A method for laterally confining neutral excitons in a semiconductor layer structure (11) of a solid-state device comprises creating an inhomogeneous electric field (F) in the semiconductor layer structure (11), the electric field (F) having an in-plane field component (F.sub.x) whose magnitude varies along at least at least one confinement direction (x) in the device plane, the magnitude of the in-plane field component (F.sub.x) having a maximum along the confinement direction (x). In this manner a lateral confining potential (V(x)) for neutral excitons is caused around the maximum. The solid-state device (10) is irradiated with light to create neutral excitons in the semiconductor layer structure (11). The neutral excitons are laterally confined along the confinement direction (x) by the lateral confining potential (V(x)).

A photodetecting device and method of using the same are provided. Light is used to irradiate the optical filter layer of the photodetecting device and positions of the electrons and the holes in the polycrystalline silicon nano-channel layer are rearranged by the light with a wavelength range capable of passing through the optical filter layer. The current between the source and the drain is changed by rearranging the positions of the electrons and the holes, so as to generate a current difference. The intensity of the light is calculated by the current difference.

A photovoltaic photodetector includes a substrate, a graphene layer, and a dielectric layer positioned between the substrate and the graphene layer. One or more first antenna electrodes includes a first metal in direct contact with the graphene layer. One or more second antenna electrodes includes a second metal in direct contact with the graphene layer. The first and second metals have different work functions. A drain electrode is electrically coupled to the one or more first antenna electrodes, and a source electrode is electrically coupled to the one or more second antenna electrodes. The photovoltaic photodetector can be configured to be operable over a wavelength region of 2 m to 24 m and has a response time of 10 ns or less.

An organic light emitting diode display device includes a substrate, a plurality of organic light emitting diodes on the substrate, a thin film encapsulation layer on the organic light emitting diodes, and at least one sensor on the thin film encapsulation layer, the sensor including a sensing gate electrode, an oxide semiconductor layer overlapping the sensing gate electrode, a sensing source electrode connected to the oxide semiconductor layer, and a sensing drain electrode spaced apart from the sensing source electrode and connected to the oxide semiconductor layer.

A near infrared light sensor includes a 2D material semiconductor layer on a substrate, a tunneling layer on the 2D material semiconductor layer, and first and second electrodes on opposite edge regions of an upper surface of the tunneling layer. The 2D material semiconductor layer may be a TMDC layer having a thickness in a range of about 10 nm to about 100 nm. The tunneling layer and the substrate may each include hBN.

A photodetecting device and method of using the same are provided. The photodetecting device includes a transistor, a silicon nano-channel and a filter dye layer. The transistor includes a source, a drain and a gate. The silicon nano-channel connects the source and the drain, and is configured to receive light. The filter dye layer is over a light-receiving surface of the silicon nano-channel.

A photoelectric semiconductor nanowire device and a method for manufacturing the same. The photoelectric semiconductor nanowire device includes a semiconductor nanowire doped with a dopant of a first conductivity type and including crystal semiconductor segments which include at least one porous semiconductor segment and are connected to opposite ends of the porous semiconductor segment. A first electrode and a second electrode respectively are disposed in the crystal semiconductor segments around the porous semiconductor segment to provide an electrical connection. The crystal semiconductor segment includes a crystal semiconductor, and the porous semiconductor segment includes a porous semiconductor. The semiconductor nanowire provides a current according to the intensity of an external light when the external light is irradiated to the porous semiconductor segment.

A photoelectric conversion device may include a substrate, a photoactive layer disposed on the substrate, and a first electrode and a second electrode respectively connected to corresponding edges of the photoactive layer. The photoactive layer may include a first oxide semiconductor layer on the substrate, and a plurality of quantum dot layers and a plurality of second oxide semiconductor layers that are alternately formed on the first oxide semiconductor layer.

A two-terminal photon-effect transistor (PET) is described that simplifies the photo sensing pixel by combing photodiode and field effect transistor dual functions into one simple but effective unit. Photons excite electrons from the valance band of semiconducting material as the electrode-free gate to modulate resistivity between source and drain, which directly results in current amplification of photo signal without traditional photo-electrical conversion and electrical amplification dual processes. PET possesses significance in both structural simplification and functional enhancement. As an implementing example of PET, a nanowire camera (NC) with large sensing area and extremely high resolution is fabricated by integrating millions of vertically aligned nanowire arrays in-between of orthogonal top and bottom nano-stripe electrodes. Each nanowire works as independent three-dimensional (3D) PET pixel, enabling the NC an ultra-high resolution and much simplified architecture. NC has pixel size of 50 nm which is two orders higher than existing CCD and CMOS image sensors.

An apparatus and method of forming an apparatus, the apparatus comprising: a graphene field effect transistor where the graphene field effect transistor comprises a graphene channel and quantum dots provided overlaying the graphene channel, wherein the quantum dots comprise a first layer comprising quantum dots connected to a first ligand and a second layer comprising quantum dots connected to a second ligand, and wherein the first ligand is configured to cause the first layer to have a first refractive index and the second ligand is configured to cause the second layer to have a second refractive index wherein the second refractive index is different to the first refractive index.