A semiconductor device includes a semiconductor element circuit, a conductive support and a sealing resin. The conductive support includes a die pad, first terminals spaced in a first direction, second terminals spaced in the first direction and opposite to the first terminals in a second direction perpendicular to the first direction, and a support terminal connected to the die pad. The sealing resin encapsulates portions of the first and second terminals, a portion of the support terminal, the semiconductor element circuit and the die pad. The sealing resin has two first side surfaces spaced apart in the second direction and two second side surfaces spaced apart in the first direction. The first terminals and second terminals are exposed from the first side surfaces, while none of the elements of the conductive support is exposed from the second side surfaces.

A semiconductor package comprises a leadframe, a component module, and a semiconductor die. The leadframe has a plurality of insertion terminals, a split die pad, and one or more leads. The component module has one or more passive components mounted on a substrate. The semiconductor die has an integrated circuit. The component module is mounted on a split die pad at a first surface of the leadframe and forms an electrical connection with the insertion terminals. Further, the semiconductor die is mounted on the split die pad at a second surface of the leadframe which is opposite to the first surface.

Embodiments of the present disclosure are directed to flat no-lead packages with wettable sidewalls or flanks. In particular, wettable conductive layers are formed on the package over lateral portions of the leads and on portions of the package body, which may be encapsulation material. The wettable conductive layers may also be formed on bottom surfaces of the package body and the leads. The wettable conductive layers provide a wettable flank for solder to wick up when the package is mounted to a substrate, such as a PCB, using SMT. In particular, solder that is used to join the PCB and the package wicks up the side of the wettable conductive layers along a side surface of the package. In that regard, the solder is exposed and coupled to the side surface of the package at the wettable conductive layers, thereby allowing for a visual inspection of the solder joints. The wettable conductive layers are formed on the package after the package body has been formed. In one embodiment, the wettable conductive layers are printed on the package body and the leads by Aerosol Jet® technology.

A process for manufacturing surface-mount semiconductor devices, in particular of the Quad-Flat No-Leads Multi-Row type, comprising providing a metal leadframe, in particular a copper leadframe, which includes a plurality of pads, each of which is designed to receive the body of the device, the pads being separated from adjacent pads by one or more rows of wire-bonding contacting areas, outermost rows from among the one or more rows of wire-bonding contacting areas identifying, together with outermost rows corresponding to the adjacent pads, separation regions.

Various aspects are directed to apparatuses, systems and related methods involving the mitigation of issues relating to thermal expansion and contraction of lead fingers of an integrated circuit package. Consistent with one or more embodiments, lead fingers on a leadframe substrate each have a locking structure that secures the lead finger in place relative to the substrate. The lead fingers provide a location to attach a bond wire to an integrated circuit, and connect the bond wire to terminals at a perimeter of the leadframe. The locking structure and arrangement of the lead fingers mitigate issues such as cracking or breaking of a solder connection of the bond wire to the leadframe, which can occur due to thermal expansion and contraction.

A leadframe includes a first die attach pad (“DAP”) having a first longitudinally extending edge surface and a second DAP having a first longitudinally extending edge surface. The second DAP is positioned with the first longitudinally extending edge surface thereof in adjacent, laterally and vertically spaced relationship with the first longitudinally extending edge surface of the first DAP.

A semiconductor device includes a silicon die having a first side and a second side, an adhesive layer attached to the first side of the silicon die, and a lead frame. The lead frame comprises a die attach pad having a mounting surface. The mounting surface has a smaller area than an area of the adhesive layer. The silicon die is mounted on the lead frame at the mounting surface so that edges of the silicon die and the adhesive layer overhang the die attach pad without touching the die attach pad. The semiconductor device further includes one or more leads that are spaced apart from the edges of the silicon die and the adhesive layer.

A semiconductor package includes at least one die attach pad of a leadframe, at least one semiconductor die mounted on the at least one die attach pad; and a plurality of lead terminals disposed around the at least one die attach pad and electrically connected to respective input/output (I/O) pads on the at least one semiconductor die through a plurality of bond wires. The plurality of lead terminals comprises first lead terminals, second lead terminals, and third lead terminals, which are arranged in triple row configuration along at least one side of the semiconductor package. Each of the first lead terminals, second lead terminals, and third lead terminals has an exposed base metal on a cut end thereof.

A lead frame is made of conductive material, and includes an interconnecting web portion and a plurality of unit lead frames. Each unit lead frame includes a die pad and a plurality of leads. The die pad has a die-attach section disposed below an upper surface of the interconnecting web portion, and a plurality of extension sections bent at an angle from a periphery of the die-attach section and projecting to the interconnecting web portion. The die pad is formed with a plurality of grooves formed at an underside of junctions of the die-attach section and the extension sections. The leads extend from the interconnecting web portion toward and are spaced apart from the die pad.

In examples, an electronic device comprises a printed circuit board (PCB), an orifice extending through the PCB, and a semiconductor die suspended above the orifice by aluminum bond wires. The semiconductor die is vertically aligned with the orifice and the bond wires coupled to the PCB.