In an aspect, a system and method for assembling a semiconductor device on a receiving surface of a destination substrate is disclosed. In another aspect, a system and method for assembling a semiconductor device on a destination substrate with topographic features is disclosed. In another aspect, a gravity-assisted separation system and method for printing semiconductor device is disclosed. In another aspect, various features of a transfer device for printing semiconductor devices are disclosed.

Before a semiconductor die of a brittle III-V compound semiconductor is encapsulated with a molding compound during package fabrication, side surfaces of the semiconductor die are treated to avoid or prevent surface imperfections from propagating and fracturing the crystal structure of the substrate of the III-V compound semiconductor under the stresses applied as the molding compound solidifies. Surfaces are treated to form a passivation layer, which may be a passivated layer of the substrate or a passivation material on the substrate. In a passivated layer, imperfections of an external layer are transformed to be less susceptible to fracture. Passivation material, such as a poly-crystalline layer on the substrate surface, diffuses stresses that are applied by the molding compound. Semiconductor dies in flip-chip and wire-bond chip packages with treated side surfaces as disclosed have a reduced incidence of failure caused by die fracturing.

An integrated radar circuit comprising: a first substrate, of a first semiconductor material, said first substrate comprising an integrated transmit and receive radar circuit; a second substrate, of a second semiconductor material, said second substrate comprising at least on through-substrate cavity having cavity walls; at least one discrete transistor chip, of a third semiconductor material, said at least one discrete transistor chip having chip walls and being held in said at least one through-substrate cavity by a metal filling extending from at least one cavity wall to at least one chip wall; a conductor on said second substrate, electrically connecting a portion of said integrated transmit and receive radar circuit to a discrete transistor on said at least one discrete transistor chip.

An electronic assembly comprising a carrier wafer having a top wafer surface and a bottom wafer surface; an electronic integrated circuit being formed in the carrier wafer and comprising an integrated circuit contact pad on the top wafer surface; said carrier wafer comprising a through-wafer cavity having walls that join said top wafer surface to said bottom wafer surface; a component chip having a component chip top surface, a component chip bottom surface and component chip side surfaces, the component chip being held in said through-wafer cavity by direct contact of at least a side surface of said component chip with an attachment metal that fills at least a portion of said through-wafer cavity; said component chip comprising at least one component contact pad on said component chip bottom surface; and a conductor connecting said integrated circuit contact pad and said component contact pad.

An example integrated circuit die includes: lower level conductor layers, lower level insulator layers between the lower level conductor layers, lower level vias extending vertically through the lower level insulator layers, upper level conductor layers overlying the lower level conductor layers, upper level insulator layers between and surrounding the upper level conductor layers, upper level vias; at least two scribe seals arranged to form a vertical barrier extending vertically from the semiconductor substrate to a passivation layer at an upper surface of the integrated circuit die; and at least one opening extending vertically through one of the at least two scribe seals and extending through: the upper level conductor layers, the upper level via layers, the lower level conductor layers, and the lower level via layers.

A III-nitride-based semiconductor packaged structure includes a lead frame, an adhesive layer, a III-nitride-based die, an encapsulant, and at least one bonding wire. The lead frame includes a die paddle and a lead. The die paddle has first and second recesses arranged in a top surface of the die paddle. The first recesses are located adjacent to a relatively central region of the top surface. The second recesses are located adjacent to a relatively peripheral region of the top surface. The first recess has a shape different from the second recess from a top-view perspective. The adhesive layer is disposed on the die paddle to fill into the first recesses. The III-nitride-based die is disposed on the adhesive layer. The encapsulant encapsulates the lead frame and the III-nitride-based die. The second recesses are filled with the encapsulant. The bonding wire is encapsulated by the encapsulant.

A III-nitride-based semiconductor packaged structure includes a lead frame, an adhesive layer, a III-nitride-based die, an encapsulant, and at least one bonding wire. The lead frame includes a die paddle and a lead. The die paddle has first and second recesses arranged in a top surface of the die paddle. The first recesses are located adjacent to a relatively central region of the top surface. The second recesses are located adjacent to a relatively peripheral region of the top surface. The first recess has a shape different from the second recess from a top-view perspective. The adhesive layer is disposed on the die paddle to fill into the first recesses. The III-nitride-based die is disposed on the adhesive layer. The encapsulant encapsulates the lead frame and the III-nitride-based die. The second recesses are filled with the encapsulant. The bonding wire is encapsulated by the encapsulant.

A microelectronic assembly is disclosed, comprising: a substrate having a core made of glass; and a first integrated circuit (IC) die and a second IC die coupled to a first side of the substrate. The core comprises a cavity, a third IC die is located within the cavity, and the core further comprises one or more conductive through-glass via (TGV) that facilitates electrical coupling between the first side of the substrate and an opposing second side of the substrate. In some embodiments, the cavity is a blind cavity; in other embodiments, the cavity is a through-hole. In some embodiments, the third IC die merely provides lateral coupling between the first IC die and the second IC die; in other embodiments, the third IC die also provides electrical coupling between the first side and the second side of the substrate with through-silicon vias.

In an aspect, a system and method for assembling a semiconductor device on a receiving surface of a destination substrate is disclosed. In another aspect, a system and method for assembling a semiconductor device on a destination substrate with topographic features is disclosed. In another aspect, a gravity-assisted separation system and method for printing semiconductor device is disclosed. In another aspect, various features of a transfer device for printing semiconductor devices are disclosed.

A chip includes a semiconductor substrate, an electrical connector over the semiconductor substrate, and a molding compound molding a lower part of the electrical connector therein. A top surface of the molding compound is lower than a top end of the electrical connector. A recess extends from the top surface of the molding compound into the molding compound.