A microelectronics package assembly and process of making same are disclosed. The flange has an upper surface and a first coating disposed on the upper surface of the flange. The insulator has a bottom surface for mounting onto the flange and an upper surface opposite the bottom surface. A second coating is disposed on the bottom surface of the insulator and a third coating disposed on the upper surface of the insulator. The first coating, the second coating, and the third coating each have a thickness of less than or equal to 1 micron. At least one of the first coating, the second coating, and the third coating is applied via at least one of physical vapor deposition, atomic deposition, or chemical deposition.

A pre-molded leadframe includes a laminar structure having empty spaces therein and a first thickness with a die pad having opposed first and second die pad surfaces. Insulating pre-mold material is molded onto the laminar structure. The pre-mold material penetrates the empty spaces and provides a laminar pre-molded substrate having the first thickness with the first die pad surface left exposed. The die pad has a second thickness that is less than the first thickness. One or more pillar formations are provided protruding from the second die pad surface to a height equal to a difference between the first and second thicknesses. With the laminar structure clamped between surfaces of a mold, the first die pad surface and pillar formations abut against the mold surfaces. The die pad is thus effectively clamped between the clamping surfaces countering undesired flashing of the pre-mold material over the first die pad surface.

A lead frame for an integrated electronic device includes a die pad made of a first metallic material. A top coating layer formed by a second metallic material is arranged on a top surface of the die pad. The second metallic material has an oxidation rate lower than the first metallic material. The top coating layer leaves exposed a number of corner portions of the top surface of the die pad. A subsequent heating operation, for example occurring in connection with wirebonding, causes an oxidized layer to form on the corner portions of the top surface of the die pad at a position in contact with the top coating layer.

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 packaged semiconductor device includes a routable molded lead frame structure with a surface finish layer. In one embodiment, the routable molded lead frame structure includes a first laminated layer including the surface finish layer, vias connected to the surface finish layer, and a first resin layer covering the vias leaving the top surface of the surface finish layer exposed. A second laminated layer includes second conductive patterns connected to the vias, bump pads connected to the second conductive patterns, and a second resin layer covering one side of the first resin layer, the second conductive patterns and the bump pads. A semiconductor die is electrically connected to the surface finish layer and an encapsulant covers the semiconductor die and another side of the first resin layer. The surface finish layer provides a customizable and improved bonding structure for connecting the semiconductor die to the routable molded lead frame structure.

In one example, a semiconductor device includes a substrate that comprises a substrate conductor material. An electronic component has a first component terminal that comprises a first component terminal conductor material and a second component terminal that comprises a second component terminal conductor material. An interconnect comprises an interconnect conductor material, a component end, and a substrate end. The second component terminal is attached to the substrate with a first intermetallic bond, the component end of the interconnect is attached to the first component terminal with a second intermetallic bond, and the substrate end of the interconnect is attached to the substrate with a third intermetallic bond. Other examples and related methods are also disclosed herein.

A semiconductor device according to the present embodiment comprises a semiconductor chip comprising a first face and a second face on an opposite side to the first face, and comprising a first electrode in the first face. A first metallic member comprises a first opposed face facing the first electrode and being larger in a profile than the first electrode, the first metallic member comprising a first protruded portion protruded from the first opposed face toward the first electrode and electrically connected to the first electrode. An insulating member coats the semiconductor chip and the first metallic member.

A heat dissipation structure, includes: a lead frame, including a high temperature pad and a low temperature pad, the high temperature pad and the low temperature pad being two portions in the lead frame which are separated from each other, wherein a high heat generation component is disposed on the high temperature pad; and a high thermal conduction element, including two sides which are respectively directly connected with the high temperature pad and the low temperature pad, to dissipate the heat energy from the high heat generation component to the low temperature pad.

A grid array type lead frame package includes a lead frame having a plurality of bonding fingers projecting inwardly from a periphery of the lead frame; a semiconductor device mounted on inner ends of the bonding fingers, wherein the semiconductor device comprises an active surface and a plurality of input/output (I/O) pads disposed on the active surface; a plurality of bonding wires extending between the I/O pads and the bonding fingers for transmitting signals from or to the semiconductor device; a molding compound at least partially encapsulating the semiconductor device, the bonding wires, and the bonding fingers; and a solder mask layer attached to a bottom surface of the molding compound and a bottom surface of each of the bonding fingers.

A lead member includes a plurality of lead terminals, and the lead terminals extend from the inside to the outside of a mold resin. Each of the lead terminals has a base portion and a tip end portion on the outside of the mold resin. The base portion is disposed on a region side having a semiconductor element and extends in a direction protruding from the mold resin. The tip end portion extends in a direction different from the base portion and is disposed on the opposite side to a region having the semiconductor element as viewed from the base portion. The length by which the base portion extends differs between a pair of lead terminals adjacent to each other, among the lead terminals. At least a surface of the base portion of each of the lead terminals is covered with a coating resin.