A device structure includes a first gate on a first fin, a second gate on a second fin, where the second gate is spaced apart from the first gate by a distance. A fuse spans the distance and is in contact with the first gate and the second gate. A first dielectric is between the first fin and the second fin, where the first dielectric is in contact with, and below, the fuse and a second dielectric is between the first gate and the second gate, where the second dielectric is on the fuse.

A memory cell includes a semiconductor substrate, a transistor, and a first anti-fuse structure. The transistor is above the semiconductor substrate. The first anti-fuse structure is above the semiconductor substrate and adjacent the transistor, and includes a first terminal and a second terminal. The first terminal of the first anti-fuse structure is in the semiconductor substrate and laterally surrounds the transistor. The second terminal of the first anti-fuse structure is above and spaced apart from the first terminal of the first anti-fuse structure.

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 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.

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.

A multilayer circuit (400) includes a base layer (205) which has a number of base vias (247, 415), a first overlying layer (215) formed on the base layer (205) and having a first routing section (210) and a second overlying layer (220) formed on the first overlying layer (215). The second overlying layer (220) has a second routing section (210) and is formed using the same set of masks. The first routing section (210) and the second routing section (210) form a unique electrical pathway (248) between a base via (247) and an element in an overlying layer. A method for forming a multilayer circuit is also provided.

In one embodiment, a programming circuit is configured to form a programming current for a silicide fuse element by using a non-silicide programming element.

A CMOS anti-fuse cell is disclosed. In one aspect, an apparatus includes an N− well and an anti-fuse cell formed on the N− well. The anti-fuse cell includes a drain P+ diffusion deposited in the N− well, a source P+ diffusion deposited in the N− well, and an oxide layer deposited on the N− well and having an overlapping region that overlaps the drain P+ diffusion. A control gate is deposited on the oxide layer. A data bit of the anti-fuse cell is programmed when a voltage difference between the control gate and the drain P+ diffusion exceeds a voltage threshold of the oxide layer and forms a leakage path from the control gate to the drain P+ diffusion. The leakage path is confined to occur in the overlapping region.