A method is provided. The method includes one or more of extracting a die from an original packaged integrated circuit, modifying the extracted die, reconditioning the modified extracted die, placing the reconditioned die into a cavity of a hermetic package base, bonding a plurality of bond wires between reconditioned die pads of the reconditioned die to leads of the hermetic package base or downbonds to create an assembled hermetic package base, and sealing a hermetic package lid to the assembled hermetic package base to create a new packaged integrated circuit. Modifying the extracted die includes removing the one or more ball bonds on the one or more die pads. Reconditioning the modified extracted die includes adding a sequence of metallic layers to bare die pads of the modified extracted die. The extracted die is a fully functional semiconductor die with one or more ball bonds on one or more die pads of the extracted die.

PROBLEM: To provide a multi-layer preform sheet capable of forming a highly reliable and high-quality electric interconnect, an electro-conductive bonding portion and so forth that are less likely to produce the Kirkendall void.

SOLUTION: A multi-layer preform sheet having at least a first layer and a second layer, the first layer being composed of a solder material that contains an intermetallic compound, and the second layer containing a first metal having a melting point of 300° C. or above, and a second metal capable of forming an intermetallic compound with the first metal.

An electrodeposition composition comprising: (a) a source of copper ions; (b) an acid; (c) a suppressor; and (d) a leveler, wherein the leveler comprises a quaternized dipyridyl compound prepared by reacting a dipyridyl compound with a difunctional alkylating agent or a quaternized poly(epihalohydrin). The electrodeposition composition can be used in a process for forming a copper feature over a semiconductor substrate in wafer level packaging to electrodeposit a copper bump or pillar on an underbump structure of a semiconductor assembly.

A semiconductor device including a semiconductor substrate including an electrode; a wire connected to the electrode; a first insulating film including a first opening that partially exposes the wire; a base portion that is connected to a portion of the wire exposed via the first opening, and that includes a conductor including a recess corresponding to the first opening; and a solder film on a surface of the base portion. Solder included in the solder film is fused by a first heat treatment, and the recess is filled with the fused solder.

A composite integrated circuit (IC) structure includes at least a first IC die in a stack with a second IC die. Each die has a device layer and metallization layers interconnected to transistors of the device layer and terminating at features. First features of the first IC die are primarily of a first composition with a first microstructure. Second features of the second IC die are primarily of a second composition or a second microstructure. A first one of the second features is in direct contact with one of the first features. The second composition has a thermal conductivity at least an order of magnitude lower than that of the first composition and first microstructure. The first composition may have a thermal conductivity at least 40 times that of the second composition or second microstructure.

Packaging devices and methods of manufacture thereof for semiconductor devices are disclosed. In some embodiments, a method of manufacturing a packaging device includes forming an interconnect wiring over a substrate, and forming conductive balls over portions of the interconnect wiring. A molding material is deposited over the conductive balls and the substrate, and a portion of the molding material is removed from over scribe line regions of the substrate.

A solder material is provided. The solder material may include a first amount of particles having particle sizes forming a first size distribution, a second amount of particles having particle sizes forming a second size distribution, the particle sizes of the second size distribution being larger than the particle sizes of the first size distribution, and a solder base material in which the first amount of particles and the second amount of particles is distributed. The first amount of particles and the second amount of particles consist of or essentially consist of a metal of a first group of metals. The first group of metals includes copper, silver, gold, palladium, platinum, iron, cobalt, and aluminum. The solder base material includes a metal of a second group of metals. The second group of metals includes tin, indium, zinc, gallium, germanium, antimony, and bismuth.

A bonding device measures a position deviation amount of the chip with respect to the substrate in a state where the chip and the substrate are in contact, and corrects and moves the chip relatively to the substrate in such a way as to reduce the position deviation amount, based on the measured position deviation amount. Then, the bonding device fixes the chip to the substrate by irradiating a resin portion of the chip with an ultraviolet ray and curing the resin portion when the position deviation amount of the chip with respect to the substrate is equal to or less than a position deviation amount threshold value.

A device includes an array of light sources (e.g., micro-LEDs, micro-RCLEDs, micro-laser: micro-SLEDs, or micro-VCSELs), a dielectric layer on the array of light sources, and a set of metal bonding pads (e.g., copper bonding pads) in the dielectric layer. Each metal bonding pad of the set of metal bonding pads is electrically connected to a respective light source of the array of light sources. Each metal bonding pad of the set of metal bonding pads includes a first portion at a bonding surface and characterized by a first lateral cross-sectional area, and a second portion away from the bonding surface and characterized by a second lateral cross-sectional area larger than two times of the first lateral cross-sectional area. The device can be bonded to a backplane that includes a drive circuit through a low annealing temperature hybrid bonding.

A semiconductor device including a terminal that is formed using copper, that is electrically connected to a circuit element, and that includes a formation face formed with a silver-tin solder bump such that a nickel layer is interposed between the terminal and the solder bump, wherein the nickel layer is formed on a region corresponding to part of the formation face.