A method for manufacturing an electronic component includes positioning a first surface of a first component facing a second surface of a second component in a first state. The first surface has a first pad having a first center. The second surface has a second pad having a second center. At least one of the first or second pads includes a metal member. The method includes melting the metal member and moving the first and second components until the melted metal member contacts both pads, moving at least one of the first or second components in a direction along the first surface, and solidifying the metal member in a second state. A first distance in a direction along the first surface between the first and second centers in the first state is longer than a second distance in the direction between the first and second centers in the second state.

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.

Described herein is a composition including copper ions, an acid, and at least one polyaminoamide including, a group of formula L1
[A-B-A-Z].sub.n[YZ].sub.m(L1)
where
B is a diacid fragment of formula L2 ##STR00001##
A, A are amine fragments independently selected from the group consisting of formula L3a ##STR00002## and formula L3b ##STR00003##
Y is a co-monomer fragment;
Z is a coupling fragment of formula L4 ##STR00004##
n is an integer of from 1 to 400; and
m is 0 or an integer of from 1 to 400.

A method for assembling a packaged integrated circuit is provided. The method includes placing a die into a cavity of a package base, securing the die to the package base with a die attach adhesive, printing a bond connection between a die pad of the die and a lead of the package base or a downbond, and sealing a package lid to the package base.

A method is provided. The method includes one or more of removing existing ball bonds from an extracted die, placing the extracted die into a recess of a hermetic substrate, the extracted die having a centered orientation in the recess, and applying a side fill compound into the recess between the extracted die and the hermetic substrate. The method also includes 3D printing, by a 3D printer, a plurality of bond connections between die pads of the extracted die and first bond pads of the hermetic substrate in order to create a 3D printed die substrate, and 3D printing a hermetic encapsulation over the die, the side fill compound, and the 3D printed bond connections in order to create a hermetic assembly. The extracted die includes a fully functional semiconductor die removed from a previous package. The hermetic substrate includes the first bond pads coupled to second bond pads.

A method is provided. The method includes removing an extracted die including an original ball bond from a previous packaged integrated circuit, bonding the extracted die to an interposer to create a remapped extracted die, 3D printing one or more first bond connections between one or more original bond pads of the extracted die and one or more first bond pads of the interposer, securing the remapped extracted die to a package base, and 3D printing one or more second bond connections between one or more second bond pads of the interposer and one or more package leads or downbonds of the package base. The one or more first and second bond connections conform to the shapes and surfaces of the extracted die, the interposer, and the package base.

An integrated circuit is provided. The integrated circuit includes a package base including package leads, an extracted die removed from a previous packaged integrated circuit, and an an interposer bonded to the extracted die and the package base. The extracted die includes original bond pads and one or more original ball bonds on the original bond pads. The interposer includes first bond pads electrically connected to the original bond pads with 3D printed first bond connections conforming to the shapes and surfaces of the extracted die and the interposer and second bond pads electrically connected to the package leads with 3D printed second bond connections conforming to shapes and surfaces of the interposer and package base.

To provide a lead-free solder the heat resistance temperature of which is high and thermal conductive property of which are not changed in a high temperature range. A semiconductor device of the present invention includes a solder material containing more than 5.0% by mass and 10.0% by mass or less of Sb and 2.0 to 4.0% by mass of Ag, and the remainder consisting of Sn and inevitable impurities, and a bonding layer including the solder material, which is formed between a semiconductor element and a substrate electrode or a lead frame.

A method of forming a semiconductor device assembly comprises forming on a first substrate, at least one bond pad comprising a first nickel material over the first substrate, a first copper material on the first nickel material, and a solder-wetting material on the first copper material. On a second substrate is formed at least one conductive pillar comprising a second nickel material, a second copper material directly contacting the second nickel material, and a solder material directly contacting the second copper material. The solder-wetting material is contacted with the solder material. The first copper material, the solder-wetting material, the second copper material, and the solder material are converted into a substantially homogeneous intermetallic compound interconnect structure. Additional methods, semiconductor device assemblies, and interconnect structures are also described.

A packaged integrated circuit for operating reliably at elevated temperatures is provided. The packaged integrated circuit includes a reconditioned die, which includes a fully functional semiconductor die that has been previously extracted from a different packaged integrated circuit. The packaged integrated circuit also includes a hermetic package comprising a base and a lid and a plurality of bond wires. The reconditioned die is placed into a cavity in the base. After the reconditioned die is placed into the cavity, the plurality of bond wires are bonded between pads of the reconditioned die and package leads of the hermetic package base or downbonds. After bonding the plurality of bond wires, the lid is sealed to the base.