Embodiments of the present invention are directed to a method for forming a complementary field effect transistor (CFET) structure having a wrap-around contact. In a non-limiting embodiment of the invention, a complementary nanosheet stack is formed over a substrate. The complementary nanosheet stack includes a first nanosheet and a second nanosheet separated by a dielectric spacer. A first sacrificial layer is formed over a source or drain (S/D) region of the first nanosheet and a second sacrificial layer is formed over a S/D region of the second nanosheet. A conductive gate is formed over channel regions of the first nanosheet and the second nanosheet. After the conductive gate is formed, the first sacrificial layer is replaced with a first wrap-around contact and the second sacrificial layer is replaced with a second wrap-around contact.

A device includes a first III-V compound layer, a second III-V compound layer, a dielectric layer, a contact, a metal-containing layer, and a metal contact. The second III-V compound layer is over the first III-V compound layer. The dielectric layer is over the second III-V compound layer. The contact extends through the dielectric layer to the second III-V compound layer. The contact is in contact with a top surface of the dielectric layer and an inner sidewall of the dielectric layer. The metal-containing layer is over and in contact with the contact, and a portion of the metal-containing layer is directly above the dielectric layer. The metal contact is over and in contact with the metal-containing layer.

A surge protection device for providing bidirectional detections of one or more surge events. The device has low dynamic resistance during a surge protection mode, and it conducts ultra-low leakage current outside of the surge protection mode. In one implementation, the device includes first and second power transistors, a sensing circuit, and a driver circuit. The first power transistor includes a first source terminal that is coupled to the substrate, and the second power transistor includes a second source terminal that is coupled to the substrate. The sensing circuit is configured to detect a voltage of the first pin relative to the second pin and generate a sense signal when the voltage exceeds a threshold. The driver circuit is configured to generate a driver signal based on the sense signal and output the driver signal to at least one of the first or second gate terminal.

In some embodiments, the present disclosure relates to a high voltage device that includes a substrate comprising a first semiconductor material. A channel layer that comprises a second semiconductor material is arranged over the substrate. An active layer that comprises a third semiconductor material is arranged over the channel layer. Over the active layer is a source contact spaced apart from a drain contact. A gate structure is arranged laterally between the source and drain contacts and over the active layer to define a high electron mobility transistor (HEMT) device. Between the gate structure and the source contact is a cap structure, which is coupled to the source contact and laterally spaced from the gate structure. The cap structure and a gate electrode of the gate structure comprise a same material.

In a general aspect, a laterally diffused metal-oxide-semiconductor (LDMOS) transistor can include: a substrate of a first conductivity type; a buried well region of a second conductivity type disposed in the substrate; a body region of the first conductivity type disposed on the buried well region, a drift region of the second conductivity type disposed in the body region, a drain implant of the second conductivity type disposed in the drift region; a source implant of the second conductivity type disposed in the body region; and a gate structure disposed on the drift region. The gate structure can include: a field plate including a RESURF dielectric layer; a gate dielectric layer; and a gate electrode disposed on the field plate and the gate dielectric layer. The LDMOS transistor can also include a drain contact extending through the field plate and defining an Ohmic contact with the drain implant.

RF transistor amplifiers include an RF transistor amplifier die having a semiconductor layer structure, a coupling element on an upper surface of the semiconductor layer structure, and an interconnect structure on an upper surface of the coupling element so that the RF transistor amplifier die and the interconnect structure are in a stacked arrangement. The coupling element includes a first shielded transmission line structure.

An integrated circuit device includes a radio frequency transistor amplifier die having a first surface, a second surface, a semiconductor layer structure that is between the first and second surfaces and includes a plurality of transistor cells adjacent the first surface, and terminals coupled to the transistor cells. At least one passive electronic component is provided on the second surface of the die and is electrically connected to at least one of the terminals, for example, by at least one conductive via. One or more conductive pillar structures may protrude from the first surface of the die to provide electrical connections to one or more of the terminals.

We disclose a Ill-nitride semiconductor based heterojunction power device, comprising: a first heterojunction transistor (19) formed on a substrate, the first heterojunction transistor comprising: a first Ill-nitride semiconductor region formed over the substrate, wherein the first Ill-nitride semiconductor region comprises a first heterojunction comprising at least one two dimensional carrier gas of second conductivity type; a first terminal (8) operatively connected to the first Ill-nitride semiconductor region; a second terminal (9) laterally spaced from the first terminal and operatively connected to the first Ill-nitride semiconductor region; a first gate terminal (10) formed over the first Ill-nitride semiconductor region between the first terminal and the second terminal. The device also includes a second heterojunction transistor (14) formed on a substrate, the second heterojunction transistor comprising: a second Ill-nitride semiconductor region formed over the substrate, wherein the second Ill-nitride semiconductor region comprises a second heterojunction comprising at least one two dimensional carrier gas of second conductivity type; a third terminal operatively connected to the second Ill-nitride semiconductor region; a fourth terminal laterally spaced from the third terminal in a first dimension and operatively connected to the second Ill-nitride semiconductor region, wherein the fourth terminal is operatively connected to the first gate terminal; and a second gate terminal formed over the second Ill-nitride semiconductor region between the third terminal and the fourth terminal and wherein the second heterojunction transistor is used in sensing and protection functions of the first power heterojunction transistor. The device also includes at least one monolithically integrated current sensing transistor (16) that has a substantially identical structure to the first heterojunction transistor, and

wherein the third transistor is scaled to a smaller area or a shorter gate width when compared to the first heterojunction transistor by a scale factor, X, where X is larger than 1. Other embodiments include both internal and external sensing, sensing loads and a feedback circuit to provide overcurrent, gate over-voltage or over-temperature protection.

An integrated circuit device includes a radio frequency transistor amplifier die having a first surface, a second surface, a semiconductor layer structure that is between the first and second surfaces and includes a plurality of transistor cells adjacent the first surface, and terminals coupled to the transistor cells. At least one passive electronic component is provided on the second surface of the die and is electrically connected to at least one of the terminals, for example, by at least one conductive via. One or more conductive pillar structures may protrude from the first surface of the die to provide electrical connections to one or more of the terminals.

A high electron mobility transistor (HEMT) includes a first III-V compound layer, a second III-V compound layer over the first III-V compound layer, source and drain structures over the second III-V compound layer and spaced apart from each other, a gate structure over the second III-V compound layer and between the source and drain structures, a gate field plate over the second III-V compound layer and between the gate structure and the drain structure, and an etch stop layer over the drain structure and spaced apart from the gate field plate.