A ferroelectric memory device includes a substrate, a gate electrode, a ferroelectric layer, and a pair of source/drain electrodes. The gate electrode is disposed over the substrate. The ferroelectric layer at least covers two adjacent side surfaces of the gate electrode. The pair of source/drain electrodes is over the substrate and disposed on two opposite sides of the gate electrode respectively.

Provided is a ferroelectric field effect transistor (FeFET) which has a wide memory window even if the ferroelectric film thickness is 200 nm or less, and which has excellent data retention characteristics, pulse rewriting endurance and the like. An FeFET which has a structure wherein an insulating body (11) and a gate electrode conductor (4) are sequentially laminated in this order on a semiconductor base (10) that has a source region (12) and a drain region (13). The insulating body (11) is configured by laminating a first insulating body (1) and a second insulating body (2) in this order on the base (10), and the second insulating body (2) is mainly composed of an oxide of strontium, calcium, bismuth and tantalum.

A memory cell includes a ferroelectric (FE) material contacting a word line; and an oxide semiconductor (OS) layer contacting a source line and a bit line, wherein the FE material is disposed between the OS layer and the word line. The OS layer comprises: a first region adjacent the FE material, the first region having a first concentration of a semiconductor element; a second region adjacent the source line, the second region having a second concentration of the semiconductor element; and a third region between the first region and the second region, the third region having a third concentration of the semiconductor element, the third concentration is greater than the second concentration and less than the first concentration.

A reconfigurable field effect transistor (RFET) includes a nanowire, wherein the nanowire comprises two Schottky contacts, as well as two gate contacts partially enclosing the nanowire in cross section. An integrated circuit can be produced therefrom. The aim of producing CMOS circuits with enhanced functionality and a more compact design is achieved in that the nanowire is divided along the cross section thereof into two nanowire parts, wherein each nanowire part comprises a respective Schottky contact and a respective gate contact, and the two nanowire parts are connected electrically to one another via a common substrate and stand vertically on the substrate. In a nanowire-parts-array, between the nanowire parts, a respective top-gate contact and/or back-gate contact can be formed in a substrate defining a substrate plane.

Provided are an electronic device and a method of manufacturing the same. The electronic device may include a first device provided on a first region of a substrate; and a second device provided on a second region of the substrate, wherein the first device may include a first domain layer including a ferroelectric domain and a first gate electrode on the first domain layer, and the second device may include a second domain layer including a ferroelectric domain and a second gate electrode on the second domain layer. The first domain layer and the second domain layer may have different characteristics from each other at a polarization change according to an electric field. At the polarization change according to the electric field, the first domain layer may have substantially a non-hysteretic behavior characteristic and the second domain layer may have a hysteretic behavior characteristic.

Semiconductor devices and methods of forming the same are provided. A semiconductor device according to the present disclosure includes a first gate electrode, a ferroelectric insulating layer over the first gate electrode, a semiconductor member over the ferroelectric insulating layer, a gate dielectric layer over the semiconductor member, and a second gate electrode over the gate dielectric layer.

Semiconductor device and the manufacturing method thereof are disclosed. An exemplary method comprises forming a first stack structure and a second stack structure in a first area over a substrate, wherein each of the stack structures includes semiconductor layers separated and stacked up; depositing a first interfacial layer around each of the semiconductor layers of the stack structures; depositing a gate dielectric layer around the first interfacial layer; forming a dipole oxide layer around the gate dielectric layer; removing the dipole oxide layer around the gate dielectric layer of the second stack structure; performing an annealing process to form a dipole gate dielectric layer for the first stack structure and a non-dipole gate dielectric layer for the second stack structure; and depositing a first gate electrode around the dipole gate dielectric layer of the first stack structure and the non-dipole gate dielectric layer of the second stack structure.

Describe is a resonator that uses ferroelectric (FE) materials in the gate of a transistor as a dielectric. The use of FE increases the strain/stress generated in the gate of the FinFET. Along with the usual capacitive drive, which is boosted with the increased polarization, FE material expands or contacts depending on the applied electric field on the gate of the transistor. As such, acoustic waves are generated by switching polarization of the FE materials. In some embodiments, the acoustic mode of the resonator is isolated using phononic gratings all around the resonator using the metal line above and vias' to body and dummy fins on the side. As such, a Bragg reflector is formed above the FE based transistor.

The present disclosure describes a device that is protected from the effects of an oxide on the metal gate layers of ferroelectric field effect transistors. In some embodiments, the device includes a substrate with fins thereon; an interfacial layer on the fins; a crystallized ferroelectric layer on the interfacial layer; and a metal gate layer on the ferroelectric layer,

A neuromorphic multi-bit digital weight cell configured to store a series of potential weights for a neuron in an artificial neural network. The neuromorphic multi-bit digital weight cell includes a parallel cell including a series of passive resistors in parallel and a series of gating transistors. Each gating transistor of the series of gating transistors is in series with one passive resistor of the series of passive resistors. The neuromorphic cell also includes a series of programming input lines connected to the series of gating transistors, an input terminal connected to the parallel cell, and an output terminal connected to the parallel cell.