A yield in the step of bonding two members together is improved. A bonding apparatus includes a stage capable of supporting a first member having a sheet-like shape, a fixing mechanism capable of fixing one end portion of a second member having a sheet-like shape so that the second member overlaps with the first member, and a pressurizing mechanism capable of moving from a side of the one end portion of the second member to a side of the other end portion and spreading a bonding layer under pressure between the first member and the second member. The first member and the second member are bonded to each other.

A wafer dicing method comprises providing a wafer and performing a cutting procedure and a contacting procedure. The wafer includes a plurality of dies and a metal layer, wherein the metal layer is formed on a scribe line which is formed between adjacent dies. A cutter is used to cut the metal layer along the scribe line during the cutting procedure to form a plurality of dies on the wafer, and the metal layer cut by the cutter remains a plurality of metal burrs on the dies. A brush is used to contact with the metal burrs along the cutting slot during the contracting procedure to prevent each of the metal burrs from protruding from a surface of each of the dies.

A yield in the step of bonding two members together is improved. A bonding apparatus includes a stage capable of supporting a first member having a sheet-like shape, a fixing mechanism capable of fixing one end portion of a second member having a sheet-like shape so that the second member overlaps with the first member, and a pressurizing mechanism capable of moving from a side of the one end portion of the second member to a side of the other end portion and spreading a bonding layer under pressure between the first member and the second member. The first member and the second member are bonded to each other.

A semiconductor device includes a wiring board, a semiconductor chip, and a connecting member provided between a surface of the wiring board and a functional surface of the semiconductor chip. The connecting member extends a distance between the wiring board surface and the functional surface. A sealing material seals a gap space between the wiring board and the semiconductor chip. An electrode is formed at the wiring board surface and arranged outside of an outer periphery of the sealing material. A lateral distance between an outer periphery of the semiconductor chip and the outer periphery of the sealing material is between 0.1 mm and a lateral distance from the outer periphery of the semiconductor chip to the electrode.

The present disclosure relates to a packaging process to enhance thermal and electrical performance of a wafer-level package. The wafer-level package with enhanced performance includes a first thinned die having a first device layer, a multilayer redistribution structure, a first mold compound, and a second mold compound. The multilayer redistribution structure includes package contacts on a bottom surface of the multilayer redistribution structure and redistribution interconnects connecting the first device layer to the package contacts. The first mold compound resides over the multilayer redistribution structure and around the first thinned die, and extends beyond a top surface of the first thinned die to define a cavity within the first mold compound and over the first thinned die. The second mold compound fills the cavity and is in contact with the top surface of the first thinned die.

A semiconductor device includes a carrier, a semiconductor die and a die attach material arranged between the carrier and the semiconductor die. A fillet height of the die attach material is less than about 95% of a height of the semiconductor die. A maximum extension of the die attach material over edges of a main surface of the semiconductor die facing the die attach material is less than about 200 micrometers.

A semiconductor device includes a box-shaped casing including a ceiling wall with a first window, a semiconductor chip having an output electrode and assembled in the casing, a first conductive block disposed in the casing, and a first connection terminal being bent so as to implement an elongated U-shape. The semiconductor device is adapted for electrical connection to a circuit board having a first land. The circuit board is placed on the ceiling wall. The first window is at a position corresponding to the first land. A lower end of the first conductive block is connected to a surface of the output electrode and the first connection terminal contacts to the first conductive block.

A semiconductor device includes a wiring board, a semiconductor chip, and a connecting member provided between a surface of the wiring board and a functional surface of the semiconductor chip. The connecting member extends a distance between the wiring board surface and the functional surface. A sealing material seals a gap space between the wiring board and the semiconductor chip. An electrode is formed at the wiring board surface and arranged outside of an outer periphery of the sealing material. A lateral distance between an outer periphery of the semiconductor chip and the outer periphery of the sealing material is between 0.1 mm and a lateral distance from the outer periphery of the semiconductor chip to the electrode.

Provided is a semiconductor device including: a first external electrode which includes a circular outer peripheral portion; a MOSFET chip; a control circuit chip which receives voltages of a drain electrode and a source electrode of the MOSFET and supplies a signal to a gate electrode to control the MOSFET on the basis of the voltage; a second external electrode which is disposed on an opposite side of the first external electrode with respect to the MOSFET chip and includes an external terminal on a center axis of the circular outer peripheral portion of the first external electrode; and an isolation substrate which isolates the control circuit chip from the external electrode. The first external electrode, the drain electrode and the source electrode of the MOSFET chip, and the second external electrode are disposed to be overlapped in a direction of the center axis. The drain electrode of the MOSFET chip and the first external electrode are connected. The source electrode of the MOSFET chip and the second external electrode are connected.

Inside an IGBT using GaN or SiC, light having an energy of approximately 3 [eV] is generated. Therefore, defects are caused in the gate insulating film of the IGBT. Furthermore, the charge trapped at a deep level becomes excited and moves to the channel region, thereby causing the gate threshold voltage to fluctuate from the predetermined value. Provided is a semiconductor device including a normally-ON semiconductor element that includes a first semiconductor layer capable of conductivity modulation and a first gate electrode, but does not include a gate insulating film between the first gate electrode and the first semiconductor layer; and a normally-OFF semiconductor element that includes a second semiconductor layer, a second gate electrode, and a gate insulating film between the second semiconductor layer and the second gate electrode. The normally-ON semiconductor element and the normally-OFF semiconductor element are connected in series.