Field effect diode structures utilize a junction structure that has an L-shape in cross-section (a fin extending from a planar portion). An anode is positioned at the top surface of the fin, and a cathode is positioned at the end surface of the planar portion. The perpendicularity of the fin and the planar portion cause the anode and cathode to be perpendicular to one another. A first gate insulator contacts the fin between the top surface and the planar portion. A first gate conductor contacts the first gate insulator, and the first gate insulator is between the first gate conductor and the surface of the fin. Additionally, a second gate insulator contacts the planar portion between the end surface and the fin. A second gate conductor contacts the second gate insulator, and the second gate insulator is between the second gate conductor and the surface of the planar portion.

A semiconductor device includes semiconductor fins on semiconductor strips on a substrate. The semiconductor fins are parallel to each other. A gate stack is over the semiconductor fins, and a drain epitaxy semiconductor region is disposed laterally from a side of the gate stack and on the semiconductor strips. A first dielectric layer is over the substrate, and the first dielectric layer has a first metal layer. A second dielectric layer is over the first dielectric layer, and the second dielectric layer has a second metal layer. Vias extend from the second metal layer and through the first dielectric layer, and the vias are electrically coupled to the drain epitaxy semiconductor region.

The present disclosure provides an array substrate and a display apparatus. The array substrate comprises at least two groups of signal lines, a common electrode line and at least two common electrode sub-lines, at least one signal line of one group of the at least two groups of signal lines is connected to one common electrode sub-line of the at least two common electrode sub-lines via a first electrostatic discharge circuit, at least one signal line of another group of the at least two groups of signal lines is connected to another common electrode sub-line of the at least two common electrode sub-lines via a second electrostatic discharge circuit, each common electrode sub-line is respectively connected to the common electrode line via a third electrostatic discharge circuit.

The present application belongs to field of integrated circuit and discloses an electrostatic discharge protection circuit comprising a first N-type transistor and a second N-type transistor. The first N-type transistor comprises a first gate terminal coupled to a ground terminal; a first electrode terminal coupled to the first gate terminal; and a second electrode terminal. The second N-type transistor comprises a second gate terminal coupled to a metal pad; a third electrode terminal coupled to the second gate terminal; a fourth electrode terminal, coupled to the second electrode terminal; and a first deep N well, disposed under the third electrode terminal and the fourth electrode terminal. The ESD protection circuits provided by the embodiments of the present application have advantages of small circuit area and good ESD protection.

The present invention provides an embedded high voltage LDMOS-SCR device with strong voltage clamp and ESD robustness, which can be used as the on-chip ESD protection for high voltage IC. Wherein said the device comprises a P substrate, a P well, a N well, a first field oxide isolation region, a first P+ injection region, a second field oxide isolation region, a first N+ injection region, a first fin polysilicon gate, a second N+ injection region, a second fin polysilicon gate, a third N+ injection region, a third fin polysilicon gate, a polysilicon gate, a fourth fin polysilicon gate, a second P+ injection region, a fifth fin polysilicon gate, a third P+ injection region, a sixth fin polysilicon gate, a fourth P+ injection region, a third oxygen isolation region, a fourth N+ injection region and a fourth field oxygen isolation region. Under the influence of ESD pulse, the ESD discharge current path with LDMOS-SCR structure and the RC coupling current path with embedded PMOS interdigital structure in the drain terminal and embedded NMOS interdigital structure in the source terminal are formed, in order to enhance the ESD robustness of the device and improve the voltage clamp capability.

A static electricity prevention circuit of a display device including: a driving circuit configured to drive a display unit that displays an image, at least one clock signal wire configured to transmit a clock signal to the driving circuit, at least one transistor electrically coupled to the clock signal wire, and at least one capacitor including a first electrode coupled to a source electrode and to a drain electrode of the transistor, and a second electrode configured to be maintained at a voltage.

A semiconductor device includes a floating buried doped region, a first doped region disposed between the floating buried doped region and a first major surface, and a semiconductor region disposed between the floating buried doped region and a second major surface. Trench isolation portions extend from the first major surface and terminate within the semiconductor region to define an active region. An insulated trench structure is laterally disposed between the trench isolation portions, terminates within the floating buried doped region, and defines a first portion and a second portion of the active region. A biasing semiconductor device is within the first portion, and a functional semiconductor device is within the second portion. The biasing semiconductor device is adapted to set a potential of the floating buried doped region and adapted to divert parasitic currents away from the functional semiconductor device.

An electrostatic discharge (ESD) protection structure that provides snapback protections to one or more high voltage circuit components. The ESD protection structure can be integrated along a peripheral region of a high voltage circuit, such as a high side gate driver of a driver circuit. The ESD protection structure includes a p-channel device and an n-channel device. The p-channel device includes an n-type barrier region circumscribing a p-type drain region with an n-type body region. The p-channel device may be positioned adjacent to the n-channel device and a high voltage junction diode.

A method is applied to reconfigure a set of uncrowned standard cells in a layout of a semiconductor apparatus. Each uncrowned standard cell includes a standard first array. Each standard first array includes a first stacked arrangement of vias interspersed with first segments of corresponding M(i)M(N) metallization layers. The M(N) metallization layer includes second segments which connect corresponding first segments of the M(N) metallization layer in the first standard arrays. The method includes crowning each first standard array in the set with a corresponding second standard array, the latter including a second stacked arrangement of vias interspersed with corresponding first segments of corresponding M(N+1)M(N+Q) metallization layers. The crowning includes disposing vias in a VIA(N+1) layer so as to be substantially collinear (relative to a first direction), and not substantially collinear (relative to a substantially perpendicular second direction), with corresponding vias in the VIA(N) layer.

A semiconductor device includes a MOS transistor which is coupled between two terminals and discharges current which flows caused by generation of static electricity and a diode which is coupled between a back gate of the MOS transistor and one of the terminal and has a polarity which is reversed to the polarity of a parasitic diode which is formed between the back gate and a source of the MOS transistor.