A semiconductor package includes: an electrically insulating core and an electrically conductive first via extending through a periphery region of the core, the core having glass fibres interwoven with epoxy material and one or more regions where the glass fibres are exposed from the epoxy material; a power semiconductor die embedded in an opening in the core and having a first load terminal bond pad which faces a same direction as a first side of the core, a second load terminal bond pad which faces a same direction as a second side of the core, and a control terminal bond pad; a resin that encases the power semiconductor die; a first contact pad plated on the first via at the second side of the core; and a second contact pad plated on the first load terminal bond pad of the power semiconductor die at the first side of the core.

This application relate to a semiconductor apparatus. The semiconductor apparatus includes: a first semiconductor layer; a second die; a thermally conductive layer, where the thermally conductive layer is stacked with the first semiconductor layer and the second die, is located between the first semiconductor layer and the second die, and a coefficient of thermal conductivity of the thermally conductive layer in a horizontal direction is greater than or equal to a coefficient of thermal conductivity in a vertical direction; and a first conductive pillar, where the first conductive pillar penetrates through the thermally conductive layer, the first conductive pillar is electrically insulated from the thermally conductive layer, an extension direction of the first conductive pillar is the vertical direction, and the coefficient of thermal conductivity of the thermally conductive layer in the horizontal direction is greater than a coefficient of thermal conductivity of the first semiconductor layer.

Embodiments may relate to a microelectronic package that includes a die and a backside metallization (BSM) layer positioned on the face of the die. The BSM layer may include a feature that indicates that the BSM layer was formed on the face of the die by a masked deposition technique. Other embodiments may be described or claimed.

A semiconductor package includes a power semiconductor chip comprising SiC, a leadframe part comprising Cu, wherein the power semiconductor chip is arranged on the leadframe part, and a solder joint electrically and mechanically coupling the power semiconductor chip to the leadframe part, wherein the solder joint comprises at least one intermetallic phase.

Method embodiments of wafer dicing for backside metallization are provided. One method includes: applying dicing tape to a front side of a semiconductor wafer, wherein the front side of the semiconductor wafer includes active circuitry; cutting a back side of the semiconductor wafer, the back side opposite the front side, wherein the cutting forms a retrograde cavity in a street of the semiconductor wafer, the retrograde cavity has a gap width at the back side of the semiconductor wafer, and the retrograde cavity has sidewalls with negative slope; depositing a metal layer on the back side of the semiconductor wafer, wherein the gap width is large enough to prevent formation of the metal layer over the retrograde cavity; and cutting through the street of the semiconductor wafer subsequent to the depositing the metal layer.

A semiconductor package includes semiconductor bridge, first and second multilayered structures, first encapsulant, and a pair of semiconductor dies. Semiconductor dies of the pair include semiconductor substrate and conductive pads disposed at front surface of semiconductor substrate. Semiconductor bridge electrically interconnects the pair of semiconductor dies. First multilayered structure is disposed on rear surface of one semiconductor die. Second multilayered structure is disposed on rear surface of the other semiconductor die. First encapsulant laterally wraps first multilayered structure, second multilayered structure and the pair of semiconductor dies. Each one of first multilayered structure and second multilayered structure includes a top metal layer, a bottom metal layer, and an intermetallic layer. Each one of first multilayered structure and second multilayered structure has surface coplanar with surface of first encapsulant. The top metal layers, the bottom metal layers, and the intermetallic layers are in contact with the first encapsulant.

A method of forming a chip assembly may include forming a plurality of cavities in a carrier; The method may further include arranging a die attach liquid in each of the cavities; arranging a plurality of chips on the die attach liquid, each chip comprising a rear side metallization and a rear side interconnect material disposed over the rear side metallization, wherein the rear side interconnect material faces the carrier; evaporating the die attach liquid; and after the evaporating the die attach liquid, fixing the plurality of chips to the carrier.

Reliability of a semiconductor device is improved. A power device includes: a semiconductor chip; a chip mounting part; a solder material electrically coupling a back surface electrode of the semiconductor chip with an upper surface of the chip mounting part; a plurality of inner lead parts and a plurality of outer lead parts electrically coupled with an electrode pad of the semiconductor chip through wires; and a sealing body for sealing the semiconductor chip and the wires. Further, a recess is formed in a peripheral region of the back surface of the semiconductor chip. The recess has a first surface extending to join the back surface and a second surface extending to join the first surface. Also, a metal film is formed over the first surface and the second surface of the recess.

A method for forming a thin film according to an exemplary embodiment of the present invention includes forming the thin film at a power density in the range of approximately 1.5 to approximately 3 W/cm.sup.2 and at a pressure of an inert gas that is in the range of approximately 0.2 to approximately 0.3 Pa. This process results in an amorphous metal thin film barrier layer that prevents undesired diffusion from adjacent layers, even when this barrier layer is thinner than many conventional barrier layers.

Backside metallization techniques for a semiconductor assembly are disclosed. In one aspect, a die, such as a radio frequency (RF) die, within a semiconductor package may include backside metallization for RF performance reasons. The metallization is generally planar and covers a surface of the RF die. Exemplary aspects of the present disclosure cause the metallization to include trenches or grooves to allow for better expansion and contraction during thermal cycling of the RF die. In particular, the trenches decrease a modulus of the metallization layer and act as a shock absorber and allow for compression and expansion of the metallization to match the compression and expansion of the non-metal substrate of the RF die. By allowing for better matching of the compression and expansion of the two heterogeneous materials, delamination may be delayed or averted.