A semiconductor device has, in a gate insulating layer, in an XPS spectrum of O 1s obtained by an X-ray photoelectron spectroscopy (XPS) using a monochromatic aluminum K (1486.6 eV) source, a ratio (%) of an AlO peak observed in a binding energy of about 530.3 eV to about 531.6 eV to all peaks of greater than or equal to about 80%.

A semiconductor device includes a transistor and a ferroelectric tunnel junction. The ferroelectric tunnel junction is connected to a drain contact of the transistor. The ferroelectric tunnel junction includes a first electrode, a second electrode, a crystalline oxide layer, and a ferroelectric layer. The second electrode is disposed over the first electrode. The crystalline oxide layer and the ferroelectric layer are disposed in direct contact with each other in between the first electrode and the second electrode. The crystalline oxide layer comprises a crystalline oxide material. The ferroelectric layer comprises a ferroelectric material.

Present invention relates to a highly-integrated memory cell and a semiconductor device including the same. According to an embodiment of the present invention, a semiconductor device comprises: an active layer including a channel, the active layer being spaced apart from a substrate and extending in a direction parallel to a surface of the substrate; a gate dielectric layer formed over the active layer; a word line laterally oriented in a direction crossing the active layer over the gate dielectric layer and including a low work function electrode and a high work function electrode, the high work function electrode having a higher work function than the low work function electrode; and a dipole inducing layer disposed between the high work function electrode and the gate dielectric layer.

Provided are a ferroelectric semiconductor device and a method of extracting a defect density of the same. A ferroelectric electronic device includes a first layer, an insulating layer including a ferroelectric layer and a first interface that is adjacent to the first layer, and an upper electrode over the insulating layer, wherein the insulating layer has a bulk defect density of 10.sup.16 cm.sup.3 eV.sup.1 or more and an interface defect density of 10.sup.10 cm.sup.2 eV.sup.1 or more.

A device comprises an array comprising rows and columns of elevationally-extending transistors. An access line interconnects multiple of the elevationally-extending transistors along individual of the rows. The transistors individually comprise an upper source/drain region, a lower source/drain region, and a channel region extending elevationally there-between. The channel region comprises an oxide semiconductor. A transistor gate is operatively laterally-proximate the channel region and comprises a portion of an individual of the access lines. Intra-row-insulating material is longitudinally between immediately-intra-row-adjacent of the elevationally-extending transistors. Inter-row-insulating material is laterally between immediately-adjacent of the rows of the elevationally-extending transistors. At least one of the intra-row-insulating material and the inter-row-insulating material comprises void space. Other embodiments, including method embodiments, are disclosed.

A method according to the present disclosure includes forming a bottom electrode layer over a substrate, forming an insulator layer over the bottom electrode layer, depositing a semiconductor layer over the bottom electrode layer, depositing a ferroelectric layer over the semiconductor layer, forming a top electrode layer over the ferroelectric layer, and patterning the bottom electrode layer, the insulator layer, the semiconductor layer, the ferroelectric layer, and the top electrode layer to form a memory stack. The semiconductor layer includes a plurality of portions with different thicknesses.

In an embodiment, a device includes: a first dielectric layer over a substrate; a word line over the first dielectric layer, the word line including a first main layer and a first glue layer, the first glue layer extending along a bottom surface, a top surface, and a first sidewall of the first main layer; a second dielectric layer over the word line; a first bit line extending through the second dielectric layer and the first dielectric layer; and a data storage strip disposed between the first bit line and the word line, the data storage strip extending along a second sidewall of the word line.

A ferroelectric semiconductor device according to an embodiment includes a substrate, a channel layer disposed over the substrate to extend in a vertical direction substantially perpendicular to a surface of the substrate, an interfacial dielectric layer disposed on the channel layer, and a floating electrode layer disposed on the interfacial dielectric layer. The floating electrode layer includes first and second electrode portions respectively disposed on different portions of the interfacial dielectric layer. In addition, the ferroelectric semiconductor device includes a ferroelectric layer disposed on the first electrode portion of the floating electrode layer, a gate electrode layer disposed on the ferroelectric layer, and an insulation structure covering the second electrode portion of the floating electrode layer over the substrate.

A memory structure includes randomly accessible, channel-all-around ferroelectric memory transistors organized as horizontal NOR memory strings. The NOR memory strings are formed over a semiconductor substrate in multiple scalable memory stacks of thin-film ferroelectric memory transistors. The three-dimensional memory stacks are manufactured in a process that includes forming holes in a multi-layer film stack for forming local word line structures and slit trenches to divide the film stack into memory stacks including local word line structures formed therein. The memory structure of channel-all-around ferroelectric memory transistors enables a scalable construction for realizing a high density, high capacity memory device.

A semiconductor device including: a lower semiconductor substrate; an upper semiconductor substrate overlapping the lower semiconductor substrate, the upper semiconductor substrate including a first surface and a second surface opposite to the first surface; an upper gate structure on the first surface of the upper semiconductor substrate; a first interlayer insulation film which covers the upper gate structure, wherein the first interlayer insulation film is between the lower semiconductor substrate and the upper semiconductor substrate; and an upper contact connected to the lower semiconductor substrate, wherein the upper contact is on a side surface of the upper gate structure, wherein the upper contact includes a first portion penetrating the upper semiconductor substrate, and a second portion having a side surface adjacent to the side surface of the upper gate structure, and a width of the first portion decreases toward the second surface.