Abstract: The present disclosure relates to semiconductor structures and, more particularly, to vertically stacked diode-trigger silicon controlled rectifiers and methods of manufacture. The structure includes: a silicon controlled rectifier in a trap rich region of a semiconductor substrate; and at least one diode built in polysilicon (gate material) and isolated by a gate-dielectric.

Abstract: The present disclosure relates to semiconductor structures and, more particularly, to silicon control rectifiers and methods of manufacture. A structure includes: a first well in a semiconductor substrate; a second well in the semiconductor substrate, adjacent to the first well; a plurality of shallow trench isolation structures extending into the first well and the second well; and at least one gate structure in the first well which abuts one shallow trench isolation structure of the plurality of shallow trench isolation structures.

Abstract: The present disclosure relates to semiconductor structures and, more particularly, to low capacitance, low resistance devices and methods of manufacture. The structure includes: a semiconductor substrate; a device having an active region; and a porous semiconductor material within the semiconductor substrate and surrounding the active region of the device.

Abstract: The present disclosure relates to semiconductor structures and, more particularly, to electrostatic discharge (ESD) devices and methods of manufacture. The structure (ESD device) includes: a bipolar transistor comprising a collector region, an emitter region and a base region; and a lateral ballasting resistance comprising semiconductor material adjacent to the collector region.

Abstract: Embodiments of the disclosure provide an integrated circuit (IC) structure, including a triple well structure within a semiconductor substrate. A base region is within a doped well of the triple well structure, a collector terminal is within the doped well and laterally separated from the base region by a first insulator and a first avalanche junction is defined between a first pair of oppositely-doped semiconductor regions within the collector terminal. An emitter terminal is within the third doped well of the triple well structure and laterally separated from the collector terminal by a second insulator. A second avalanche junction is defined between a second pair of oppositely-doped semiconductor regions of the emitter terminal.

Abstract: A structure includes trigger control circuitry for an SCR including: a first transistor having two P-type semiconductor terminals connected to an Nwell and a Pwell of the SCR; a second transistor having two N-type semiconductor terminals connected to the Pwell and ground; and, optionally, an additional transistor having two P-type semiconductor terminals connected to the Nwell and ground. Control terminals of the transistors receive the same control signal (e.g., RST from a power-on-reset). When a circuit connected to the SCR for ESD protection is powered on, ESD risk is limited so RST switches to high. Thus, the first transistor and optional additional transistor turn off and the second transistor turns on, reducing leakage. When the circuit is powered down, the ESD risk increases so RST switches to low. Thus, the first transistor and optional additional transistor turn on and the second transistor turns off, lowering the trigger voltage and current.

Abstract: Disclosed is a semiconductor structure including a semiconductor substrate (e.g., a P-substrate) and a symmetric BDSCR. The BDSCR includes, within the substrate, a first well (e.g., a low-doped deep Nwell) and, within the first well, symmetric side sections and a middle section positioned laterally between the side sections. Each side section includes: second and third wells (e.g., Pwells), where the third well is shallower than and has a higher conductivity level than the second well. Each middle section includes multiple floating wells including: two fourth wells (e.g., Nwells), which have a higher conductivity level than the first well, and a fifth well (e.g., another Pwell), which is positioned laterally between and shallower than the fourth wells. By incorporating the floating wells into the middle section, high current tolerance is improved.

Abstract: The disclosure provides a structure including an n-type well over an n-type deep well and between a pair of p-type wells for electrostatic discharge (ESD) protection. The structure may include a p-type deep well over a substrate, a first n-type well over the p-type deep well, and a pair of p-type wells over the p-type deep well. The pair of p-type wells are each adjacent opposite horizontal ends of the n-type well. A pair of second n-type wells are over the p-type deep well and adjacent one of the pair of p-type wells. Each p-type well is horizontally between the first n-type well and one of the second n-type wells.

Abstract: A structure includes: an electrically programmable fuse (e-fuse) including an anode and a cathode; at least one transistor positioned adjacent the e-fuse; and an electrically conductive interconnect coupling the cathode of the e-fuse to the at least one transistor, wherein the at least one transistor includes at least one semiconductor fin extending perpendicularly to the e-fuse.

Abstract: Structures for an electrostatic discharge protection device and methods of forming same. The structure comprises a first well and a second well in the semiconductor substrate. The first and second wells have a first conductivity type. The structure further comprises a third well and a fourth well in the semiconductor substrate. The third and fourth wells have a second conductivity type, the third well includes a portion that overlaps with the first well, and the fourth well includes a portion that overlaps with the second well.

Abstract: The disclosure provides a structure with a buried doped region, and methods to form the same. A structure may include a semiconductor substrate including a first well. A first terminal includes a first doped region in the first well. A second terminal includes a second doped region in the first well. The first well horizontally separates the first doped region from the second doped region. A first buried doped region is in the first well. The first buried doped region overlaps with, and is underneath, the first doped region. The first well vertically separates the first doped region from the first buried doped region.

