A two-terminal memory device including: a substrate; a source and a drain formed to face each other on an upper surface of the substrate; a ferroelectric layer connected to the source and the drain and formed between the source and the drain; and an extended drain extending from the drain and laminated on the ferroelectric layer. The two-terminal memory device may be applied as a cross-point type and neuromorphic device capable of implementing multi-resistance levels with multi-layer switchable resistance layers.

Provided are a capacitor and a semiconductor device including the same. The capacitor includes: a dielectric layer having a perovskite crystal structure; and first and second electrodes spaced apart from each other with the dielectric layer therebetween. At least one of the first and second electrodes includes a metallic layer having a perovskite crystal structure, a first ionic layer having ionic properties, and a semiconductor layer.

A memory cell includes a select device and a capacitor electrically coupled in series with the select device. The capacitor includes two conductive capacitor electrodes having ferroelectric material there-between. The capacitor has an intrinsic current leakage path from one of the capacitor electrodes to the other through the ferroelectric material. There is a parallel current leakage path from the one capacitor electrode to the other. The parallel current leakage path is circuit-parallel the intrinsic path and of lower total resistance than the intrinsic path. Other aspects are disclosed.

A memory cell includes a select device and a capacitor electrically coupled in series with the select device. The capacitor includes two conductive capacitor electrodes having ferroelectric material there-between. The capacitor has an intrinsic current leakage path from one of the capacitor electrodes to the other through the ferroelectric material. There is a parallel current leakage path from the one capacitor electrode to the other. The parallel current leakage path is circuit-parallel the intrinsic path and of lower total resistance than the intrinsic path. Other aspects are disclosed.

A semiconductor structure and method for forming the semiconductor are provided. The semiconductor structure includes a first electrode comprising a first portion, a second portion, and a sheet portion connecting the first portion to the second portion. A ferroelectric material is over the sheet portion. A second electrode is over the ferroelectric material.

A semiconductor structure and method for forming the semiconductor are provided. The semiconductor structure includes a first electrode comprising a first portion, a second portion, and a sheet portion connecting the first portion to the second portion. A ferroelectric material is over the sheet portion. A second electrode is over the ferroelectric material.

An integrated circuit device includes a ferroelectric layer that is formed with chlorine-free precursors. This ferroelectric material may be of the composition HF.sub.xZr.sub.1-xO.sub.2. The ferroelectric layer may be used in a memory device such as a ferroelectric field effect transistor (FeFET). A ferroelectric layer formed with chlorine-free precursors has no chlorine residue. The absence of chlorine ameliorates time-dependent dielectric breakdown (TDDB) and Bias Temperature Instability (BTI).

Some embodiments include an integrated assembly having pillars arranged in an array. The pillars have channel regions between upper and lower source/drain regions. Gating structures are proximate to the channel regions and extend along a row direction. Digit lines are beneath the pillars, extend along a column direction, and are coupled with the lower source/drain regions. Linear structures are above the pillars and extend along the column direction. Bottom electrodes are coupled with the upper source/drain regions. The bottom electrodes have horizontal segments adjacent the upper source/drain regions and have vertical segments extending upwardly from the horizontal segments. The vertical segments are adjacent to lateral sides of the linear structures. Ferroelectric-insulative-material and top-electrode-material are over the bottom electrodes. A slit passes through the top-electrode-material, is directly over one of the linear structures, and extends along the column direction.

A semiconductor device includes a bottom electrode, a top electrode, a sidewall spacer, and a data storage element. The sidewall spacer is disposed aside the top electrode. The data storage element is located between the bottom electrode and the top electrode, and includes a ferroelectric material. The data storage element has a peripheral region which is disposed beneath the sidewall spacer and which has at least 60% of ferroelectric phase. A method for manufacturing the semiconductor device and a method for transforming a non-ferroelectric phase of a ferroelectric material to a ferroelectric phase are also disclosed.

A semiconductor device includes a bottom electrode, a top electrode, a sidewall spacer, and a data storage element. The sidewall spacer is disposed aside the top electrode. The data storage element is located between the bottom electrode and the top electrode, and includes a ferroelectric material. The data storage element has a peripheral region which is disposed beneath the sidewall spacer and which has at least 60% of ferroelectric phase. A method for manufacturing the semiconductor device and a method for transforming a non-ferroelectric phase of a ferroelectric material to a ferroelectric phase are also disclosed.