Some embodiments relate to a thin film transistor comprising an active layer over a substrate. An insulator is stacked with the active layer. A gate electrode structure is stacked with the insulator and includes a gate material layer having a first work function and a first interfacial layer. The first interfacial layer is directly between the insulator and the gate material layer, wherein the gate electrode structure has a second work function that is different from the first work function.

Various embodiments are directed to electrostatic discharge (ESD) protection apparatus comprising a bipolar junction transistor (BJT) having terminals, a field-effect transistor (FET) having terminals, and a common base region connected to a recombination region. The BJT and the FET are integrated with one another and include a common region that is shared by the BJT and the FET. The BJT and FET collectively bias the common base region and prevent triggering of the BJT by causing a potential of the common base region to follow a potential of one of the terminals of the BJT in response to an excessive but tolerable non-ESD voltage change at one or more of the terminals.

The present technology relates to a semiconductor integrated circuit which operates with a low voltage and is capable of preventing destruction of a protection circuit and a control method thereof. The semiconductor integrated circuit includes a resistance element and a capacitance element connected between a power supply line and a ground line in series, an inverter of which an input is connected between the resistance element and the capacitance element, a MOS transistor of which a gate electrode is connected to an output of the inverter and a drain electrode and a source electrode are respectively connected to the power supply line and the ground line, and a current limit element inserted between a well region where the MOS transistor is formed and the gate electrode. The present technology is applied to, for example, the protection circuit for preventing destruction of an internal circuit by ESD and the like.

A semiconductor device of the present invention achieves improved avoidance of a parasitic operation in a circuit region while achieving miniaturization of the semiconductor device and a reduction in the amount of time for manufacturing the semiconductor device. The semiconductor device according to the present invention includes an IGBT disposed on a first main surface of a semiconductor substrate provided with a drift layer of a first conductivity type; a thyristor disposed on the first main surface of the semiconductor substrate; a circuit region; a hole-current retrieval region separating the IGBT and the circuit region in a plan view; and a diffusion layer of a second conductivity type, the diffusion layer being disposed on a second main surface of the semiconductor substrate. The IGBT has an effective area equal to or less than an effective area of the thyristor in a plan view.

Techniques related to a boosted vertical field effect transistor and method of fabricating the same are provided. A logic device can comprise a vertical field effect transistor comprising a substrate, a first epitaxial layer and a second epitaxial layer. A bottom source/drain contact can be between a top surface and the first epitaxial layer and a top source/drain contact can be between the top surface and the second epitaxial layer at respective first portions of one or more vertical fins. The logic device can also comprise a boosted bipolar junction transistor. A bipolar junction transistor contact can be between the top surface and the second epitaxial layer at respective second portions of the one or more vertical fins. The respective first portions and the respective second portions can be opposite portions of the one or more vertical fins.

An apparatus comprises an antifuse cell comprising first and second nodes, an antifuse element, and a transistor. The antifuse element and the transistor are coupled in series between the first and second nodes. The antifuse element comprises an antifuse gate. The transistor comprises a transistor gate comprising a substantially-annular structure substantially surrounding the antifuse gate.

A microelectronic device having a functional metal oxide channel may be fabricated on a microelectronic substrate that can be utilized in very large scale integration, such as a silicon substrate, by forming a buffer transition layer between the microelectronic substrate and the functional metal oxide channel. In one embodiment, the microelectronic device may be a microelectronic transistor with a source structure and a drain structure formed on the buffer transition layer, wherein the source structure and the drain structure abut opposing sides of the functional metal oxide channel and a gate dielectric is disposed between a gate electrode and the functional metal oxide channel. In another embodiment, the microelectronic device may be a two-terminal microelectronic device.

A variable inductor which comprises a primary conductor, first and second secondary conductors and one or more switch. The primary conductor has a first node and a second node, wherein the first node is used to connect a first external component and the second node is used to connect a second external component. The first and second secondary conductors magnetically couple to the primary conductor. The one or more switch has two sides connected to the first or second secondary conductor, respectively. The first and second secondary conductors are formed a single-loop structure with two or more changeable current paths which are operated by the states of the one or more switch. An integrated circuit using the variable inductor is also introduced.

A device integrated with a depletion-mode junction field-effect transistor and a method for manufacturing the device. The device includes: a well region, which is of a second conduction type and formed within a first conduction region (214); a JFET source (210), which is of a first conduction type and formed within the well region; a metal electrode (212) of the JFET sources formed on the JFET sources (210), which is in contact with the JFET sources (210); a lateral channel region (208), which is of the first conduction type and formed between two adjacent JFET sources (210), while two ends thereof are in contact with the two adjacent JFET sources (210); and a JFET metal gate (213) formed on the well region.

An apparatus comprises an antifuse cell comprising first and second nodes, an antifuse element, and a transistor. The antifuse element and the transistor are coupled in series between the first and second nodes. The antifuse element comprises an antifuse gate. The transistor comprises a transistor gate comprising a substantially-annular structure substantially surrounding the antifuse gate.