Monolithic microwave integrated circuits (MMICs) tolerant to electrical overstress are provided. In certain embodiments, a MMIC includes a signal pad that receives a radio frequency (RF) signal, and an RF circuit coupled to the RF signal pad. The RF circuit includes a transistor layout, an input field-effect transistor (FET) implemented using a first portion of a plurality of gate fingers of the transistor layout, and an embedded protection device electrically connected between a gate and a source of the input FET and implemented using a second portion of the plurality of gate fingers. The MMIC is tolerant to electrical overstress events, such as field-induced charged-device model (FICDM) events.

A layout structure of a capacitive element using forksheet FETs is provided. A capacitive structure constituting the capacitive element includes: a first transistor having a first nanosheet extending in the X direction and a first gate interconnect extending in the Y direction and surrounding the periphery of the first nanosheet; and a second transistor having a second nanosheet extending in the X direction and a second gate interconnect extending in the Y direction and surrounding the periphery of the second nanosheet. The face of the first nanosheet closer to the second nanosheet is exposed from the first gate interconnect, and the face of the second nanosheet closer to the first nanosheet is exposed from the second gate interconnect.

Substrate-less diode, bipolar and feedthrough integrated circuit structures, and methods of fabricating substrate-less diode, bipolar and feedthrough integrated circuit structures, are described. For example, a substrate-less integrated circuit structure includes a semiconductor structure. A plurality of gate structures is over the semiconductor structure. A plurality of P-type epitaxial structures is over the semiconductor structure. A plurality of N-type epitaxial structures is over the semiconductor structure. One or more open locations is between corresponding ones of the plurality of gate structures. A backside contact is connected directly to one of the pluralities of P-type and N-type epitaxial structures.

The present invention provides an ESD protection circuit including a control circuit, a first transistor, a filter and a second transistor. The control circuit is configured to detect a level of a supply voltage to generate a control signal. The first transistor is coupled between the supply voltage and a ground voltage, and is used to refer to the control signal to determine whether to be enabled as a discharging path for the supply voltage to discharge current to the ground voltage. The filter is configured to filter the control signal to generate a filtered control signal. The second transistor is coupled between the supply voltage and the ground voltage, and is used to refer to the filtered control signal to determine whether to be enabled as a discharging path for the supply voltage to discharge current to the ground voltage.

The present disclosure provides embodiments of semiconductor structures. A semiconductor structure according to the present disclosure includes a substrate, a fin-shaped structure disposed over the substrate, the fin-shaped structure including a plurality of first semiconductor layers interleaved by a plurality of second semiconductor layers, a gate structure disposed over a channel region of the fin-shaped structure, a first source/drain feature extending through at least a first portion the fin-shaped structure, a second source/drain feature extending through at least a second portion of the fin-shaped structure, and a backside metal line disposed below the substrate and spaced apart from the first source/drain feature and the second source/drain feature.

A semiconductor device includes a capacitance adjusting region. The capacitance adjusting region includes a first semiconductor layer of a first conductivity type, a second semiconductor layer of a second conductivity type, and a plurality of control trench gates. The first semiconductor layer is provided as a surface layer at an upper surface of the semiconductor substrate. The second semiconductor layer is selectively provided at an upper surface of the first semiconductor layer. The second semiconductor layer contacts a side surface of each of the control trench gates. The first semiconductor layer and the second semiconductor layer are electrically connected to an emitter electrode of a transistor. A control trench electrode of at least one control trench gate is electrically connected to a gate electrode of the transistor.

A semiconductor device includes a substrate provided with a decoupling capacitor and plurality of circuit elements disposed along a first direction, and a plurality of first wiring line patterns disposed in a first wiring line layer over the substrate, including a power routing pattern coupled to the decoupling capacitor and a plurality of internal wiring line patterns coupled to the plurality of circuit elements. The plurality of first wiring line patterns extend in the first direction, and are aligned in conformity with virtual wiring line pattern tracks which are defined at a first pitch along a second direction intersecting the first direction and parallel to the substrate.

A new class of logic gates are presented that use non-linear polar material. The logic gates include multi-input majority gates and threshold gates. Input signals in the form of analog, digital, or combination of them are driven to first terminals of non-ferroelectric capacitors. The second terminals of the non-ferroelectric capacitors are coupled to form a majority node. Majority function of the input signals occurs on this node. The majority node is then coupled to a first terminal of a capacitor comprising non-linear polar material. The second terminal of the capacitor provides the output of the logic gate, which can be driven by any suitable logic gate such as a buffer, inverter, NAND gate, NOR gate, etc. Any suitable logic or analog circuit can drive the output and inputs of the majority logic gate. As such, the majority gate of various embodiments can be combined with existing transistor technologies.

A switching circuit forming a bidirectional switch between a first node and a second node and resting on a substrate, the circuit comprising°: a first branch with a first diode in series with a first heterojunction field-effect transistor, a second branch with a second heterojunction field-effect transistor in series with a second diode, the first branch and the second branch being mounted in parallel to one another and so that the first diode and the second diode are arranged in antiparallel or in anti-series with respect to one another, the first transistor, the second transistor being each provided with a control gate facing a heterojunction band forming an active zone in which an electron gas is capable of being formed, the first diode being a Schottky diode with a metal electrode in contact with the heterojunction band, the second diode being a Schottky diode with a metal electrode in contact with the heterojunction band, the first diode, the first transistor, the second diode, the second transistor sharing the same active zone (FIG. 5).

In some aspects, the techniques described herein relate to a circuit including: a metal-oxide semiconductor field-effect transistor (MOSFET) including a gate, a source, and a drain; and a snubber circuit coupled between the drain and the source, the snubber circuit including: a diode having a cathode and an anode, the cathode being coupled with the drain; a capacitor having a first terminal coupled with the anode, and a second terminal coupled with the source; and a resistor having a first terminal coupled with the anode and the first terminal of the capacitor, and a second terminal coupled with the source.