A semiconductor device including a clip, and the clip includes a clip slot, and a slug and the slug includes a groove. The clip and the slug are attached by the ultrasonic welding. The groove and the clip slot are at least partially overlapping to form a gas pathway.

An integrated circuit package includes a semiconductor die having a first surface and a second surface. The first surface is attached to a top surface of a die attach pad, and the second surface has a sensing area thereon. A mold compound covers or encapsulates at least a portion of the die attach pad and the semiconductor die. A channel is formed in a top portion of the mold compound. The channel extends from a first side of the mold compound to a second side of the mold compound. A cavity is formed between the channel and the sensing area so that the sensing area is exposed to the environment.

Lead frames for semiconductor device packages may include lead fingers proximate to a die-attach pad. A convex corner of the lead frame proximate to a geometric center of the lead frame may be rounded to include a radius of curvature of at least two times a greatest thickness of the die-attach pad. The thickness of the die-attach pad may be measured in a direction perpendicular to a major surface of the die-attach pad. A shortest distance between the die-attach pad and each one of the lead fingers having a surface area larger than an average surface area of the lead fingers may be at least two times the greatest thickness of the die-attach pad.

A semiconductor device and method of forming the same are provided. The semiconductor device includes at least one substrate and an interconnection structure. The at least one substrate has a cavity partially defined by an inner sidewall of the at least one substrate and a channel disposed at a bottom of the at least one substrate. The channel laterally penetrates through the at least one substrate. The interconnections structure is disposed over the substrate, and the interconnection structure has a through hole penetrating through the interconnection structure. The through hole, the cavity and the channel are in spatial communication with each other.

An electronic device includes a semiconductor die, a package structure enclosing the semiconductor die, and a conductive lead having first and second surfaces. The first surface has a bilayer exposed along a bottom side of the package structure, and the second surface is exposed along another side of the package structure. The bilayer includes first and second plated layers, the first plated layer on and contacting the first surface of the conductive lead and the second plated layer on and contacting the first plated layer and exposed along the bottom side of the package structure, where the first plated layer includes cobalt, and the second plated layer includes tin.

In examples, a semiconductor device comprises a semiconductor die, an opaque mold compound housing covering the semiconductor die, a conductive terminal extending from the mold compound housing, and an insulative coat covering the mold compound housing and at least a portion of the conductive terminal.

Techniques and devices are disclosed for forming wettable flanks on no-leads semiconductor packages. A lead frame assembly may include a plurality of leads, each lead including a die surface and a plating surface, and an integrated circuit die arranged on the die surface. The plating surface for each of the leads may be plated with an electrical plating. A connecting film may be applied and lead frame assembly may be singulated into individual semiconductor packages by a series of cuts through each of the plurality of leads and the electrical plating of each of the plurality of leads to a depth up to or through a portion of the connecting film to create a channel exposing lead sidewalls of each of the plurality of leads. The lead sidewalls of each of the plurality of leads may be plated with a second electrical plating and the connecting film may be removed.

In a described example, an apparatus includes: a package substrate having a die pad configured for mounting a semiconductor die, a first lead connected to the die pad, and a second lead spaced from and electrically isolated from the die pad; a spacer dielectric mounted on the die pad; a semiconductor die including a temperature sensor mounted on the spacer dielectric; electrical connections coupling the semiconductor die to the second lead; and mold compound covering the semiconductor die, the die pad, the electrical connections, and a portion of the package substrate, with portions of the first lead and portions of the second lead exposed from the mold compound to form terminals for a packaged temperature sensor device.

A method of frame handling during semiconductor package production includes: providing a lead frame having leads secured to a periphery of the lead frame by first tie bars; providing a multi-gauge spacer frame having spacers secured to a periphery of the spacer frame by second tie bars, the spacers being thicker than the second tie bars; and aligning the multi-gauge spacer frame with the lead frame such that the spacers and the second tie bars of the multi-gauge spacer frame do not contact the leads of the lead frame. A power semiconductor module and a method of assembling a power semiconductor module are also described.

In examples, a semiconductor device comprises a semiconductor die, an opaque mold compound housing covering the semiconductor die, a conductive terminal extending from the mold compound housing, and an insulative coat covering the mold compound housing and at least a portion of the conductive terminal.