Abstract: Disclosed are embodiments of a semiconductor structure that includes a semiconductor-controlled rectifier (e.g., for electrostatic discharge (ESD) protection). The SCR can be readily integrated into advanced semiconductor-on-insulator processing technology platforms (e.g., a fully depleted silicon-on-insulator (FDSOI) processing technology platform) that employ hybrid semiconductor substrates (i.e., semiconductor substrates with both bulk semiconductor and semiconductor-on-insulator regions) and is configured with an on-Pwell semiconductor-on-insulator gate structure that is tied to an anode terminal to effectively lower the SCR trigger voltage. To further lower the trigger voltage of the SCR, the Pwell on which the gate structure sits may be made narrower than the gate structure and/or the doping profile of the Pwell on which the gate structure sits may be graded (e.g., P to P? closer to insulator layer).

Abstract: The present disclosure relates to a structure including a trigger element within a semiconductor-on-insulator (SOI) substrate, and a silicon controlled rectifier (SCR) under a buried insulator layer of the SOI substrate. The trigger element is between an anode and a cathode of the SCR.

Abstract: Structures for a silicon-controlled rectifier and methods of forming a structure for a silicon-controlled rectifier. The structure comprises a semiconductor substrate, a dielectric layer on the semiconductor substrate, and a first well and a second well in the semiconductor substrate beneath the dielectric layer. The first well has a first conductivity type, the second well has a second conductivity type opposite to the first conductivity type, and the second well adjoins the first well along a p-n junction. The structure further comprises a first terminal and a second terminal above the dielectric layer, a first connection extending through the dielectric layer from the first terminal to the first well, and a second connection extending through the dielectric layer from the second terminal to the second well.

Abstract: Device structures including a silicon-controlled rectifier and methods of forming a device structure including a silicon-controlled rectifier. The device structure comprises a first well and a second well in a semiconductor substrate, a first terminal including a first doped region in the first well, and a second terminal including a second doped region in the second well. The first well and the second doped region have a first conductivity type, and the second well and the first doped region have a second conductivity type opposite from the first conductivity type. The second well adjoins the first well along an interface. A third doped region includes a first portion in the first well and a second portion in the second well, and a gate structure that overlaps with a portion of the second well.

Abstract: Embodiments of the disclosure provide a semiconductor controlled rectifier (SCR) structure and methods to form the same. The SCR structure may include a first polycrystalline semiconductor material on a first insulator and includes a first well therein. A monocrystalline semiconductor material is adjacent the first polycrystalline semiconductor material and includes an anode region and a cathode region therein. A second polycrystalline semiconductor material is on a second insulator and includes a second well therein.

Abstract: Embodiments of the disclosure provide an integrated circuit (IC) structure with a diode over a lateral bipolar transistor. A structure according to the disclosure may include a lateral bipolar transistor within a monocrystalline semiconductor over a substrate. An insulator layer is over a portion of the monocrystalline semiconductor. A diode is within a polycrystalline semiconductor on the insulator layer. A cathode of the diode is coupled to a first well within the monocrystalline semiconductor. The first well defines one of an emitter terminal and a collector terminal of the lateral bipolar transistor.

Abstract: Structures for a silicon-controlled rectifier and methods of forming a structure for a silicon-controlled rectifier. The structure comprises a first well and a second well in a semiconductor substrate, a first terminal including a first doped region in the first well, and a second terminal including a second doped region in the second well. The first well, the second well and the first doped region have a first conductivity type, and the second doped region has a second conductivity type opposite to the first conductivity type. The structure further comprises a deep well in the semiconductor substrate. The deep well has the second conductivity type, the first well is positioned in a vertical direction between the deep well and the top surface of the semiconductor substrate, and the second well is positioned in the vertical direction between the deep well and the top surface of the semiconductor substrate.

Abstract: An electrostatic discharge (ESD) protection device including: a substrate including: a first, second and third doped regions, the second doped region disposed between the first and third doped regions, the second doped region has a first conductivity type and a first doping concentration and the first and third doped regions have a second conductivity type and a second doping concentration; first and second doped terminal regions disposed within the first and second doped regions, respectively; and a doped island region disposed within the second doped region, the first and second doped terminal regions and doped island region have the second conductivity type and a third doping concentration, the third doping concentration higher than the first and second doping concentrations; and conductive terminals respectively coupled to the doped terminal regions; and an insulation layer arranged on the substrate between the conductive terminals and covering at least the second doped region.

Abstract: A structure includes trigger control circuitry for an SCR including: a first transistor having two P-type semiconductor terminals connected to an Nwell and a Pwell of the SCR; a second transistor having two N-type semiconductor terminals connected to the Pwell and ground; and, optionally, an additional transistor having two P-type semiconductor terminals connected to the Nwell and ground. Control terminals of the transistors receive the same control signal (e.g., RST from a power-on-reset). When a circuit connected to the SCR for ESD protection is powered on, ESD risk is limited so RST switches to high. Thus, the first transistor and optional additional transistor turn off and the second transistor turns on, reducing leakage. When the circuit is powered down, the ESD risk increases so RST switches to low. Thus, the first transistor and optional additional transistor turn on and the second transistor turns off, lowering the trigger voltage and current.