores of the nanoporous layer, and removes at least part of the nanoporous layer to reveal a layer of nanowires less than 1 μm in height for direct bonding.

According to an aspect of the inventive concept, there is provided a die-to-wafer bonding structure including a die having a first test pad, a first bonding pad formed on the first test pad, and a first insulating layer, the first bonding pad penetrates the first insulating layer. The structure may further include a wafer having a second test pad, a second bonding pad formed on the second test pad, and a second insulating layer, the second bonding pad penetrates the second insulating layer. The structure may further include a polymer layer surrounding all side surfaces of the first bonding pad and all side surfaces of the second bonding pad, the polymer layer being arranged between the die and the wafer. Additionally, the wafer and the die may be bonded together.

Electronic assemblies and methods of assembly are described. In an embodiment, an electronic assembly includes a stiffener structure shear bonded to an opposite side of a module substrate from a ball grid array (BGA) package. The stiffener structure may be shear bonded at elevated temperature after bonding of the BGA package to lock in a flat or near-flat surface contour of the module substrate.

Provided is a semiconductor chip mounting tape. The semiconductor chip mounting tape comprises a tape base film including first and second surfaces opposite to each other; and an adhesive film including a third surface facing the first surface of the tape base film, and a fourth surface opposite to the third surface, wherein the adhesive film includes a plurality of voids therein, and the fourth surface of the adhesive film may be adhered to a semiconductor chip.

A chip packaging structure and a method for preparing the same, and a method for packaging a semiconductor structure are provided, which relate to the technical field of semiconductors, and solve the technical problem of low yield of a chip. The chip packaging structure includes: a chip, an intermediate insulating layer arranged on the chip and a non-conductive adhesive layer arranged on the intermediate insulating layer, where a plurality of conductive pillar bumps are arranged on the chip, and each conductive pillar bump penetrates through the intermediate insulating layer; the intermediate insulating layer is provided with at least one group of holding holes, and the non-conductive adhesive layer fills the holding holes, so that grooves respectively matched with the holding holes are formed in a surface, far away from the intermediate insulating layer, of the non-conductive adhesive layer.

An integrated circuit die may be fabricating to have a plurality of contacts. A metal post may be formed on each of the plurality of contacts. A plurality of bumps may be formed on a plurality of contact regions of a leadframe or on the posts, in which the plurality of bumps are formed with a material that includes metal nanoparticles. The IC die may be attached to the leadframe by aligning the metal posts to the leadframe and sintering the metal nanoparticles in the plurality of bumps to form a sintered metal bond between each metal post and corresponding contact region of the leadframe.

Provided are a device packing facility and method using DEHT and a device processing apparatus utilizing the DEHT. The device packaging facility includes a mounting unit providing bis(2-ethylhexyl) terephthalate (DEHT) between first and second devices to attach the first and second devices to each other, a processing unit thermally processing the first and second devices that are attached to each other to remove the DEHT and fix the first and second devices to each other, and a transfer unit transferring the first and second devices that are attached to each other from the mounting unit to the processing unit.

Embodiments of a thermal compression bonding (TCB) process cooling manifold, a TCB process system, and a method for TCB using the cooling manifold are disclosed. In some embodiments, the cooling manifold comprises a pre-mixing chamber that is separated from a mixing chamber by a baffle. The baffle may comprise at least one concentric pattern formed through the baffle such that the primary cooling fluid in the pre-mixing chamber is substantially evenly distributed to the mixing chamber. The pre-mixing chamber may be coupled to a source of primary cooling fluid. The mixing chamber may have an input configured to accept the primary cooling fluid and an output to output the primary cooling fluid.