A method of transferring a micro device and an array of micro devices are disclosed. A carrier substrate carrying a micro device connected to a bonding layer is heated to a temperature below a liquidus temperature of the bonding layer, and a transfer head is heated to a temperature above the liquidus temperature of the bonding layer. Upon contacting the micro device with the transfer head, the heat from the transfer head transfers into the bonding layer to at least partially melt the bonding layer. A voltage applied to the transfer head creates a grip force which picks up the micro device from the carrier substrate.

In a general aspect, an apparatus can include an inner package including a first silicon carbide die having a die gate conductor coupled to a common gate conductor, and a second silicon carbide die having a die gate conductor coupled to the common gate conductor. The apparatus can include an outer package including a substrate coupled to the common gate conductor, and a clip coupled to the inner package and coupled to the substrate.

An electronic component includes a first set comprising an interconnect layer and an electronic circuit having a front face and a back face, which is connected to the interconnect layer by the front face, wherein the first set comprises a metal plate having a front face and a back face joined to the back face of the electronic circuit; a coupling agent between the front face of the metal plate and the back face of the electronic circuit, configured to thermally and electrically connect the metal plate to the electronic circuit; and in that the electronic component comprises: one or more layers made of organic materials stacked around the first set and the metal plate using a printed circuit-type technique and encapsulating the electronic circuit; a thermally conductive metal surface arranged at least partially in contact with the back face of the metal plate.

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 optoelectronic device includes a first semiconductor die, having first front and rear surfaces and including at least one avalanche photodetector configured to output electrical pulses in response to photons incident on the first front surface. A second semiconductor die has a second front surface, which is bonded to the first rear surface, and a second rear surface, and includes a photodetector receiver analog circuit coupled to the at least one avalanche photodetector and an emitter driver circuit configured to drive a pulsed optical emitter. A third semiconductor die has a third front surface, which is bonded to the second rear surface, and a third rear surface, and includes logic circuits coupled to control the photodetector receiver analog circuit and the emitter driver circuit and to receive and process the electrical pulses output by the at least one avalanche photodetector.

A semiconductor wafer processing method, having: ablating a back side of a semiconductor wafer with a laser ablation process; and etching the back side of the semiconductor wafer with an etching process; wherein the laser ablation process forms a pattern in the back side of the semiconductor wafer; wherein the etching process preserves the pattern in the back side of the semiconductor wafer.

A semiconductor device that includes a bipolar transistor, wherein a third opening, through which a pillar bump and a second wiring line, which is electrically connected to an emitter layer, contact each other, is shifted in a longitudinal direction of the emitter layer away from a position at which the third opening would be directly above the emitter layer. The third opening is arranged, with respect to the emitter layer, such that an end portion of the emitter layer in the longitudinal direction of the emitter layer and the edge of the opening of the third opening are substantially aligned with each other.

A method of manufacturing a packaged semiconductor device is provided. The method includes placing a plurality of semiconductor die on a carrier substrate. The plurality of semiconductor die and an exposed portion of the carrier substrate are encapsulated with an encapsulant. A cooling fixture includes a plurality of nozzles and is placed over the encapsulant. The encapsulant is cooled by way of air exiting the plurality of nozzles. A property of air exiting a first nozzle of the plurality of nozzles is different from that of a second nozzle of the plurality of nozzles.

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 chip structure including a chip body and a plurality of conductive bumps. The chip body includes an active surface and a plurality of bump pads disposed on the active surface. The conductive bumps are disposed on the active surface of the chip body and connected to the bump pads respectively, and at least one of the conductive bumps has a trapezoid shape having one pair of parallel sides and one pair of non-parallel sides.