Integrated circuitry comprising transistor structures with a source/drain etch stop layer to limit the depth of source and drain material relative to a channel of the transistor. A portion of a channel material layer may be etched in preparation for source and drain materials. The etch may be stopped at an etch stop layer buried between a channel material layer and an underlying planar substrate layer. The etch stop layer may have a different composition than the channel layer while retaining crystallinity of the channel layer. The source and drain etch stop layer may provide adequate etch selectivity to ensure a source and drain etch process does not punch through the etch stop layer. Following the etch process, source and drain materials may be formed, for example with an epitaxial growth process. The source and drain etch stop layer may be, for example, primarily silicon and carbon.

Subject matter disclosed herein may relate to semiconductor devices, and may more particularly relate to power semiconductor packages, for example.

A semiconductor structure including chips is provided. The chips are arranged in a stack. Each of the chips includes a radio frequency (RF) device. Two adjacent chips are bonded to each other. The RF devices in the chips are connected in parallel. Each of the RF devices includes a gate, a source region, and a drain region. The gates in the RF devices connected in parallel have the same shape and the same size. The source regions in the RF devices connected in parallel have the same shape and the same size. The drain regions in the RF devices connected in parallel have the same shape and the same size.

This disclosure relates to a discrete cascode semiconductor device and associated method of manufacture, the device includes: a high voltage depletion mode device die having gate, source and drain terminals arranged on a first major surface thereof; a low voltage enhancement mode device die having a gate and a source terminal formed on a first major surface thereof, and a drain terminal formed on a second major surface opposite the first major surface. The drain terminal of the high voltage device die is mounted on a drain connection; the source terminal of the low voltage device die and the gate terminal of the high voltage device are mounted on a common source connection; and the drain terminal of the low voltage device die is mounted on the source terminal of the high voltage device.

Embodiments disclosed herein include semiconductor devices and methods of forming such devices. In an embodiment the semiconductor device comprises a first semiconductor layer, where first transistors are fabricated in the first semiconductor layer, and a back end stack over the first transistors. In an embodiment the back end stack comprises conductive traces and vias electrically coupled to the first transistors. In an embodiment, the semiconductor device further comprises a second semiconductor layer over the back end stack, where the second semiconductor layer is a different semiconductor than the first semiconductor layer. In an embodiment, second transistors are fabricated in the second semiconductor layer.

Provided is a clip structure for a semiconductor package comprising: a first bonding unit bonded to a terminal part of an upper surface or a lower surface of a semiconductor device by using a conductive adhesive interposed therebetween, a main connecting unit which is extended and bent from the first bonding unit, a second bonding unit having an upper surface higher than the upper surface of the first bonding unit, an elastic unit elastically connected between the main connecting unit and one end of the second bonding unit, and a supporting unit bent and extended from the other end of the second bonding unit toward the main connecting unit, wherein the supporting unit is formed to incline at an angle of 1° through 179° from an extended surface of the main connecting unit and has an elastic structure so that push-stress applying to the semiconductor device while molding may be dispersed.

Semiconductor device structures and methods for manufacturing the same are provided. The semiconductor device structure includes a substrate, a first nitride semiconductor layer, a second nitride semiconductor layer, a gate electrode, a first electrode, a first via and a second via. The substrate has a first surface and a second surface. The first nitride semiconductor layer is disposed on the first surface of the substrate. The second nitride semiconductor layer is disposed on the first nitride semiconductor layer and has a bandgap exceeding that of the first nitride semiconductor layer. The gate electrode and the first electrode are disposed on the second nitride semiconductor layer. The first via extends from the second surface and is electrically connected to the first electrode. The second via extends from the second surface. The depth of the first via is different from the depth of the second via.

A method includes providing a first lead frame that includes a first die pad and a first row of leads, providing a connection lug, mounting a first semiconductor die on the first die pad, the first semiconductor die including first and second voltage blocking terminals, electrically connecting the connection lug to one of the first and second voltage blocking terminals, electrically connecting a first one of the leads from the first row to an opposite one of the first and second voltage blocking terminals, and forming an encapsulant body of electrically insulating material that encapsulates first die pad and the first semiconductor die. After forming the encapsulant body, the first row of leads each protrude out of a first outer face of the encapsulant body and the connection lug protrudes out of a second outer face of the encapsulant body.

Multichip package manufacturing process is disclosed to form external pins at one side or each side of die-bonding area of package carrier board and to bond first IC and second IC to die-bonding area in stack. First IC and second IC each comprise transistor layer with core circuits, plurality of metal layers, plurality of VIA layers and solder pad layer. During production of first IC, design of at least one metal layer, VIA layer and dummy pads can be modified according to change of design of second IC. After chip probing, die sawing and bonding, wire bonding, packaging and final test are performed to package the package carrier board, first IC and second IC into automotive multichip package, achieving purpose of first IC only need to modify at least one layer or more than one layer to cooperate with second IC design change to carry out multichip packaging process.

The disclosure concerns an electronic device comprising, stacked from a first surface to a second surface, a first stack and a second stack of two high electron mobility transistors, referred to as first and second transistor, the first and the second stack each comprising, from an insulating layer, interposed between the first and the second stack, a barrier layer and a channel layer, the first and the second transistor respectively comprising a first and a second set of electrodes, the first and the second set of electrodes being each provided with a source electrode, with a drain electrode, and with a gate electrode which are arranged so that the first and the second transistor form a half-arm of a bridge.