An encapsulation of laser direct structuring (LDS) material is molded onto first and second semiconductor dice. A die-to-die coupling formation between the first and second semiconductor dice includes die vias extending through the LDS material to reach the first and second semiconductor dice and a die-to-die line extending at a surface of the encapsulation between the die vias. After laser activating and structuring selected locations of the surface of the encapsulation for the die vias and die-to-die line, the locations are placed into contact with an electrode that provides an electrically conductive path. Metal material is electrolytically grown onto the locations of the encapsulation by exposure to an electrolyte carrying metal cations. The metal cations are reduced to metal material via a current flowing through the electrically conductive path provided via the electrode. The electrode is then disengaged from contact with the locations having metal material electrolytically grown thereon.

An encapsulation of laser direct structuring (LDS) material is molded onto a substrate having first and second semiconductor dice arranged thereon. Laser beam energy is applied to a surface of the encapsulation of LDS material to structure therein die vias extending through the LDS material to the first and second semiconductor dice and a die-to-die line extending at surface of the LDS material between die vias. Laser-induced forward transfer (LIFT) processing is applied to transfer electrically conductive material to the die vias and the die-to-die line extending between die vias. A layer of electrically conductive material electroless grown onto the die vias and the die-to-die line facilitates improved adhesion of the electrically conductive material transferred via LIFT processing.

A lead frame includes: a frame body; a plurality of leads individually projecting from the frame body; and a recess formed across one surfaces of the leads adjacent to each other with the frame body therebetween, the recess including a first recess, and a second recess partially overlapping the first recess in a bottom surface thereof and having a smaller depth than the first recess.

A semiconductor device of embodiments includes: a die pad including a first region and a second region surrounding the first region and thinner than the first region; a semiconductor chip including an upper electrode, a lower electrode, and a silicon carbide layer between the upper electrode and the lower electrode and provided on an inner side rather than the second region on a surface of the die pad; and a connection layer for connecting the lower electrode to the surface.

A semiconductor device of embodiments includes: a die pad; a semiconductor chip fixed on the die pad; and a sealing resin covering the semiconductor chip and at least a part of the die pad. The sealing resin has a first protruding portion provided on one side surface and a second protruding portion provided on another side surface. The cross-sectional area of the first protruding portion is equal to or more than 10% of the maximum cross-sectional area of the sealing resin. The cross-sectional area of the second protruding portion is equal to or more than 10%; of the maximum cross-sectional area. The maximum cross-sectional area is equal to or more than 6 mm.sup.2.

An electronic device includes a bond wire with a first end bonded by a ball bond to a planar side of a first conductive plate, and a second end bonded by a stitch bond to a conductive stud bump at an angle greater than or equal to 60 degrees. A wirebonding method includes bonding the first end of the conductive bond wire to the first conductive plate includes forming a ball bond to join the first end of the conductive bond wire to a planar side of the first conductive plate by a ball bond, and bonding the second end of the conductive bond wire to the conductive stud bump includes forming a stitch bond to join the second end of the conductive bond wire to the conductive stud bump.

This semiconductor device includes: a bed including a first upper surface having a plurality of first grooves and a first lower surface; a first bonding material provided on the first upper surface and in contact with the first grooves; a semiconductor chip including a second upper surface having a first electrode and a second electrode, and a second lower surface, the semiconductor chip being provided on the first bonding material and having the second lower surface connected to the first bonding material; a second bonding material provided on the first electrode and connected to the first electrode; and a first connector having a first end having a plurality of second grooves and connected to the second bonding material, and a second end.

A semiconductor device includes: a die pad having a top surface; a semiconductor chip provided on the top surface; a first solder provided between the top surface and the semiconductor chip, the first solder bonding the top surface and the semiconductor chip; a first metal film provided on the semiconductor chip; a first insulating film provided on the first metal film and having a first opening; a connector having a first end and a second end, the first end being provided on the first metal film in the first opening; a second metal film provided in the first opening, the second metal film having a plurality of second openings provided so as to surround a portion of the first metal film in contact with the first end, and the second metal film being provided between the first end of the connector and the portion of the first metal film; a plurality of second insulating films provided in direct contact with the first metal film in each of the second openings; and a second solder provided between the second metal film and the first end to bond the first end and the second metal film to each other.

A leadframe has a die pad area and an outer layer of a first metal having a first oxidation potential. The leadframe is placed in contact with a solution containing a second metal having a second oxidation potential, the second oxidation potential being more negative than the first oxidation potential. Radiation energy is then applied to the die pad area of the leadframe contacted with the solution to cause a local increase in temperature of the leadframe. As a result of the temperature increase, a layer of said second metal is selectively provided at the die pad area of the leadframe by a galvanic displacement reaction. An oxidation of the outer layer of the leadframe is then performed to provide an enhancing layer which counters device package delamination.

A method for soldering a die obtained using the semiconductor technique with a leadframe, comprising the steps of providing a leadframe, which has at least one surface made at least partially of copper; providing a die, which has at least one surface coated with a metal layer; applying to the surface a solder alloy comprising at least 40 wt % of tin or at least 50% of indium or at least 50% of gallium, without lead, and heating the alloy to a temperature of at least 380° C. to form a drop of solder alloy; providing a die, which has at least one surface coated with a metal layer; and setting the metal layer in contact with the drop of solder alloy to form the soldered connection with the leadframe. Moreover, a device obtained with said method is provided.