A leadframe includes an individual region to become a semiconductor device, and an outer frame part supporting the individual region through its peripheral edge. The thickness of the outer frame part is greater than the thickness of the individual region.

A method of forming a microelectronic device structure comprises coiling a portion of a wire up and around at least one sidewall of a structure protruding from a substrate. At least one interface between an upper region of the structure and an upper region of the coiled portion of the wire is welded to form a fused region between the structure and the wire.

One or more embodiments are directed to leadframes and leadframe semiconductor packages. One embodiment is directed to copper leadframes with one or more die pads and one more leads with a roughened surface. Covering the roughened surface of the die pad of the leadframe is nanolayer of Silver (Ag). The thickness of the nanolayer preferably has a thickness that corresponds to the roughened surface of the copper leadframe. For instance, in one embodiment, the copper leadframe is roughened to have peaks and valleys that approximately average 10 nanometers and the thickness of the nanolayer is 10 nanometers. Covering a portion of the nanolayer of Ag is a microlayer of Ag, which provides a suitable bonding surface for coupling a semiconductor die to the die pad by an adhesive material.

A method for bonding a hermetic module to an electrode array including the steps of: providing the electrode array having a flexible substrate with a top surface and a bottom surface and including a plurality of pads in the top surface of the substrate; attaching the hermetic module to the bottom surface of the electrode array, the hermetic module having a plurality of bond-pads wherein each bond-pad is adjacent to the bottom surface of the electrode array and aligns with a respective pad; drill holes through each pad to the corresponding bond-pad; filling each hole with biocompatible conductive ink; forming a rivet on the biocompatible conductive ink over each pad; and overmolding the electrode array with a moisture barrier material.

A semiconductor device includes a leadframe, a semiconductor chip, and an encapsulation resin encapsulating the leadframe and the semiconductor chip. The leadframe includes a first surface and a second surface facing away from the first surface. The semiconductor chip is mounted on the first surface of the leadframe. A part of the second surface of the leadframe is depressed toward the first surface to foam a step surface. The step surface includes an uneven surface part where depressions are formed, and is covered with the encapsulation resin.

A leadframe includes an individual region to become a semiconductor device, and an outer frame part supporting the individual region through its peripheral edge. The thickness of the outer frame part is greater than the thickness of the individual region.

A semiconductor device includes a lead frame; a semiconductor chip mounted on the lead frame; and an encapsulation resin, wherein a convexo-concave portion including a plurality of concave portions is provided at a covered portion of the lead frame that is covered by the encapsulation resin, wherein the planer shape of each of the concave portions is a circle, the diameter of which is greater than or equal to 0.020 mm and less than or equal to 0.060 mm, or a polygon, the diameter of whose circumcircle is greater than or equal to 0.020 mm and less than or equal to 0.060 mm, and wherein a ratio S/S.sub.0 is greater than or equal to 1.7 where S is a surface area of the convexo-concave portion that is formed at a flat surface whose surface area is S.sub.0.

A method of forming a microelectronic device structure comprises coiling a portion of a wire up and around at least one sidewall of a structure protruding from a substrate. At least one interface between an upper region of the structure and an upper region of the coiled portion of the wire is welded to form a fused region between the structure and the wire.

A method for bonding a hermetic module to an electrode array including the steps of: providing the electrode array having a flexible substrate with a top surface and a bottom surface and including a plurality of pads in the top surface of the substrate; attaching the hermetic module to the bottom surface of the electrode array, the hermetic module having a plurality of bond-pads wherein each bond-pad is adjacent to the bottom surface of the electrode array and aligns with a respective pad; drill holes through each pad to the corresponding bond-pad; filling each hole with biocompatible conductive ink; forming a rivet on the biocompatible conductive ink over each pad; and overmolding the electrode array with a moisture barrier material.

A semiconductor device includes a semiconductor element, a lead, and a wire including a first bonding portion bonded to the semiconductor element and a second bonding portion bonded to the lead. The semiconductor element includes a first bonding surface which faces to a first side in a first direction and to which the first bonding portion is bonded. The lead includes a second bonding surface and a third bonding surface both facing to the first side in the first direction and forming an angle larger than 180 on the first side in the first direction. The semiconductor device further includes a ball bump extending onto both the second bonding surface and the third bonding surface. The second bonding portion is bonded to the lead via the ball bump.