An anti-static metal oxide semiconductor field effect transistor structure includes an anti-static body structure and a slave metal oxide semiconductor field effect transistor, the anti-static body structure includes: a main metal oxide semiconductor field effect transistor; a first silicon controlled rectifier, an anode thereof being connected to a drain of the main metal oxide semiconductor field effect transistor, a cathode and a control electrode thereof being connected to a source of the main metal oxide semiconductor field effect transistor; and a second silicon controlled rectifier, an anode thereof being connected to the drain of the main metal oxide semiconductor field effect transistor, a cathode thereof being connected to a gate of the main metal oxide semiconductor field effect transistor, a control electrode thereof being connected to the source or the gate of the main metal oxide semiconductor field effect transistor.

Electrical overstress protection for high speed interfaces are disclosed. In certain embodiments, a semiconductor die with bidirectional protection against electrical overstress is provided. The semiconductor die includes a first pad, a second pad, a forward protection silicon controlled rectifier (SCR) electrically connected between the first pad and the second pad and configured to activate in response to electrical overstress that increases a voltage of the first pad relative to a voltage of the second pad, and a reverse protection SCR electrically connected in parallel with the forward protection SCR between the first pad and the second pad and configured to activate in response to electrical overstress that decreases the voltage of the first pad relative to the voltage of the second pad.

Fin field-effect transistor (FinFET) thyristors for protecting high-speed communication interfaces are provided. In certain embodiments herein, high voltage tolerant FinFET thyristors are provided for handling high stress current and high RF power handling capability while providing low capacitance to allow wide bandwidth operation. Thus, the FinFET thyristors can be used to provide electrical overstress protection for ICs fabricated using FinFET technologies, while addressing tight radio frequency design window and robustness. In certain implementations, the FinFET thyristors include a first thyristor, a FinFET triggering circuitry and a second thyristor that serves to provide bidirectional blocking voltage and overstress protection. The FinFET triggering circuitry also enhances turn-on speed of the thyristor and/or reduces total on-state resistance.

An ESD protection device includes a semiconductor body having an upper surface, a plurality of p-type wells that each extend from the upper surface into the semiconductor body, a plurality of n-type wells that each extend from the upper surface into the semiconductor body, first isolation regions comprising an electrical insulator that laterally surrounds the p-type wells and extends from the upper surface into the semiconductor body at least as deep as the p-type wells, and second isolation regions comprising an electrical insulator that laterally surrounds the n-type wells and extends from the upper surface into the semiconductor body at least as deep as the n-type wells, wherein the p-type wells and the n-type wells alternate with one another a first direction, and wherein an isolating area of the first isolation regions is greater than an isolating area of the second isolation regions.

An electrostatic discharge protection device including a substrate, a first PNP element, a second PNP element, and an isolation region is provided. The substrate has a P-type conductivity. The first and second PNP elements are formed in the substrate. The isolation region isolates the first and second PNP elements.

Electrical overstress protection for high speed interfaces are disclosed. In certain embodiments, a semiconductor die with bidirectional protection against electrical overstress is provided. The semiconductor die includes a first pad, a second pad, a forward protection silicon controlled rectifier (SCR) electrically connected between the first pad and the second pad and configured to activate in response to electrical overstress that increases a voltage of the first pad relative to a voltage of the second pad, and a reverse protection SCR electrically connected in parallel with the forward protection SCR between the first pad and the second pad and configured to activate in response to electrical overstress that decreases the voltage of the first pad relative to the voltage of the second pad.

A semiconductor device includes a thyristor disposed in a semiconductor body. The thyristor has an anode, a cathode, a first bipolar transistor located on an anode side, and a second bipolar transistor located on a cathode side. The first and second bipolar transistors are nested and connected between the anode and the cathode. A MOS transistor is disposed in the semiconductor body. The MOS transistor is coupled between a collector region and an emitter region of the second bipolar transistor. The MOS transistor has a gate region connected to the cathode via a resistive semiconductor region that incorporates at least a part of a base region of the second bipolar transistor.

A semiconductor structure for a DRAM is described having multiple layers of arrays of thyristor memory cells and associated peripheral circuitry. Memory cells in a vertical string extending through the layers have an electrical connection to one terminal of the memory cells in that string. Word lines couple the strings together. Each layer of the array also includes bit line connections to memory cells on that layer. Methods of fabricating the array are described.

An integrated circuit includes a T-coil circuit, a silicon-controlled rectifier (SCR), and a signal-loss prevention circuit. The T-coil circuit is coupled to an input/output (I/O) pad and an internal circuit. The SCR is coupled to the T-coil circuit and the internal circuit. The signal-loss prevention circuit is coupled to the T-coil circuit and the SCR. The signal-loss prevention circuit includes a resistor coupled to the T-coil circuit and the SCR. An electrostatic current flows through the resistor and turns on the SCR. The signal-loss prevention circuit may also include a diode circuit coupled to the T-coil circuit and the SCR. The diode circuit is configured to prevent signal loss.

A thyristor tile includes first and second PNP tiles and first and second NPN tiles. Each PNP tile is adjacent to both NPN tiles, and each NPN tile is adjacent to both PNP tiles. A thyristor includes a plurality of PNP tiles and a plurality of NPN tiles. The PNP and NPN tiles are arranged in an alternating configuration in both rows and columns. The PNP tiles are oriented perpendicular to the NPN tiles. Interconnect layers have a geometry that enables even distribution of signals to the PNP and NPN tiles.