This description relates generally to semiconductor devices. A semiconductor device can include first and second conductive layers that can be positioned over a substrate, and at least one dielectric layer between the first and second conductive layers. The at least one dielectric layer can be positioned over at least a portion of the second conductive layer, and the first conductive layer can be positioned over a portion of the least one dielectric layer. The semiconductor device can further include a third conductive layer that can be positioned over the substrate and can be conductively connected to the second conductive layer and the substrate. The third conductive layer includes a fusible link.

Embodiments herein describe techniques for fuse lines and plugs formation. A semiconductor device may include a fuse line having a nominal fuse segment abutted to a necked fuse segment. The nominal fuse segment may be wider than the necked fuse segment. A first spacer may be along a first side of the fuse line and a second spacer along a second side opposite to the first side of the fuse line. The first spacer may include a part having a width at least twice a width of a part of the second spacer. A plug within a vicinity of the necked fuse segment may have a plug width that may be at least twice a plug with of a plug of an interconnect line outside the vicinity. Other embodiments may also be described and claimed.

A semiconductor device with a fuse component is provided. The semiconductor device includes a substrate having an active region; a fuse dielectric layer disposed in the active region; and a gate metal layer disposed in the active region and surrounded by the fuse dielectric layer. The he gate metal layer is configured to receive a voltage to change a resistivity between the gate metal layer and the active region.

An electronic fuse (e-fuse) module may be formed in an integrated circuit device. The e-fuse module may include a pair of metal e-fuse terminals (e.g., copper terminals) and an e-fuse element formed directly on the metal e-fuse terminals to define a conductive path between the pair of metal e-fuse terminals through the e-fuse element. The metal e-fuse terminals may be formed in a metal interconnect layer, along with various interconnect elements of the integrated circuit device. The e-fuse element may be formed by depositing and patterning a diffusion barrier layer over the metal e-fuse terminals and interconnect elements formed in the metal interconnect layer. The e-fuse element may be formed from a material that provides a barrier against metal diffusion (e.g., copper diffusion) from each of the metal e-fuse terminals and interconnect elements. For example, the e-fuse element may be formed from titanium tungsten (TiW) or titanium tungsten nitride (TiW.sub.2N).

An integrated circuit includes a front-side horizontal conducting line in a first metal layer, a front-side vertical conducting line in a second metal layer, a front-side fuse element, and a backside conducting line. The front-side horizontal conducting line is directly connected to the drain terminal-conductor of a transistor through a front-side terminal via-connector. The front-side vertical conducting line is directly connected to the front-side horizontal conducting line through a front-side metal-to-metal via-connector. The front-side fuse element having a first fuse terminal conductively connected to the front-side vertical conducting line. The backside conducting line is directly connected to the source terminal-conductor of the transistor through a backside terminal via-connector.

A solid-state fuse device includes a switch a gate driver connected to the switch and configured to transition the switch from a closed state to an open state when at least one of an overcurrent measurement exceeds a predetermined overcurrent threshold or a voltage drop across the switch exceeds a predetermined saturation voltage threshold.

In one aspect of the present disclosure, a semiconductor device is disclosed. In some embodiments, the semiconductor device includes a first conductive structure extending in a first direction, the first conductive structure coupled to a metal-oxide-semiconductor (MOS) device; a second conductive structure extending in the first direction and spaced from the first conductive structure in a second direction perpendicular to the first direction; a dielectric material extending in the second direction and disposed over, in a third direction perpendicular to the first direction and the second direction, the first conductive structure; and a via structure disposed over the second conductive structure and in contact with the dielectric material, wherein the dielectric material is configured to create a channel between the first conductive structure and the via structure when a voltage is applied to the second conductive structure.

Certain aspects of the present disclosure are generally directed to techniques and apparatus for adjusting capacitance in one or more metal-insulator-metal (MIM) capacitors in an effort to reduce capacitance variation between semiconductor devices and improve yield during fabrication. One example method for fabricating a semiconductor device generally includes measuring a capacitance value of a MIM capacitor of the semiconductor device, determining the measured capacitance value of the MIM capacitor is above a target capacitance value for the MIM capacitor, and selectively rupturing a set of connections in the MIM capacitor based on the measured capacitance value. Selectively rupturing the set of connections in the MIM capacitor may reduce the capacitance value of the MIM capacitor to a value approximately that of the target capacitance value.

A semiconductor device includes a substrate, an isolation structure, a conductive structure, and a first contact structure. The isolation structure is disposed in the substrate. The conductive structure is disposed on the isolation structure. The conductive structure extends upwards from the isolation structure, in which the first contact structure has a top portion on the conductive structure and a bottom portion in contact with the isolation structure.

A piezoelectric actuator is formed like a rectangular flat plate, and includes a substrate layer, a lower electrode layer, a piezoelectric layer, and an upper electrode layer formed in this order from bottom to top in a thickness direction. The upper electrode layer is constituted of a plurality of electrode segments separated in a surface direction, and connection wires connecting the electrode segments which are adjoining in the surface direction.