A semiconductor device is extremely reliable because a sealant thereof is difficult to deteriorate even when a SiC semiconductor element is energized. The semiconductor device is produced by sealing a SiC semiconductor element 11 mounted on a multilayer substrate 12 and electrically conductive connection members 14 and 18 with a sealant 20 containing an ultraviolet light absorbent.

The present invention relates to a semiconductor package in which a metal bridge, which is bent and has elasticity and a non-vertical structure, may protect a semiconductor chip in such a way that push-stress occurring while molding is relieved by being absorbed or dispersed by being diverted, a method of manufacturing the same, and the metal bridge applied to the semiconductor package.

A package includes a leadframe having first surface and a second surface opposing the first surface, the leadframe forming a plurality of leads, a first semiconductor die mounted on the first surface of the leadframe and electrically connected to at least one of the plurality of leads, a second semiconductor die mounted on the second surface of the leadframe, wire bonds electrically connecting the second semiconductor die to the leadframe, and mold compound at least partially covering the first semiconductor die, the second semiconductor die and the wire bonds.

A semiconductor device includes a semiconductor die attached to a substrate and a metal clip attached to a side of the semiconductor die facing away from the substrate by a soldered joint. The metal clip has a plurality of slots dimensioned so as to take up at least 10% of a solder paste that reflowed to form the soldered joint. Corresponding methods of production are also described.

A bonded structure includes a semiconductor element, an electrical conductor and a sintered metal layer. The semiconductor element has an element obverse surface and an element reverse surface spaced apart from each other in a first direction and includes a reverse-surface electrode on the element reverse surface. The electrical conductor has a mount surface facing in a same direction as the element obverse surface and supports the semiconductor element with the mount surface facing the element reverse surface. The sintered metal layer bonds the semiconductor element to the electrical conductor and electrically connects the reverse-surface electrode and the electrical conductor. The mount surface includes a roughened area roughened by a roughening process. The sintered metal layer is formed on the roughened area.

A leadframe includes a die pad having arranged thereon a first semiconductor die with an electrically conductive ribbon extending on the first semiconductor die. The first semiconductor die lies intermediate the leadframe and the electrically conductive ribbon. A second semiconductor die is mounted on the electrically conductive ribbon to provide, on the same die pad, a stacked arrangement of the second semiconductor die and the first semiconductor die with the at least one electrically conductive ribbon intermediate the first semiconductor die and the second semiconductor die. Package size reduction can thus be achieved without appreciably affecting the assembly flow of the device.

A method of attaching a metal clip to a semiconductor die includes: aligning a first bonding region of the metal clip with a first bond pad of the semiconductor die; and while the first bonding region of the metal clip is aligned with the first bond pad of the semiconductor die, forming a plurality of first wire bonds to the first bond pad of the semiconductor die through a plurality of openings in the first bonding region of the metal clip, the plurality of first wire bonds forming a joint between the metal clip and the first bond pad of the semiconductor die. Additional methods and related semiconductor packages produced from such methods are also described.

A semiconductor device includes an insulating substrate, a first and a second obverse-surface metal layers disposed on an obverse surface of the insulating substrate, a first and a second reverse-surface metal layers disposed on a reverse surface of the insulating substrate, a first conductive layer and a first semiconductor element disposed on the first obverse-surface metal layer, and a second conductive layer and a second semiconductor element disposed on the second obverse-surface metal layer. Each of the first conductive layer and the second conductive layer has an anisotropic coefficient of linear expansion and is arranged such that the direction in which the coefficient of linear expansion is relatively large is along a predetermined direction perpendicular to the thickness direction of the insulating substrate. The first and second reverse-surface metal layers are smaller than the first and second obverse-surface metal layers in dimension in the predetermined direction.

A gang clip includes a plurality of clips formed from a metal each having a center region oriented along a first plane and an angled clip foot having a foot height, a length and a bend angle sufficient to electrically contact a lead terminal of the leadframe to be used to form a device. Adjacent ones of the plurality of clips are joined to one another by a first tie bar also oriented along the first plane. The first tie bar extends to a saw street region located between adjacent ones of the clips. A second tie bar attached to the first tie bar is positioned in the saw street region.

In one example, a method of manufacturing a semiconductor device includes providing a substrate having substrate terminals and providing a component having a first component terminal and a second component terminal adjacent to a first major side of the component. The method includes providing a clip structure having a first clip, a second clip, and a clip connector coupling the first clip to the second clip. The method includes coupling the first clip to the first component terminal and a first substrate terminal and coupling the second clip to a second substrate terminal. The method includes encapsulating the component, portions of the substrate, and portions of the clip structure. the method includes removing a sacrificial portion of the clip connector while leaving a first portion of the clip connector attached to the first clip and leaving a second portion of the clip connector attached to the second clip. In some examples, the first portion of the clip connector includes a first portion surface, the second portion of the clip connector includes a second portion surface, and the first portion surface and the second portion surface are exposed from a top side of the encapsulant after the removing. Other examples and related structures are also disclosed herein.