A memory device includes a plurality of memory cells, each of which includes a first transistor, a second transistor, and a resistor operatively coupled to each other in series. Each of the first and second transistors include a sub-transistor, the sub-transistor having a channel structure, a source structure disposed on one side of the channel structure, and a drain structure disposed on the other side of the channel structure. The resistor includes a metal structure disposed above the first and second transistors. The channel structures, source structures, and drain structures of the sub-transistors are all formed in a first active region of a substrate.

A superconducting connecting system includes an anti-fuse structure. There is a first superconducting trace having a first segment that is cantilevered over a cavity a substrate. A second superconducting trace having a second segment is cantilevered over the cavity in the substrate. A first auxiliary segment is coupled to the first segment and suspended over the cavity. A second auxiliary segment is coupled to the second segment and suspended over the cavity. The first segment and the second segment face each other and have a predetermined gap therebetween. The first segment and the second segment are configured to receive an output of a laser. An amount of material of the first and second auxiliary segment is based on creating a fuse ball joint that provides an electrical short between the first superconducting trace and the second superconducting trace, upon receiving the output of the laser.

A semiconductor memory device with a three-dimensional (3D) structure may include: a cell region arranged over a substrate, including a cell structure; a peripheral circuit region arranged between the substrate and the cell region; an upper wiring structure arranged over the cell region; main channel films and dummy channel films formed through the cell structure. The dummy channel films are suitable for electrically coupling the upper wiring structure.

A method for activating a backup unit includes providing a fuse element connected to the backup unit. The fuse element includes an active area, which includes a source region and a drain region beside the source region, a gate region disposed on the active area, and a shallow trench isolation (STI) structure surrounding the active area. The method also includes applying a stress voltage on the drain region of the fuse element; accumulating electrons in a portion of the STI structure adjacent to the drain region; generating a conductive path through the drain region and the source region so that the fuse element is conductive; and activating the backup unit through the fuse element.

A system and method for providing and programming a programmable inductor is provided. The structure of the programmable inductor includes multiple turns, with programmable interconnects incorporated at various points around the turns to provide a desired isolation of the turns during programming. In an embodiment the programming may be controlled using the size of the vias, the number of vias, or the shapes of the interconnects.

A semiconductor wafer comprising a first die including a first integrated circuit having a trimmable or programmable component. The trimmable or programmable component is configured to be trimmed or permanently altered in response to an electrical signal. The semiconductor wafer also includes a saw street arranged adjacent to the first die, and at least one probe pad electrically connected to the trimmable or programmable component. The at least one probe pad is arranged in the saw street.

A semiconductor package includes a metallic pad and leads, a semiconductor die including a semiconductor substrate attached to the metallic pad, and a conductor including a sacrificial fuse element above the semiconductor substrate, the sacrificial fuse element being electrically coupled between one of the leads and at least one terminal of the semiconductor die, and a multilayer dielectric between the sacrificial fuse element and the semiconductor substrate, the multilayer dielectric forming one or more planar gaps beneath a profile of the sacrificial fuse element.

A memory device is disclosed. The memory device includes a plurality of memory cells, each of the memory cells including an access transistor and a resistor coupled to each other in series. The resistors of the memory cells are each formed as one of a plurality of interconnect structures disposed over a substrate. The access transistors of the memory cells are disposed opposite a first metallization layer containing the plurality of interconnect structures from the substrate.

A semiconductor circuit and semiconductor device for determining status of a fuse element are provided. The semiconductor circuit includes a configurable reference resistor unit with a first terminal receiving a first power signal and a second terminal electrically coupled to the fuse element. The semiconductor circuit also includes a latch circuit for reading a first status signal of a first node between the configurable reference resistor unit and the fuse element. The configurable reference resistor unit includes a first resistor, a first transistor connected in parallel with the first resistor, and a first configurable unit connected to a gate of the first transistor. The first configurable unit is configured to generate a first configurable signal to be provided to the gate of the first transistor.

The present disclosure provides a method for determining status of a fuse element of a memory device. The method includes providing the memory device including a first terminal and a second terminal and applying a first power signal on the first terminal of the semiconductor device. The memory device includes a configurable reference resistor unit electrically coupled to the fuse element. The method also includes obtaining an evaluation signal at the second terminal of the memory device and identifying the evaluation signal to determine whether the memory device is redundant. The configurable reference resistor unit includes a first resistor, a first transistor connected in parallel with the first resistor, and a first configurable unit connected to a gate of the first transistor. The first configurable unit is configured to generate a first configurable signal to turn on the first transistor.