A composition exhibits excellent heat resistance and mounting reliability when bonding a semiconductor power element to a metal lead frame, which is also free of lead and thereby places little burden on the environment. An electrically conductive composition contains at least a sulfide compound represented by RSR (wherein R is an organic group containing at least carbon; R is an organic group that is the same as or different from R; and R and R may be bonded to each other to form a so-called cyclic sulfide) and metal particles containing at least Cu, Sn or Ni as its essential component. Further, a conductive paste and a conductive bonding film each are produced using the electrically conductive composition. A dicing die bonding film is obtained by bonding the conductive bonding film with an adhesive tape.

Provided is a metal paste for joints, containing: metal particles; and linear or branched monovalent aliphatic alcohol having 1 to 20 carbon atoms, in which the metal particles include sub-micro copper particles having a volume average particle diameter of 0.12 m to 0.8 M.

Provided are a sintered material excellent in both thermal stress and bonding strength; a connection structure comprising the sintered material; a composition for bonding with which the sintered material can be produced; and a method for producing the sintered material. The sintered material comprises a base portion, one or more buffer portions, and one or more filling portions. The buffer portions and the filling portions are dispersed in the base portion. The base portion is a metal sintered body, each buffer portion is formed from at least one of a pore and a material that is not the same as that of the sintered body, and each filling portion is formed from at least one of particles and fibers. The sintered material satisfies A>B, where A is the kurtosis of volume distribution of the base portions in a three-dimensional image of the sintered material, and B is the kurtosis of volume distribution of the base portions in a three-dimensional image of the sintered material from which the filling portions are removed.

Provided are a sintered material excellent in both thermal stress and bonding strength; a connection structure comprising the sintered material; a composition for bonding with which the sintered material can be produced; and a method for producing the sintered material. The sintered material comprises a base portion, one or more buffer portions, and one or more filling portions. The buffer portions and the filling portions are dispersed in the base portion. The base portion is a metal sintered body, each buffer portion is formed from at least one of a pore and a material that is not the same as that of the sintered body, and each filling portion is formed from at least one of particles and fibers. The sintered material satisfies A>B, where A is the kurtosis of volume distribution of the base portions in a three-dimensional image of the sintered material, and B is the kurtosis of volume distribution of the base portions in a three-dimensional image of the sintered material from which the filling portions are removed.

A metal sintered bonding body bonds a substrate and a die. In the metal sintered bonding body, at least a center part and corner part of a rectangular region where the metal sintered bonding body faces the die have a low-porosity region whose porosity is lower than an average porosity of the rectangular region. The low-porosity region is located within a strip-shaped region whose central lines are diagonal lines of the rectangular region.

A sintered material excellent in thermal stress and bonding strength; a connection structure containing the sintered material; a composition for bonding with which the sintered material can be produced; and a method for producing the sintered material. The sintered material has a base portion, buffer portions, and filling portions. The buffer portions and filling portions are dispersed in the base portion. The base portion is a metal sintered body, each buffer portion is formed from a pore and/or material that is not the same as the sintered body, and each filling portion is formed from particles and/or fibers. The sintered material satisfies A>B. A is the kurtosis of volume distribution of the base portions in a three-dimensional image of the sintered material. B is the kurtosis of volume distribution of the base portions in a three-dimensional image of the sintered material from which the filling portions are removed.

A sintered material excellent in thermal stress and bonding strength; a connection structure containing the sintered material; a composition for bonding with which the sintered material can be produced; and a method for producing the sintered material. The sintered material has a base portion, buffer portions, and filling portions. The buffer portions and filling portions are dispersed in the base portion. The base portion is a metal sintered body, each buffer portion is formed from a pore and/or material that is not the same as the sintered body, and each filling portion is formed from particles and/or fibers. The sintered material satisfies A>B. A is the kurtosis of volume distribution of the base portions in a three-dimensional image of the sintered material. B is the kurtosis of volume distribution of the base portions in a three-dimensional image of the sintered material from which the filling portions are removed.

A hybrid bonding layer includes a metal inverse opal (MIO) layer with a plurality of hollow spheres and a predefined porosity, and a ball grid array (BGA) disposed within the MIO layer. The MIO layer and the BGA may be disposed between a pair of bonding layers. The MIO layer and the BGA each have a melting point above a TLP sintering temperature and the pair of bonding layers each have a melting point below the TLP sintering temperature such that the hybrid bonding layer can be transient liquid phase bonded between a substrate and a semiconductor device. The pair of bonding layers may include a first pair of bonding layers with a melting point above the TLP sintering temperature and a second pair of bonding layers with a melting point below the TLP sintering temperature.

A hybrid bonding layer includes a metal inverse opal (MIO) layer with a plurality of hollow spheres and a predefined porosity, and a ball grid array (BGA) disposed within the MIO layer. The MIO layer and the BGA may be disposed between a pair of bonding layers. The MIO layer and the BGA each have a melting point above a TLP sintering temperature and the pair of bonding layers each have a melting point below the TLP sintering temperature such that the hybrid bonding layer can be transient liquid phase bonded between a substrate and a semiconductor device. The pair of bonding layers may include a first pair of bonding layers with a melting point above the TLP sintering temperature and a second pair of bonding layers with a melting point below the TLP sintering temperature.

A hybrid bonding layer includes a metal inverse opal (MIO) layer with a plurality of hollow spheres and a predefined porosity, and a ball grid array (BGA) disposed within the MIO layer. The MIO layer and the BGA may be disposed between a pair of bonding layers. The MIO layer and the BGA each have a melting point above a TLP sintering temperature and the pair of bonding layers each have a melting point below the TLP sintering temperature such that the hybrid bonding layer can be transient liquid phase bonded between a substrate and a semiconductor device. The pair of bonding layers may include a first pair of bonding layers with a melting point above the TLP sintering temperature and a second pair of bonding layers with a melting point below the TLP sintering temperature.