The disclosed technology generally relates to a memory device, and more particularly to a ferroelectric memory device and a method of operating the memory device. According to one aspect, a memory device comprises a bit cell. The bit cell comprises a write transistor, a read transistor and a ferroelectric capacitor. A write word line is connected to a gate terminal of the write transistor. A write bit line is connected to a first terminal of the write transistor. A read bit line connected to a terminal of the read transistor. A first control line is connected to a first electrode of the ferroelectric capacitor. A second terminal of the write transistor is connected to the gate terminal of the read transistor, and a second electrode of the ferroelectric capacitor is connected to the second terminal.

A gated ferroelectric memory cell includes a dielectric material layer disposed over a substrate, a metallic bottom electrode, a ferroelectric dielectric layer contacting a top surface of the bottom electrode, a pillar semiconductor channel overlying the ferroelectric dielectric layer and capacitively coupled to the metallic bottom electrode through the ferroelectric dielectric layer, a gate dielectric layer including a horizontal gate dielectric portion overlying the ferroelectric dielectric layer and a tubular gate dielectric portion laterally surrounding the pillar semiconductor channel, a gate electrode strip overlying the horizontal gate dielectric portion and laterally surrounding the tubular gate dielectric portion and a metallic top electrode contacting a top surface of the pillar semiconductor channel.

A device structure includes at least one selector device. Each selector device includes a vertical stack including, from bottom to top, a bottom electrode, a metal oxide semiconductor channel layer, and a top electrode and located over a substrate, a gate dielectric layer contacting sidewalls of the bottom electrode, the metal oxide semiconductor channel layer, and the top electrode, and a gate electrode formed within the gate dielectric layer and having a top surface that is coplanar with a top surface of the top electrode. Each top electrode or each bottom electrode of the at least one selector device may be contacted by a respective nonvolatile memory element to provide a one-selector one-resistor memory cell.

Described herein are ferroelectric (FE) memory cells that include transistors having gate stacks separate from FE capacitors of these cells. An example memory cell may be implemented as an IC device that includes a support structure (e.g., a substrate) and a transistor provided over the support structure and including a gate stack. The IC device also includes a FE capacitor having a first capacitor electrode, a second capacitor electrode, and a capacitor insulator of a FE material between the first capacitor electrode and the second capacitor electrode, where the FE capacitor is separate from the gate stack (i.e., is not integrated within the gate stack and does not have any layers that are part of the gate stack). The IC device further includes an interconnect structure, configured to electrically couple the gate stack and the first capacitor electrode.

The present disclosure relates to semiconductor structures and, more particularly, to ferroelectric based transistors and methods of manufacture. The ferroelectric based transistor includes: a semiconductor-on-insulator substrate including a semiconductor material, a buried insulator layer under the semiconductor material and a substrate material under the semiconductor channel material; a ferroelectric capacitor under the buried insulator layer and which includes a bottom electrode, a top electrode and a ferroelectric material between the bottom electrode and the top electrode; a gate stack over the semiconductor material; a first terminal contact connecting to the bottom electrode of the ferroelectric capacitor; and a second terminal contact connecting to the top electrode of the ferroelectric capacitor.

Some embodiments include an assembly having first and second pillars. Each of the pillars has an inner edge and an outer edge. A first gate is proximate a channel region of the first pillar. A second gate is proximate a channel region of the second pillar. A shield line is between the first and second pillars. First and second bottom electrodes are over the first and second pillars, respectively; and are configured as first and second angle plates. An insulative material is over the first and second bottom electrodes. The insulative material may be ferroelectric or non-ferroelectric. A top electrode is over the insulative material. Some embodiments include methods of forming assemblies.

Some embodiments include a capacitor having a container-shaped bottom portion. The bottom portion has a first region over a second region. The first region is thinner than the second region. The first region is a leaker region and the second region is a bottom electrode region. The bottom portion has an interior surface that extends along the first and second regions. An insulative material extends into the container shape. The insulative material lines the interior surface of the container shape. A conductive plug extends into the container shape and is adjacent the insulative material. A conductive structure extends across the conductive plug, the insulative material and the first region of the bottom portion. The conductive structure directly contacts the insulative material and the first region of the bottom portion, and is electrically coupled with the conductive plug. Some embodiments include methods of forming assemblies.

A method of forming an array of capacitors comprises forming elevationally-extending and longitudinally-elongated capacitor electrode lines over a substrate. Individual of the capacitor electrode lines are common to and a shared one of two capacitor electrodes of individual capacitors longitudinally along a line of capacitors being formed. A capacitor insulator is formed over a pair of laterally-opposing sides of and longitudinally along individual of the capacitor electrode lines. An elevationally-extending conductive line is formed over the capacitor insulator longitudinally along one of the laterally-opposing sides of the individual capacitor electrode lines. The conductive line is cut laterally through to form spaced individual other of the two capacitor electrodes of the individual capacitors. Other methods are disclosed, including structures independent of method of manufacture.

In one aspect, the invention is formulations comprising both organoaminohafnium and organoaminosilane precursor compounds that allows anchoring both silicon-containing fragments and hafnium-containing fragments onto a given surface having hydroxyl groups to deposit silicon doped hafnium oxide having a silicon doping level ranging from 0.5 to 8 mol %, suitable as ferroelectric material. In another aspect, the invention is methods and systems for depositing the silicon doped hafnium oxide films as ferroelectric materials using the formulations.

Some embodiments relate to a ferroelectric random access memory (FeRAM) device. The FeRAM device includes a bottom electrode structure and a top electrode overlying the ferroelectric structure. The top electrode has a first width as measured between outermost sidewalls of the top electrode. A ferroelectric structure separates the bottom electrode structure from the top electrode. The ferroelectric structure has a second width as measured between outermost sidewalls of the ferroelectric structure. The second width is greater than the first width such that the ferroelectric structure includes a ledge that reflects a difference between the first width and the second width. A dielectric sidewall spacer structure is disposed on the ledge and covers the outermost sidewalls of the top electrode.