A high-voltage circuitry device is provided. The high-voltage circuitry device includes a high-voltage transistor, a protection component and a feedback component. The high-voltage transistor has a gate, a drain and a source. The protection component is coupled between the source of the high-voltage transistor and the ground. When a current corresponding to an electrostatic discharge (ESD) event flows through the drain of the high-voltage transistor, the current flows from the drain of the high-voltage transistor to the ground through the high-voltage transistor and the protection component. The feedback component is coupled between the protection component, the ground and the gate of the high-voltage transistor. When the ESD event occurs, the feedback component enables the high-voltage transistor to stay on a turned-on state to pass the current.

This disclosure relates to semiconductor devices, and, more particularly, to a semiconductor structure that improves the switching speed of a switch for which the turn-off process depends on the recombination speed of charge carriers. The disclosure describes a semiconductor device formed on a semiconductor substrate that includes a power semiconductor switch having a drift region in the semiconductor substrate, an Extraction Plug in electrical contact with the drift region of the power semiconductor switch, and an extraction device electrically coupled to the Extraction Plug. The extraction device is structured to remove charge carriers from the drift region through the Extraction Plug when the extraction device is turned on. Methods are also described.

A semiconductor device is provided. The semiconductor device comprises a substrate of a first type, a first doped region embedded within the substrate and having a first portion and a second portion, and a first gate electrode disposed above the substrate. The semiconductor device further comprises a well region of a second type and embedded within the substrate. The well region is in contact with the second portion of the first doped region.

A control circuit applied in a specific element and including a first transistor and an electrostatic discharge (ESD) protection circuit is provided. The specific element has a III-V semiconductor material and includes a control electrode, a first electrode and a second electrode. The first transistor is coupled between the first electrode and the second electrode and has the III-V semiconductor material. The ESD protection circuit is coupled to the control electrode, the first transistor and the second electrode. In response to an ESD event, the ESD protection circuit provides a discharge path to release the ESD current from the control electrode to the second electrode.

A semiconductor integrated circuit device may include a pad, a first voltage protection unit and a second voltage protection unit. The first voltage protection unit may be connected with the pad. The first voltage protection unit may be configured to maintain a turn-off state when a test voltage having a negative level may be applied from the pad. The second voltage protection unit may be connected between the first voltage protection unit and a ground terminal. The second voltage protection unit may be turned-on when an electrostatic voltage having a positive level may be applied from the pad. The second voltage protection unit may include a plurality of gate positive p-channel metal oxide semiconductor (GPPMOS) transistors serially connected with each other.

A dual mode snap back circuit device is disclosed. The dual mode snap back device may be used for electrostatic discharge (ESD) protection, and may provide both positive ESD protection and negative ESD protection. The dual mode snap back device may implement both an n-type metal-oxide-semiconductor (NMOS) transistor (e.g., a gate-grounded NMOS transistor, such as a gate-grounded extended drain NMOS (GGEDNMOS) transistor) to provide protection against positive ESD events and a bipolar junction transistor (BJT) (e.g., a PNP BJT) to provide protection against negative ESD events. Other embodiments may be described and claimed.

The present disclosure relates to a semiconductor device, including a first source/drain region, a second source/drain region, a base region, a first electrostatic discharge region and a second electrostatic discharge region. The first source/drain region and the second source/drain region are configured to receive a first power voltage and a second power voltage, and are formed on the base region. The first electrostatic discharge region includes a first doped region and a first well. The first doped region is configured to receive the second power voltage, and formed in the first well. The second electrostatic discharge region includes a second doped region and a second well. The second doped region is configured to receive the first power voltage, and formed in the second well. The first source/drain region and the second source/drain region are disposed between the first electrostatic discharge region and the second electrostatic discharge region.

A semiconductor device includes a substrate having a semiconductor surface doped a second dopant type with a buried layer (BL) doped a first dopant type. First, second and third well regions doped the second dopant type are on top of the BL. Second doped regions doped the first dopant type on top of and contacting the BL arraigned as a first well ring and second well ring are around the first and third well regions respectively. At least one high-injection component including the first well region is surrounded by the first well ring. At least one component including the third well region is surrounded by the second well ring. An npn or pnp guard wall pocket including a wall of the first and second well rings, and the second well region is between the high-injection component and the component.

An electrostatic-discharge (ESD) protection circuit is provided. The circuit includes an I/O terminal coupled for receiving a signal having a negative voltage relative to a voltage supply terminal. An ESD transistor is formed in an isolated well. The transistor includes a control electrode and a first current electrode coupled to the I/O terminal. The isolated well is configured as a body electrode of the transistor. An ESD diode includes an anode electrode coupled to the voltage supply terminal and a cathode electrode coupled to a second current electrode of the transistor.

Voltage clamping and level shifting is provided. A first reverse direction high-electron-mobility transistor includes a source connected to an input pad, and a drain connected to a first reference voltage. A second reverse direction high-electron-mobility transistor includes a source and a gate connected to a second reference voltage, and a drain connected to the input pad. A gate of the first reverse direction high-electron-mobility transistor is connected to the second reference voltage. Level shifting is provided by an arrangement of three high-electron-mobility transistor and a resistive element