A method of making a semiconductor die includes forming, over a substrate, a stack including insulating layers and sacrificial layers alternatively on top of each other; replacing a portion of first sacrificial layers located in a first portion of the stack to form first gate layers; forming first channel layers extending in a first direction in the first portion; forming first memory layers extending in the first direction in the first portion; replacing a portion of second sacrificial layers located in a second portion of the stack to form second gate layers; forming second channel layers extending in the first direction in the second portion; and forming second memory layers extending in the first direction in the second portion.

A transistor includes an insulating layer, a source region, a drain region, a channel layer, a ferroelectric layer, and a gate electrode. The source region and the drain region are respectively disposed on and in physical contact with two opposite sidewalls of the insulating layer. A thickness of the source region, a thickness of the drain region, and a thickness of the insulating layer are substantially the same. The channel layer is disposed on the insulating layer, the source region, and the drain region. The ferroelectric layer is disposed over the channel layer. The gate electrode is disposed on the ferroelectric layer.

A memory device and a manufacturing method are provided. The memory device includes a substrate, a transistor, and a memory cell. The substrate has a semiconductor device and a dielectric structure disposed on the semiconductor device. The transistor is disposed over the dielectric structure and is electrically coupled with the semiconductor device. The semiconductor device includes a gate, a channel layer, source drain regions, and a stack of a gate dielectric layer and a first ferroelectric layer. The gate and the source and drain regions are disposed over the dielectric structure. The channel layer is located between the source and drain regions. The stack of the gate dielectric layer and the first ferroelectric layer is disposed between the gate and the channel layer. The memory cell is disposed over the transistor and is electrically connected to one of the source and drain regions. The memory cell includes a ferromagnetic layer or a second ferroelectric layer.

A method of fabricating a transistor structure is provided. The method comprises forming a gate electrode in a dielectric layer of an interconnect structure; forming a monolayer on a portion of the dielectric layer laterally spaced from the gate electrode; sequentially forming a ferroelectric layer, a barrier layer and a channel layer on the gate electrode; and forming a source/drain electrode on the channel layer.

Methods for producing ferroelectric device are described. A method includes positioning an organic polymeric ferroelectric layer between two conductive materials to form a stack. The stack can be subjected to a 2-step heat treating process. The first heat treating step transforms the organic polymeric ferroelectric precursor to a ferroelectric material having ferroelectric hysteresis properties, and the second heat treating step densities the ferroelectric material to obtain the ferroelectric device. The thin film ferroelectric device can include a thin film ferroelectric capacitor, a thin film ferroelectric transistor, or a thin film ferroelectric diode.

Disclosed herein are nanoscale devices comprising one or more ferroelectric nanoshells characterized as having an extreme curvature in at least one spatial dimension. Also disclosed are ferroelectric field effect transistors and metal ferroelectric metal capacitors comprising one or more ferroelectric nanoshells. Methods for controlling spontaneous ferroelectric polarization in nanoshell devices are also disclosed.

A method includes providing a semiconductor structure. The semiconductor structure includes a first transistor region, a second transistor region and a silicon dioxide layer on the first transistor region and the second transistor region. A layer of a high-k dielectric material is deposited on the silicon dioxide layer. A layer of a first metal is formed over the second transistor region. The layer of first metal does not cover the first transistor region. After the formation of the layer of the first metal, a layer of a second metal is deposited over the first transistor region and the second transistor region. A first annealing process is performed. The first annealing process initiates a scavenging reaction between the second metal and silicon dioxide from a portion of the silicon dioxide layer on the first transistor region. After the annealing process, a ferroelectric transistor dielectric is formed over the first transistor region.

The disclosed technology generally relates to ferroelectric materials and semiconductor devices, and more particularly to semiconductor memory devices incorporating doped polar materials. In one aspect, a capacitor comprises a crystalline polar layer comprising a base polar material substitutionally doped with a dopant. The base polar material comprises one or more metal elements and one or both of oxygen or nitrogen. The dopant comprises a metal element of one of 4d series, 5d series, 4f series or 5f series that is different from the one or more metal elements, such that a ferroelectric switching voltage of the capacitor is different from that of the capacitor having the base polar material without being doped with the dopant by more than about 100 mV.

Semiconductor devices and methods of forming the same are provided. A semiconductor device according to the present disclosure includes a ferroelectric structure including a channel region and a source/drain region, a gate dielectric layer disposed over the channel region of the ferroelectric structure, a gate electrode disposed on the gate dielectric layer, and a source/drain contact disposed on the source/drain region of the ferroelectric structure. The ferroelectric structure includes gallium nitride, indium nitride, or indium gallium nitride. The ferroelectric structure is doped with a dopant.

A method for forming a memory device includes: forming a first layer stack and a second layer stack successively over a substrate, wherein each of the first and the second layer stacks comprises a dielectric layer, a channel layer, and a source/drain layer formed successively over the substrate; forming openings that extend through the first layer stack and the second layer stack, where the openings include first openings within boundaries of the first and the second layer stacks, and a second opening extending from a sidewall of the second layer stack toward the first openings; forming inner spacers by replacing portions of the source/drain layer exposed by the openings with a dielectric material; lining sidewalls of the openings with a ferroelectric material; and forming first gate electrodes in the first openings and a dummy gate electrode in the second opening by filling the openings with an electrically conductive material.