A semiconductor package includes a chip level unit including a semiconductor chip; a medium level unit; and a solder ball unit. The solder ball unit is to be connected to a circuit substrate. The medium level unit includes: a wiring pad layer on a first protection layer; a second protection layer including a pad-exposing hole on the first protection layer, a post layer in the pad-exposing hole on the wiring pad layer; and a third protection layer including a post-exposing hole on the second protection layer. A width or diameter of the post-exposing hole is smaller than a width or diameter of the pad-exposing hole; and a barrier layer is disposed in the post-exposing hole on the post layer. The solder ball unit includes a solder ball on the barrier layer.

A package is disclosed. In one example, the package comprises a substrate having at least one first recess on a front side and at least one second recess on a back side, wherein the substrate is separated into a plurality of separate substrate sections by the at least one first recess and the at least one second recess, an electronic component mounted on the front side of the substrate, and a single encapsulant filling at least part of the at least one first recess and at least part of the at least one second recess. The encapsulant fully circumferentially surrounds sidewalls of at least one of the substrate sections.

A semiconductor chip is arranged on a first surface of a die pad in a substrate (leadframe) including an array of electrically conductive leads. An encapsulation of laser direct structuring (LDS) material encapsulates the substrate and the semiconductor chip. The encapsulation has a first surface, a second surface opposed to the first surface and a peripheral surface. The array of electrically conductive leads protrude from the peripheral surface with areas of the second surface of the encapsulation arranged between adjacent leads. LDS structured areas of the second surface located between adjacent leads in the array of electrically conductive leads provide a further array of electrically conductive leads exposed at the second surface. First and second electrically conductive vias extending through the encapsulation material as well as electrically conductive lines over the encapsulation material provide an electrical bonding pattern between the semiconductor chip and selected ones of the leads.

A packaged semiconductor includes an electrically insulating encapsulant body having an upper surface, a first semiconductor die encapsulated within the encapsulant body, the first semiconductor die having a main surface with a first conductive pad that faces the upper surface of the encapsulant body, a second semiconductor die encapsulated within the encapsulant body and disposed laterally side by side with the first semiconductor die, the second semiconductor die having a main surface with a second conductive pad that faces the upper surface of the encapsulant body, and a first conductive track that is formed in the upper surface of the encapsulant body and electrically connects the first conductive pad to the second conductive pad. The encapsulant body includes a laser activatable mold compound.

A method comprises molding laser direct structuring material onto at least one semiconductor die, forming resist material on the laser direct structuring material, producing mutually aligned patterns of electrically-conductive formations in the laser direct structuring material and etched-out portions of the resist material having lateral walls sidewise of said electrically-conductive formations via laser beam energy, and forming electrically-conductive material at said etched-out portions of the resist material, the electrically-conductive material having lateral confinement surfaces at said lateral walls of said etched-out portions of the resist material.

Semiconductor dice are arranged on a substrate such as a leadframe. Each semiconductor die is provided with electrically-conductive protrusions (such as electroplated pillars or bumps) protruding from the semiconductor die opposite the substrate. Laser direct structuring material is molded onto the substrate to cover the semiconductor dice arranged thereon, with the molding operation leaving a distal end of the electrically-conductive protrusion to be optically detectable at the surface of the laser direct structuring material. Laser beam processing the laser direct structuring material is then performed with laser beam energy applied at positions of the surface of the laser direct structuring material which are located by using the electrically-conductive protrusions optically detectable at the surface of the laser direct structuring material as a spatial reference.

An encapsulation of laser direct structuring (LDS) material is molded onto first and second semiconductor dice. A die-to-die coupling formation between the first and second semiconductor dice includes die vias extending through the LDS material to reach the first and second semiconductor dice and a die-to-die line extending at a surface of the encapsulation between the die vias. After laser activating and structuring selected locations of the surface of the encapsulation for the die vias and die-to-die line, the locations are placed into contact with an electrode that provides an electrically conductive path. Metal material is electrolytically grown onto the locations of the encapsulation by exposure to an electrolyte carrying metal cations. The metal cations are reduced to metal material via a current flowing through the electrically conductive path provided via the electrode. The electrode is then disengaged from contact with the locations having metal material electrolytically grown thereon.

An encapsulation of laser direct structuring (LDS) material is molded onto a substrate having first and second semiconductor dice arranged thereon. Laser beam energy is applied to a surface of the encapsulation of LDS material to structure therein die vias extending through the LDS material to the first and second semiconductor dice and a die-to-die line extending at surface of the LDS material between die vias. Laser-induced forward transfer (LIFT) processing is applied to transfer electrically conductive material to the die vias and the die-to-die line extending between die vias. A layer of electrically conductive material electroless grown onto the die vias and the die-to-die line facilitates improved adhesion of the electrically conductive material transferred via LIFT processing.

A nitride semiconductor device includes a semiconductor carrier, a first nitride-based chip, and first conformal connecting structures. The first nitride-based chip is disposed over the semiconductor carrier. The semiconductor carrier has a first planar surface. The first nitride-based chip has a second planar surface, first conductive pads, and first slanted surfaces. The first conductive pads are disposed in the second planar surface. The first slanted surfaces connect the second planar surface to the first planar surface. The first conformal connecting structures are disposed on the first planar surface and the first nitride-based chip. First obtuse angles are formed between the second planar surface and the first slanted surfaces. Each of the first conformal connecting structures covers one of the first slanted surfaces of the first nitride-based chip and one of the first obtuse angles and is electrically connected to the first conductive pads.

A semiconductor device, such as a QFN (Quad-Flat No-lead) package, includes an insulating encapsulation of a semiconductor chip. The insulating encapsulation is formed by a first encapsulation material which encapsulates the semiconductor chip and a second encapsulation material that is molded onto an upper surface of the first encapsulation material. The first encapsulation material includes an oblique cavity extending from the upper surface. The second encapsulation material includes an anchoring protrusion that enters into the cavity.