An arrangement of nonvolatile memory devices, having at least one memory device level stacked level by level above a semiconductor substrate, each memory level comprising an oxide layer substantially disposed above a semiconductor substrate, a plurality of word lines substantially disposed above the oxide layer; a plurality of bit lines substantially disposed above the oxide layer; a plurality of via plugs substantially in electrical contact with the word lines and, an anti-fuse dielectric material substantially disposed on side walls beside the bit lines and substantially in contact with the plurality of bit lines side wall anti-fuse dielectrics.

A semiconductor device and methods thereof are disclosed. The proposed semiconductor device includes at least a unit cell wherein the unit cell includes a select transistor, and half of a ground-gate transistor electrically connected to the select transistor, and including a central conductive gate electrode region, two side conductive spacer regions and a gate dielectric layer, wherein a first and a second thicknesses of the gate dielectric layer underneath the two side conductive spacer regions are thinner than a third thickness of the gate dielectric layer underneath the central conductive gate electrode region.

A semiconductor device structure is provided. The semiconductor device structure includes a first gate structure, a second gate structure, and a first active region. The first gate structure extends along a first direction and is electrically connected to a first transistor. The second gate structure extends along the first direction and is electrically connected to a second transistor. The first active region extends along a second direction different from the first direction and across the first gate structure and the second gate structure. The first gate structure and the first active region collaboratively form a first fuse element. The second gate structure and the first active region collaboratively form a second fuse element.

A semiconductor device structure is provided. The semiconductor device structure includes a first gate structure, a second gate structure, and a first active region. The first gate structure extends along a first direction and is electrically connected to a first transistor. The second gate structure extends along the first direction and is electrically connected to a second transistor. The first active region extends along a second direction different from the first direction and across the first gate structure and the second gate structure. The first gate structure and the first active region collaboratively form a first fuse element. The second gate structure and the first active region collaboratively form a second fuse element.

The present application provides a memory device. The memory device includes a semiconductor substrate including an isolation structure and an active area surrounded by the isolation structure; a fuse gate structure disposed over the active area; a device gate structure disposed over the active area and adjacent to the fuse gate structure; and a contact plug coupled to the active area and extending away from the semiconductor substrate, wherein at least a portion of the active area is disposed under the device gate structure. Further, a method of manufacturing the memory device is also disclosed.

The present application provides a memory device. The memory device includes a semiconductor substrate including an isolation structure and an active area surrounded by the isolation structure; a fuse gate structure disposed over the active area; a device gate structure disposed over the active area and adjacent to the fuse gate structure; and a contact plug coupled to the active area and extending away from the semiconductor substrate, wherein at least a portion of the active area is disposed under the device gate structure. Further, a method of manufacturing the memory device is also disclosed.

A memory device includes a first memory cell having a first polysilicon line associated with a first read word line and intersecting a first active region and a second active region, and a second polysilicon line and a first CPODE associated with a first program word line, the second polysilicon line intersecting the first active region and the first CPODE intersecting the second active region. The memory device also includes a second memory cell adjacent to the first memory cell, the second memory cell having a third polysilicon line associated with a second read word line and intersecting the first active region and the second active region, and a fourth polysilicon line and a second CPODE associated with a second program word line, the fourth polysilicon line intersecting the second active region and the second CPODE intersecting the first active region to form a cross-arrangement of CPODE.

A configurable read only memory (ROM) including a number of memory cells. The memory cells include first-type memory cells that are electrically-programmable antifuses and second-type memory cells that are antifuses programmed by masking.

The present invention discloses a three-dimensional vertical read-only memory (3D-OTP.sub.V). It comprises a plurality of vertical OTP strings formed side-by-side on a substrate circuit. Each OTP string is vertical to the substrate and comprises a plurality of vertically stacked OTP cells. Each OTP cell comprises an antifuse layer. The antifuse layer is irreversibly switched from a high-resistance state to a low-resistance state during programming.

Semiconductor structures containing FinFET anti-fuses with reduced breakdown voltage are provided which can be readily integrated with high performance FinFETs. The anti-fuse includes at least one metal structure having a faceted sidewall. The sharp corner of the faceted sidewall of the at least one metal structure causes an electric field concentration, thus reducing the breakdown voltage of the anti-fuse.