A method is provided for fabricating an electrostatic discharge (ESD) protection structure. The method includes forming a substrate having a first region and a second region, wherein the first region and the second region have a preset distance; forming a well area in the substrate; forming a first fin portion in the substrate in the first region and a second fin portion in the substrate in the second region; forming a supporting gate structure, wherein the supporting gate structure includes a first supporting gate crossing the first fin portion and a second supporting gate crossing the second fin portion; forming a dielectric layer on the well area; and forming a conductive structure in the dielectric layer, wherein the conductive structure includes a first conductive structure connecting to the first fin portion and a second conductive structure connecting to the second fin portion.

An apparatus for anticipating a transistor-fault includes a control circuit that applies a blocking potential of a transistor to its gate using a resistive component, the blocking potential being less than the source and drain potentials. The detection circuit detects a leakage current between the transistor's gate and its source to anticipate a short circuit between them. It does so by measuring the gate-potential while the transistor is blocked. It then compares this measured potential to a reference potential and generates an anomaly signal as a function of this comparison.

Apparatus and methods for electrical overstress (EOS) protection circuits are provided herein. In certain configurations, an EOS protection circuit includes an overstress sensing circuit electrically connected between a pad and a first supply node, an impedance element electrically connected between the pad and a signal node, a controllable clamp electrically connected between the signal node and the first supply node and selectively activatable by the overstress sensing circuit, and an overshoot limiting circuit electrically connected between the signal node and a second supply node. The overstress sensing circuit activates the controllable clamp when an EOS event is detected at the pad. Thus, the EOS protection circuit is arranged to divert charge associated with the EOS event away from the signal node to provide EOS protection.

Methods of forming 3-D ICs with integrated passive devices (IPDs) include stacking separately prefabricated substrates coupled by through-substrates-vias (TSVs). An active device (AD) substrate has contacts on its upper portion. An isolator substrate is bonded to the AD substrate so the TSVs in the isolator substrate are coupled to the contacts on the AD substrate. An IPD substrate is bonded to the isolator substrate so that TVs therein are coupled to an interconnect zone on the isolator substrate and/or TSVs therein. The IPDs of the IPD substrate are coupled by TSVs in the IPD and isolator substrates to devices in the AD substrate. The isolator substrate provides superior IPD to AD cross-talk attenuation while permitting each substrate to have small high aspect ratio TSVs, thus facilitating high circuit packing density and efficient manufacturing.

An array substrate and a display panel are provided. The array substrate includes a transparent substrate including a display area and a rim area; a pixel structure and an antistatic switching tube which are arranged on a same side of the transparent substrate. The pixel structure includes a pixel thin-film transistor located in the display area, and the antistatic switching tube is located in the rim area. The pixel structure also includes first grounding wire located on a side of the antistatic switching tube facing away from the transparent substrate, and a second grounding wire located between the antistatic switching tube and the transparent substrate.

A device is disclosed that includes a first transistor, a second transistor, and a first PODE device. The second transistor is electrically coupled to the first transistor. The first PODE device is adjacent to a drain/source region of the second transistor. A control end of the first PODE device is electrically coupled to a drain/source end of the second transistor.

The present disclosure relates to an array substrate, a display panel and a display device. The array substrate includes GND wirings and GOA areas. The GND wirings are configured at outer sides of the GOA areas, and the GOA area includes a variety of GOA signal lines and N-th stage GOA circuits electrically connected by the GOA signal lines. A first ESD protection circuit is configured in a middle area between the 1-th stage GOA circuit and the N-th stage GOA circuit to discharge abnormal electrical charges of the GOA signal lines within the middle area. With such configuration, better ESD protection capability is provided between the GOA signal lines.

A system includes a carrier defining a plurality of channels. The system includes an integrated circuit (IC) die having a first side and having a second side opposite the first side. The second side of the IC die is coupled to the carrier. The system includes a die attach layer between the carrier and the second side of the IC die. The die attach layer defines one or more openings that enable a fluid to flow from the carrier to the second side of the IC die.

Semiconductor structure and methods for fabricating the same are provided. An example semiconductor structure includes a bulk substrate having a top surface and a silicon-on-insulator (SOI) substrate merged in the bulk substrate. The SOI substrate further includes a heavily doped layer, an insulating layer disposed on and surrounded by the heavily doped layer, and an active substrate disposed on and surrounded by the insulating layer. The semiconductor structure further includes one or more semiconductor devices disposed in the active substrate, a peripheral heavily doped region connected to the heavily doped layer, and a discharging metal structure electrically interconnecting the semiconductor devices to the peripheral heavily doped region.

Various embodiments of the present application are directed towards an integrated circuit (IC) in which a shield structure blocks the migration of charge to a semiconductor device from proximate a through substrate via (TSV). In some embodiments, the IC comprises a substrate, an interconnect structure, the semiconductor device, the TSV, and the shield structure. The interconnect structure is on a frontside of the substrate and comprises a wire. The semiconductor device is on the frontside of the substrate, between the substrate and the interconnect structure. The TSV extends completely through the substrate, from a backside of the substrate to the wire, and comprises metal. The shield structure comprises a PN junction extending completely through the substrate and directly between the semiconductor device and the TSV.