The disclosed technology generally relates to electrical overstress protection devices, and more particularly to electrical overstress monitoring devices for detecting electrical overstress events in semiconductor devices. In one aspect, a device configured to monitor electrical overstress (EOS) events includes a pair of spaced conductive structures configured to electrically arc in response to an EOS event, wherein the spaced conductive structures are formed of a material and have a shape such that arcing causes a detectable change in shape of the spaced conductive structures, and wherein the device is configured such that the change in shape of the spaced conductive structures is detectable to serve as an EOS monitor.

The present disclosure relates to semiconductor structures and, more particularly, to a metal-free fuse structure and methods of manufacture. The structure includes: a first metal-free fuse structure comprising a top semiconductor material of semiconductor-on-insulator (SOI) technologies, the top semiconductor material including end portions with a first electrical resistance and a fuse portion of a second, higher electrical resistance electrically connected to the end portions; and a second metal-free fuse structure comprising the top semiconductor material of semiconductor-on-insulator (SOI) technologies, the top semiconductor material of the second metal-free fuse structure including at least a fuse portion of a lower electrical resistance than the second, higher electrical resistance.

A system and method for detecting and measuring electrostatic discharge during semiconductor assembly are described. A semiconductor device fabrication process forms a conductor between two metal routes in a series path on a semiconductor die. The series path is between a bump on the die and a substrate tie. The two metal routes have a width greater than a threshold based on a metal width capable of conducting a critical current density caused by an electrostatic discharge event without conductive failure or breakdown. The conductor has a width less than the threshold. When an electrostatic discharge event occurs, if the current exceeds a critical amount of current, the conductor experiences conductive breakdown and current ceases to flow. During later testing, this series path is tested for open connections, which indicate whether the conductor acting as an electrical on-die fuse experienced conductive failure during assembly of a semiconductor chip.

A semiconductor device having a fuse structure includes a region of semiconductor material having a major surface. A dielectric region is over the major surface. A first fuse terminal is over a first part of the dielectric region, a second fuse terminal is over a second part of the dielectric region and spaced apart from the first fuse terminal to provide a gap region, and a fuse body over a third part of the dielectric region interposed between and connected to the first fuse terminal and the second fuse terminal. A dummy structure is over the dielectric region in the gap region on a first side of the fuse body, the dummy structure spaced apart and electrically isolated from the fuse body, the first fuse terminal, and the second fuse terminal. The dummy structure is configured to reduce the presence of or reduce the effects of defects, such as cracks or voids that can emanate from the fuse structure.

Metal fuses and self-aligned gate edge (SAGE) architectures having metal fuses are described. In an example, an integrated circuit structure includes a plurality of semiconductor fins protruding through a trench isolation region above a substrate. A first gate structure is over a first of the plurality of semiconductor fins. A second gate structure is over a second of the plurality of semiconductor fins. A gate edge isolation structure is laterally between and in contact with the first gate structure and the second gate structure. The gate edge isolation structure is on the trench isolation region and extends above an uppermost surface of the first gate structure and the second gate structure. A metal fuse is on the gate edge isolation structure.

Interconnect structures and methods of fabricating an interconnect structure. A first interconnect and a second interconnect extend in a first direction in a interlayer dielectric layer and are spaced apart from each other. A third interconnect is arranged in the interlayer dielectric layer to connect the first interconnect with the second interconnect. The first interconnect and the second interconnect have a first width, and the third interconnect has a second width that is less than the first width.

The disclosed embodiments provide neural network inference accelerator based on one-time-programmable (OTP) memory arrays with one-way selectors. In some embodiments, a memory array may comprise: a plurality of one-time-programmable memory cells each comprising: a one-time-programmable memory element; a top electrode having an upper surface in contact with the one-time-programmable memory element; a dielectric layer in contact with a lower surface of the top electrode; a bottom electrode; and a dense layer having an upper surface in contact with the dielectric layer, and a lower surface in contact with the bottom electrode, wherein the dense layer comprises Al.sub.2O.sub.3 or MgO.

An electrical fuse (e-fuse) includes a fuse link including a silicided semiconductor layer over a dielectric layer covering a gate conductor. The silicided semiconductor layer is non-planar and extends orthogonally over the gate conductor. A first terminal is electrically coupled to a first end of the fuse link, and a second terminal is electrically coupled to a second end of the fuse link. The fuse link may be formed in the same layer as an intrinsic and/or extrinsic base of a bipolar transistor. The gate conductor may control a current source for programming the e-fuse. The e-fuse reduces the footprint and the required programming energy compared to conventional e-fuses.

The present disclosure provides a semiconductor device with air gaps between adjacent conductive lines and a method for forming the semiconductor device. The semiconductor device with air gaps between adjacent conductive lines and a method for forming the semiconductor device. The semiconductor device includes a first dielectric layer disposed over a semiconductor substrate, and a first electrode disposed over the first dielectric layer. The semiconductor device also includes a fuse link disposed over the first electrode, and a second electrode disposed over the fuse link. The semiconductor device further includes a third electrode disposed adjacent to the first electrode, and a second dielectric layer separating the first electrode from the first dielectric layer and the third electrode. The first electrode, the fuse link, and the second electrode form a fuse structure, and the first electrode, the third electrode, and a portion of the second dielectric layer between the first electrode and the third electrode form an anti-fuse structure.

An electronic fuse (e-fuse) module may be formed in copper interconnect in an integrated circuit device. A pair of e-fuse terminals may be formed by forming a pair of spaced-apart e-fuse terminal structures (e.g., copper damascene structures) and forming a conductive barrier region on each e-fuse terminal structure. The barrier regions may be formed by displacement plating a conductive barrier layer, e.g., comprising CoWP, CoWB, Pd, CoP, Ni, Co, or Ni—Co alloy, on each e-fuse terminal structure. An e-fuse element, e.g., comprising NiCr, TiW, TiWN, or Al, may be formed on the barrier regions of the pair of e-fuse terminals to define a conductive path between the pair of e-fuse terminal structures through the e-fuse element and through the barrier region on each e-fuse terminal structure. The barrier regions may protect the e-fuse terminal structures (e.g., copper structures) from corrosion and/or diffusion.