A bonding film for bonding a semiconductor element and a substrate. The bonding film has an electroconductive bonding layer formed by molding an electroconductive paste including metal fine particles (P) into a film form, and a tack layer having tackiness and laminated on the electroconductive bonding layer. The tack layer includes 0.1% to 1.0% by mass of metal fine particles (M) with respect to the metal fine particles (P) in the electroconductive bonding layer, and the metal fine particles (M) have a melting point of 250° C. or lower.

A bonding film for bonding a semiconductor element and a substrate. The bonding film has an electroconductive bonding layer formed by molding an electroconductive paste including metal fine particles (P) into a film form, and a tack layer having tackiness and laminated on the electroconductive bonding layer. The tack layer includes 0.1% to 1.0% by mass of metal fine particles (M) with respect to the metal fine particles (P) in the electroconductive bonding layer, and the metal fine particles (M) have a melting point of 250° C. or lower.

Invention compositions are a replacement for high melting temperature solder pastes and preforms in high operating temperature and step-soldering applications. In the use of the invention, a mixture of metallic powders reacts below 350 degrees C. to form a dense metallic joint that does not remelt at the original process temperature.

Invention compositions are a replacement for high melting temperature solder pastes and preforms in high operating temperature and step-soldering applications. In the use of the invention, a mixture of metallic powders reacts below 350 degrees C. to form a dense metallic joint that does not remelt at the original process temperature.

A semiconductor die attach composition with greater than 60% metal volume after thermal reaction having: (a) 80-99 wt % of a mixture of metal particles comprising 30-70 wt % of a lead-free low melting point (LMP) particle composition comprising at least one LMP metal Y that melts below a temperature T1, and 25-70 wt % of a high melting point (HMP) particle composition comprising at least one metallic element M that is reactive with the at least one LMP metal Y at a process temperature T1, wherein the ratio of wt % of M to wt % of Y is at least 1.0; (b) 0-30 wt % of a metal powder additive A; and (c) a fluxing vehicle having a volatile portion, and not more than 50 wt % of a non-volatile portion.

The inventive concept relates to a filling composition for a semiconductor package. The filling composition for a semiconductor package may include a resin, a curing agent, and an insulating filler. The insulating filler may include a first filler body part, a second filler body part, a polymer chain coupled to the first filler body part and the second filler body part, and supramolecules coupled to the polymer chain.

The inventive concept relates to a filling composition for a semiconductor package. The filling composition for a semiconductor package may include a resin, a curing agent, and an insulating filler. The insulating filler may include a first filler body part, a second filler body part, a polymer chain coupled to the first filler body part and the second filler body part, and supramolecules coupled to the polymer chain.

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.