A memory device is disclosed, including a bit cell storing a bit data. The bit cell includes multiple first transistors coupled to a node, multiple second transistors each coupled in series to a corresponding one of the first transistors, and at least one third transistor. The first transistors are turned on in response to a control signal. The second transistors are turned on in response to a first word line signal. The at least one third transistor has a control terminal to receive a second word line signal. In a programming mode of the memory device, the at least one third transistor provides, in response to the second word line signal, an adjust voltage to the node. The adjust voltage is associated with a voltage level of a first terminal of the at least one third transistor.

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 cross-point memory includes a plurality of memory devices, with each device comprising a memory layer between first and second address lines. In one preferred embodiment, the memory layer comprises an OTS (Ovonic Threshold Switch) film and an antifuse film. In another preferred embodiment, the memory layer comprises an OTS film having a first switch voltage (i.e. forming voltage V.sub.form) greater than all subsequent switch voltages (i.e. threshold voltage V.sub.th). The cross-point memory is preferably a three-dimensional one-time-programmable memory (3D-OTP), including horizontal 3D-OTP and vertical 3D-OTP

Embodiments disclose a semiconductor structure and a method for fabricating the same. The semiconductor structure includes: a substrate, a gate dielectric layer, a first conductive layer, and a conductive plug. The gate dielectric layer is provided on the substrate, and the first conductive layer is provided on the gate dielectric layer. The conductive plug is provided on the gate dielectric layer and covers a side wall of the first conductive layer, where a projection of the conductive plug on the substrate and a projection of the gate dielectric layer on the substrate at least partially overlap. By providing the conductive plug, a breakdown current can break down a region of the gate dielectric layer corresponding to the conductive plug by means of the conductive plug. That is, a breakdown position is adjusted by controlling an overlapping position between the conductive plug and the gate dielectric layer.

Embodiments disclose a semiconductor structure and a method for fabricating the same. The semiconductor structure includes: a substrate, a gate dielectric layer, a first conductive layer, and a conductive plug. The gate dielectric layer is provided on the substrate, and the first conductive layer is provided on the gate dielectric layer. The conductive plug is provided on the gate dielectric layer and covers a side wall of the first conductive layer, where a projection of the conductive plug on the substrate and a projection of the gate dielectric layer on the substrate at least partially overlap. By providing the conductive plug, a breakdown current can break down a region of the gate dielectric layer corresponding to the conductive plug by means of the conductive plug. That is, a breakdown position is adjusted by controlling an overlapping position between the conductive plug and the gate dielectric layer.

A one-time programmable (OTP) memory cell includes a substrate having a first conductivity type and having an active area surrounded by an isolation region, a transistor disposed on the active area, and a capacitor disposed on the active area and electrically coupled to the transistor. The capacitor comprises a diffusion region of a second conductivity type in the substrate, a metallic film in direct contact with the active area, a capacitor dielectric layer on the metallic film, and a metal gate surrounded by the capacitor dielectric layer. The diffusion region and the metallic film constitute a capacitor bottom plate.

An anti-fuse memory cell includes a substrate, a gate dielectric layer over the substrate, a word line gate over the gate dielectric layer, a first implant region on a first side of the word line gate, a bit line contact plug over the first implant region, a second implant region on a second side of the word line gate opposite the first side of the word line gate, an oxidized region on the second implant region and having a convex upper surface and a source line gate over the convex upper surface of the oxidized region.

A layout structure of an anti-fuse array at least includes an array circuit area and a functional circuit area. The array circuit area is electrically connected with the functional circuit area. The functional circuit area is located on at least one side of the array circuit area, and at least one side of the array circuit area is located on an edge of the layout structure. The array circuit area includes an anti-fuse array composed of anti-fuse cells, and the array circuit area is configured to provide the anti-fuse cells under different column addresses to the functional circuit area. The functional circuit area is configured to fuse the anti-fuse cells under the different column addresses.

An anti-fuse circuit includes the following: a first transistor, and at least one parasitic transistor and at least one parasitic triode that are connected to the first transistor. The at least one parasitic transistor and the at least one parasitic triode are connected to a first node.

A one-time programmable nonvolatile memory cell includes a substrate providing a first conductivity type well and a second conductivity type well, a first MOS transistor having a floating gate and a gate oxide, and an auxiliary gate and a gate oxide formed by extending one end of the floating gate and the gate oxide of the first MOS transistor from an edge of the first active region, along a second direction perpendicular to the first direction, passing through the isolation region until to cover a part or an entire of the second active region. The first and the second active regions are separated by an isolation region, and the first and second active regions and the isolation region are arranged parallel to each other along a first direction. The memory cell has an improved structure and optimized performance and a reduced size.