A semiconductor memory structure includes a substrate, two doped regions in the substrate, a plurality of gate layers, a plurality of insulating layers, a column over the substrate, a charge-trapping layer, and a channel layer. The substrate includes dopants of a first conductivity type, and the two doped regions include dopants of a second conductivity type complementary to the first conductivity type. The gate layers and the insulating layers are alternately stacked over the substrate. The column penetrates the gate layers and the insulating layers, and includes an isolation structure, a source structure and a drain structure. at two sides of the isolation structure. The charge-trapping layer is at two sides of the column, and the channel layer is between the charge-trapping layer and the column. A bottom surface of the charge-trapping layer is in contact with the substrate and separated from the two doped regions.

A memory device includes a plurality of memory cells. Each memory cell includes a multi-gate FeFET that has a first source/drain terminal, a second source/drain terminal, and a gate with a plurality of ferroelectric layers configured such that each of the ferroelectric layers has a respective unique switching E-field.

A semiconductor structure includes a substrate, an interconnection structure disposed over the substrate and a first memory cell. The first memory cell is disposed over the substrate and embedded in dielectric layers of the interconnection structure. The first memory cell includes a first transistor and a first data storage structure. The first transistor is disposed on a first base dielectric layer and embedded in a first dielectric layer. The first data storage structure is embedded in a second dielectric layer and electrically connected to the first transistor. The first data storage structure includes a first electrode, a second electrode and a storage layer sandwiched between the first electrode and the second electrode.

A method includes forming a stack of multi-layers, each multi-layer including a first isolation layer, a semiconductor layer, and a first metal layer; etching the stack of multi-layers to form gate trenches in a channel region; removing the first isolation layers and the first metal layers from the channel region, resulting in channel portions of the semiconductor layers exposed in the gate trenches; laterally recessing the first metal layers from the gate trenches, resulting in gaps between adjacent layers of the first isolation layers and the semiconductor layers; forming an inner spacer layer in the gaps; forming a ferroelectric (FE) layer surrounding each of the channel portions and over sidewalls of the gate trenches, wherein the inner spacer layer is disposed laterally between the FE layer and the first metal layers; and depositing a metal gate layer over the FE layer and filling the gate trenches.

In an anti-fuse memory includes a rectifier element of a semiconductor junction structure in which a voltage applied from a memory gate electrode to a word line is applied as a reverse bias in accordance with voltage values of the memory gate electrode and the word line, and does not use a conventional control circuit. Hence, the rectifier element blocks application of a voltage from the memory gate electrode to the word line. Therefore a conventional switch transistor that selectively applies a voltage to a memory capacitor and a conventional switch control circuit allowing the switch transistor to turn on or off are not necessary. Miniaturization of the anti-fuse memory and a semiconductor memory device are achieved correspondingly.

Routing arrangements for 3D memory arrays and methods of forming the same are disclosed. In an embodiment, a memory array includes a ferroelectric (FE) material contacting a first word line; an oxide semiconductor (OS) layer contacting a source line and a bit line, the FE material being disposed between the OS layer and the first word line; a dielectric material contacting the FE material, the FE material being between the dielectric material and the first word line; an inter-metal dielectric (IMD) over the first word line; a first contact extending through the IMD to the first word line, the first contact being electrically coupled to the first word line; a second contact extending through the dielectric material and the FE material; and a first conductive line electrically coupling the first contact to the second contact.

A 1S-1T ferroelectric memory cell is provided that include a transistor and a two-terminal selector device. The transistor exhibits a low conductive state and a high conductive state (channel resistance), depending on drive voltage. The two-terminal selector device exhibits one of an ON-state and an OFF-state depending upon whether the transistor is in its low conductive state or its high conductive state. The transistor may be, for instance, a ferroelectric gate vertical transistor. Modulation of a polarization state of ferroelectric material of the vertical transistor may be utilized to switch the state of the selector device. The memory cell may thus selectively be operated in one of an ON-state and an OFF-state depending upon whether the selector device is in its ON-state or OFF-state.

A semiconductor structure includes a substrate, an interconnection structure disposed over the substrate and a first memory cell. The first memory cell is disposed over the substrate and embedded in dielectric layers of the interconnection structure. The first memory cell includes a first transistor and a first data storage structure. The first transistor is disposed on a first base dielectric layer and embedded in a first dielectric layer. The first data storage structure is embedded in a second dielectric layer and electrically connected to the first transistor. The first data storage structure includes a first electrode, a second electrode and a storage layer sandwiched between the first electrode and the second electrode.

A memory device includes a plurality of memory cells. Each memory cell includes a multi-gate FeFET that has a first source/drain terminal, a second source/drain terminal, and a gate with a plurality of ferroelectric layers configured such that each of the ferroelectric layers has a respective unique switching E-field.

The present disclosure relates generally to structures in semiconductor devices and methods of forming the same. The present disclosure provides a semiconductor device including a first device region and a second device region. The first device region includes a first metal layer, a first via structure over the first metal layer, a second via structure over the first via structure, and a second metal layer over the second via structure. The first via structure and the second via structure electrically couple the second metal layer to the first metal layer. The second device region includes a third metal layer, a contact structure over the third metal layer, a memory cell structure over the contact structure, and a fourth metal layer over the memory cell structure. The first via structure and the contact structure are made of the same material.