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 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.

Direct-bonded LED arrays and applications are provided. An example process fabricates a LED structure that includes coplanar electrical contacts for p-type and n-type semiconductors of the LED structure on a flat bonding interface surface of the LED structure. The coplanar electrical contacts of the flat bonding interface surface are direct-bonded to electrical contacts of a driver circuit for the LED structure. In a wafer-level process, micro-LED structures are fabricated on a first wafer, including coplanar electrical contacts for p-type and n-type semiconductors of the LED structures on the flat bonding interface surfaces of the wafer. At least the coplanar electrical contacts of the flat bonding interface are direct-bonded to electrical contacts of CMOS driver circuits on a second wafer. The process provides a transparent and flexible micro-LED array display, with each micro-LED structure having an illumination area approximately the size of a pixel or a smallest controllable element of an image represented on a high-resolution video display.

In some embodiments, the present disclosure relates to a method of forming an integrated chip including forming a ferroelectric layer over a bottom electrode layer, forming a top electrode layer over the ferroelectric layer, performing a first removal process to remove peripheral portions of the bottom electrode layer, the ferroelectric layer, and the top electrode layer, and performing a second removal process using a second etch that is selective to the bottom electrode layer and the top electrode layer to remove portions of the bottom electrode layer and the top electrode layer, so that after the second removal process the ferroelectric layer has a surface that protrudes past a surface of the bottom electrode layer and the top electrode layer.

A Semiconductor device includes a semiconductor substrate, an insulating film, a first conductive film, a ferroelectric film, an insulating layer, a first plug and a second plug. The semiconductor substrate includes a source region and a drain region which are formed on a main surface thereof. The insulating film is formed on the semiconductor substrate such that the insulating film is located between the source region and the drain region in a plan view. The first conductive film is formed on the insulating film. The ferroelectric film is formed on the first conductive film. The insulating layer covers the first conductive film and the ferroelectric film. The first plug reaches the first conductive film. The second plug reaches the ferroelectric film. A material of the ferroelectric film includes hafnium and oxygen. In plan view, a size of the ferroelectric film is smaller than a size of the insulating film.

A method includes: providing a substrate including a planar portion and a mesa portion over the planar portion; depositing an oxide layer over the mesa portion; depositing a ferroelectric material strip over the oxide layer and aligned with the mesa portion; and depositing a gate strip crossing the ferroelectric material strip and over the oxide layer.

A memory device structure includes a transistor structure including a gate electrode over a top surface of a fin and adjacent to a sidewall of the fin, a source structure coupled to a first region of the fin and a drain structure coupled to a second region of the fin, where the gate electrode is between the first and the second region. A gate dielectric layer is between the fin and the gate electrode. The memory device structure further includes a capacitor coupled with the transistor structure, the capacitor includes the gate electrode, a ferroelectric layer on a substantially planar uppermost surface of the gate electrode and a word line on the ferroelectric layer.

An alternating electric field-driven gallium nitride (GaN)-based nano-light-emitting diode (nanoLED) structure with an electric field enhancement effect is provided. The GaN-based nanoLED structure forms a nanopillar structure that runs through an indium tin oxide (ITO) layer, a p-type GaN layer, a multiple quantum well (MQW) active layer and an n-type GaN layer and reaches a GaN buffer layer; and the nanopillar structure has a cross-sectional area that is smallest at the MQW active layer and gradually increases towards two ends of a nanopillar, forming a pillar structure with a thin middle and two thick ends. The shape of the GaN-based nanopillar improves the electric field strength within the QW layer in the alternating electric field environment and increases the current density in the QW region of the nanopillar structure under current driving, forming strong electric field gain and current gain, thereby improving the luminous efficiency of the device.

A method for fabricating epitaxial light control features, without reactive ion etching or wet etching, when active layers are included. The epitaxial light control features comprise light extraction or guiding structures integrated on an epitaxial layer of a light emitting device such as a light emitting diode. The light extraction or guiding structures are fabricated on the epitaxial layer using an epitaxial lateral overgrowth (ELO) technique. The epitaxial light control features can have many different shapes and can be fabricated with standard processing techniques, making them highly manufacturable at costs similar to standard processing techniques.