A fusible structure includes: a metal line in a first metal layer extending along a first direction; and a first dummy structure disposed proximal to the metal line relative to a second direction, the second direction being perpendicular to the first direction, the first dummy structure being in a second metal layer. Relative to the first direction, the metal line includes first, second and third portions, the second portion being between the first portion and third portion. Relative to a third direction that is perpendicular to the first direction and the second direction, the first portion has a first thickness and the second portion has a second thickness, the first thickness being greater than the second thickness.

The present disclosure relates to an electrical fuse (e-fuse) device and a method for forming the electrical fuse device. The vertical e-fuse device includes a fuse link disposed over a semiconductor base. A material of the fuse link and a material of the semiconductor base are the same. The vertical e-fuse device also includes a first bottom anode/cathode region and a second bottom anode/cathode region disposed over the semiconductor base. A bottom portion of the fuse link is sandwiched between the first bottom anode/cathode region and the second anode/cathode region. The vertical e-fuse device further includes a top anode/cathode region disposed over the fuse link.

A method of forming a storage cell includes: forming a transistor on a semiconductor substrate; forming a plurality of fuses in at least one conductive layer on the semiconductor substrate to couple a connecting terminal of the transistor; forming a bit line to couple the plurality of fuses; and forming a word line to couple a control terminal of the transistor.

The present disclosure provides a semiconductor structure employing an antifuse structure and a controlling method of the semiconductor structure. The semiconductor structure includes a semiconductor substrate, a transistor and an antifuse structure. The transistor is disposed on the semiconductor substrate. The antifuse structure is disposed on the semiconductor substrate and adjacent to the transistor. The antifuse structure includes a first conductive portion, a fusible portion and a second conductive portion. The first conductive portion is disposed in the semiconductor substrate. The fusible portion is disposed on the first conductive portion. The second conductive portion is disposed on the fusible portion. The antifuse structure encloses the transistor in a top view.

A semiconductor wafer includes first zones containing integrated circuits, each first zone including a substrate and a sealing ring at a periphery of the substrate. The first zones are separated from each other by second zones defining cutting lines or paths. The integrated circuit includes an electrically conductive fuse that extends between a first location inside the integrated circuit and a second location situated outside the integrated circuit beyond one of the cutting lines. This electrically conductive fuse includes a portion that passes through the sealing ring and another portion that straddles the adjacent cutting line. The portion of the fuse that passes through is electrically isolated from the sealing ring and from the substrate. The straddling portion is configured to be sliced, when cutting the wafer along the cutting line, so as to cause the fuse to change from an electrical on state to an electrical off state.

Disclosed herein are integrated circuit (IC) components with dummy structures, as well as related methods and devices. For example, in some embodiments, an IC component may include a dummy structure in a metallization stack. The dummy structure may include a dummy material having a higher Young's modulus than an interlayer dielectric of the metallization stack.

An electronic device, e.g. a trimmable resistor, includes a plurality of fused resistors, each fused resistor including one or more doped resistive regions formed in a semiconductor substrate. The doped resistive regions may be thermistors. Each fused resistor further includes a corresponding one of a plurality of fusible links. A first terminal of each of the fused resistors is connected to a first terminal of the corresponding fusible link. First and second interconnection buses are located over the substrate, with the first interconnection bus connecting to a second terminal of each of the fused resistors, and the second interconnection bus connecting to a second terminal of each of the fusible links. The plurality of fused resistors have resistance values that form an exponential progression.

A multi-fuse memory cell is disclosed. The circuit includes: a first fuse element electrically coupled to a first transistor, a gate of the first transistor is electrically coupled to a first selection signal; a second fuse element electrically coupled to a second transistor, a gate of the second transistor is electrically coupled to a second selection signal, both the first transistor and the second transistor are grounded; and a programming transistor electrically coupled to the first fuse element and the second fuse element, wherein a gate of the programming transistor is electrically coupled to a programming signal.

A semiconductor layout structure includes a substrate, a plurality of gate structures, and a plurality of conductive structures. The substrate includes a plurality of active regions extending along a first direction, in which the active regions are separated from each other by an isolation structure. The transistors are respectively disposed in the active regions. The gate structures extend across the active regions along a second direction that is perpendicular to the first direction, in which each of the active regions includes a pair of source/drain portions at opposite sides of each of the gate structures. The conductive structures are embedded in a first portion of the isolation structure disposed between the adjacent active regions in the first direction, wherein the conductive structures extend along the second direction and are separated from the source/drain portions by the isolation structure.

An interposer circuit includes a substrate and a dielectric layer that is disposed on top of the substrate. The interposer circuit includes two or more connection layers including a first connection layer and a second connection layer that are disposed at different depths in the dielectric layer. The interposer circuit includes a fuse that is disposed in the first connection layer. The first connection layer is coupled to a first power node and the second connection layer is coupled to a first ground node. The interposer circuit further includes a first capacitor that is in series with the fuse and is connected between the first and the second connection layers. The interposer circuit also includes first, second, and third micro-bumps on top of the dielectric layer such that the fuse is coupled between the first and second micro-bumps and the first capacitor is coupled between the second and third micro-bumps.