An imaging element includes an organic photoelectric conversion layer formed of a mixture of an electron transport material, an organic pigment material, and a hole transport material. The electron transport material has higher electron mobility than the organic pigment material. The hole transport material has higher hole mobility than the organic pigment material. A relation between values of electron affinity of the electron transport material and the organic pigment material, a relation between values of ionization potentials of the hole transport material and the organic pigment material, and a relation between a value of the electron affinity of the electron transport material and a value of an ionization potential of the hole transport material have predetermined relations.

A photoelectric conversion device, comprising a semiconductor substrate on which a plurality of pixels are arrayed, and an insulating member which is transparent and configured to cover the semiconductor substrate, wherein the insulating member includes at least three portions whose thickness are different from each other so as to increase types of wavelengths of light that are to be ripple reduction targets.

Disclosed herein is a laminated structure including a first layer covering a substrate and a raised portion existing on the substrate, and a second layer covering the first layer, in which a first seam is formed inside the first layer, starting from a part at which the raised portion rises from the substrate or a vicinity of the rising part as a start point, a second seam is formed inside the second layer, starting from a part at which the first layer positioned above the substrate rises or a part of the second layer corresponding to a vicinity of the rising part as a start point, and the first seam and the second seam are discontinuous.

The present disclosure relates to a solid-state imaging device, a method for driving the solid-state imaging device, and an electronic device capable of improving auto-focusing accuracy by using a phase difference signal obtained by using a photoelectric conversion film. The solid-state imaging device includes a pixel including a photoelectric conversion portion having a structure where a photoelectric conversion film is interposed by an upper electrode on the photoelectric conversion film and a lower electrode under the photoelectric conversion film. The upper electrode is divided into a first upper electrode and a second upper electrode. The present disclosure can be applied to, for example, a solid-state imaging device or the like.

A solid-state imaging device includes a photoelectric conversion element. The photoelectric conversion element includes a first electrode, an electron transport layer, and a photoelectric conversion layer. The first electrode is disposed on a substrate and the photoelectric conversion layer is disposed on the first electrode. The electron transport layer is disposed between the first electrode and the photoelectric conversion layer and includes a buffer layer and a particulate layer. The buffer layer has an ionization potential larger than a work function of the first electrode and an electron affinity larger than the photoelectric conversion layer. Then, the particulate layer includes particulates that contain conductive zinc oxide as a main component.

A photoelectric conversion device of an embodiment includes: a first photoelectric conversion part including a first transparent electrode provided on a transparent substrate, a first active layer, and a first counter electrode; and a second photoelectric conversion part including a second transparent electrode, a second active layer, and a second counter electrode. A conductive layer containing noble metal as a main component is formed on a partial region of the second transparent electrode, and a fine particle layer having a stack of fine particles is formed on the conductive layer. The first counter electrode and the second transparent electrode are electrically connected by a connection part having a scribe groove penetrating through the fine particle layer from the second active layer and exposing a surface of the conductive layer, and a conductive layer having a part of the first counter electrode filled in the scribe groove.

By introducing new concepts into a structure of a conventional organic semiconductor element and without using a conventional ultra thin film, an organic semiconductor element is provided which is more reliable and has higher yield. Further, efficiency is improved particularly in a photoelectronic device using an organic semiconductor. Between an anode and a cathode, there is provided an organic structure including alternately laminated organic thin film layer (functional organic thin film layer) realizing various functions by making an SCLC flow, and a conductive thin film layer (ohmic conductive thin film layer) imbued with a dark conductivity by doping it with an acceptor and a donor, or by the like method.

The present disclosure relates to a nano-scale transistor. The nano-scale transistor includes a source electrode, a drain electrode, a gate electrode and a nano-heterostructure. The nano-heterostructure is electrically coupled with the source electrode and the drain electrode. The gate electrode is insulated from the nano-heterostructure, the source electrode and the drain electrode via an insulating layer. The nano-heterostructure includes a first carbon nanotube, a second carbon nanotube and a semiconductor layer. The semiconductor layer includes a first surface and a second surface opposite to the first surface. The first carbon nanotube is located on the first surface, the second carbon nanotube is located on the second surface.

A measuring system comprises a substrate (IO), which has a quantum dot layer, which is arranged on the substrate and which comprises an emission segment having a first plurality of quantum dots, which first plurality has an average first energy gap, wherein the first plurality can emit radiation corresponding to the average first energy gap, wherein the quantum dot layer comprises at least one absorption segment having a laterally located second plurality of quantum dots and the second plurality has an average second energy gap that is less than the average first energy gap so that radiation emitted by the emission segment can be absorbed by the at least one absorption segment.

A method of fabricating a multicolor light-emitting diode (LED) display includes forming a first LED layer on a first release layer comprising a first two-dimensional (2D) material disposed on a first substrate. The first LED layer is configured to emit light at a first wavelength. The method also includes transferring the first LED layer from the first release layer to a host substrate and forming a second LED layer on a second release layer comprising a second 2D material disposed on a second substrate. The second LED layer is configured to emit light at a second wavelength. The method also includes removing the second LED layer from the second release layer and disposing the second LED layer on the first LED layer.