Systems and methods are provided for the embedding of thin chips. A well region is generated in a substrate that includes a conductive material disposed on a flexible polymer. The standoff well region can be generated by pattern the conductive material, where the thin chip is embedded in the standoff well region. A cavity can be generated in the polymer layer to form a polymer well region, where the thin chip is embedded in the polymer well region.

The present invention can give a joining structure using metal nanoparticles to join the same types or different types of metal where when one surface metal is Al based, the parts are joined through a joining layer containing Ni nanoparticles, whereby a good joining strength is obtained. Further, by using two joining layers (6, 8) including metal nanoparticles to sandwich metal foil (7) so as to form a joining layer and joining the same type or different types of surface metals (3-4) through this joining layer, it is possible to ease the thermal stress due to the difference in amounts of thermal expansion of joined members which have two surface metals.

The present invention can give a joining structure using metal nanoparticles to join the same types or different types of metal where when one surface metal is Al based, the parts are joined through a joining layer containing Ni nanoparticles, whereby a good joining strength is obtained. Further, by using two joining layers (6, 8) including metal nanoparticles to sandwich metal foil (7) so as to form a joining layer and joining the same type or different types of surface metals (3-4) through this joining layer, it is possible to ease the thermal stress due to the difference in amounts of thermal expansion of joined members which have two surface metals.

The present invention relates to a conductive paste for bonding that comprises a metal powder and a solvent, wherein the metal powder comprises a first metal powder having a particle diameter (D50) of 10 to 150 nm and a second metal powder having a particle diameter (D50) of 151 to 500 nm. The paste is useful for manufacturing an electronic device comprising a substrate with an electrically conductive layer and an electrical or electronic component, which are reliably bonded together using the paste.

The present invention relates to a conductive paste for bonding that comprises a metal powder and a solvent, wherein the metal powder comprises a first metal powder having a particle diameter (D50) of 10 to 150 nm and a second metal powder having a particle diameter (D50) of 151 to 500 nm. The paste is useful for manufacturing an electronic device comprising a substrate with an electrically conductive layer and an electrical or electronic component, which are reliably bonded together using the paste.

Semiconductor packages and methods for forming a semiconductor package are disclosed. The method includes providing a package substrate having first and second major surfaces. The package substrate includes a base substrate having a mold material and a plurality of interconnect structures including via contacts extending through the first to the second major surface of the package substrate. A die having conductive contacts on its first or second surface is provided. The conductive contacts of the die are electrically coupled to the interconnect structures. A cap is formed over the package substrate to encapsulate the die.

An electronic device includes a semiconductor die having a lower surface, a sintered metallic layer underlying the lower surface of the semiconductor die, a conductive layer underlying the sintered metallic layer, and a conductive substrate underlying the conductive layer.

An electronic device includes a semiconductor die having a lower surface, a sintered metallic layer underlying the lower surface of the semiconductor die, a conductive layer underlying the sintered metallic layer, and a conductive substrate underlying the conductive layer.

Systems and methods are provided for the embedding of thin chips. A well region is generated in a substrate that includes a conductive material disposed on a flexible polymer. The standoff well region can be generated by pattern the conductive material, where the thin chip is embedded in the standoff well region. A cavity can be generated in the polymer layer to form a polymer well region, where the thin chip is embedded in the polymer well region.

An electronic device includes a semiconductor die having a lower surface, a sintered metallic layer underlying the lower surface of the semiconductor die, a thermally conductive flow layer underlying the sintered metallic layer, and a thermally conductive substrate underlying the thermally conductive flow layer.