A memory device includes a memory cell and a controller. The memory cell includes: (a) an array of molecule chains, at least one molecule chain includes: (i) first and second binding sites positioned at first and second ends of the molecule chain, respectively, and (ii) a chain of one or more fullerene derivatives, chemically connecting between the first and second binding sites, (b) source and drain electrodes, electrically connected to the first and second binding sites, respectively, and configured to apply to the array a source-drain voltage (VSD) along a first axis, and (c) a gate electrode, configured to apply to the array a gate voltage (VG) along a second different axis. The controller is configured to perform a data storage operation in the memory cell by (i) applying to the gate electrode a signal for producing the VG, and (ii) applying the VSD between the source and drain electrodes.

A photovoltaic solar cell apparatus is described herein combining the advantages of several discoveries that address the previously unsolved problem of creating high conversion efficiency solar cells at a low cost. The solar cell designs and underlying principals disclosed herein may be applied in any type of photovoltaic solar power application, such as large scale photovoltaic solar plants, rooftop panels, solar powered electronic devices, and many others.

An organic-inorganic hybrid solar cell and method for manufacturing the same wherein the solar cell includes a first electrode, a first common layer provided on the first electrode, a light absorption layer including a perovskite material provided on the first common layer, a second common layer provided on the light absorption layer, and a conductive adhesive layer provided on the second common layer.

A method of forming a memory device includes the following steps. A plurality of carbon nanotubes are formed over a substrate as a first electrode. An insulating layer is formed over the carbon nanotubes. A graphene is formed over the insulating layer as a second electrode separated from the first electrode by the insulating layer.

The present disclosure generally relates to multi-switch storage cells (MSSCs), three-dimensional MSSC arrays, and three-dimensional MSSC memory. Multi-switch storage cells include a cell select device, multiple resistive change elements, and an intracell wiring electrically connecting the multiple resistive change elements together and to the cell select device. MSSC arrays are designed (architected) and operated to prevent inter-cell (sneak path) currents between multi-switch storage cells, which prevents stored data disturb from adjacent cells and adjacent cell data pattern sensitivity. Additionally, READ and WRITE operations may be performed on one of the multiple resistive change elements in a multi-switch storage cell without disturbing the stored data in the remaining resistive change elements. However, controlled parasitic currents may flow in the remaining resistive change elements within the cell. Isolating each multi-switch storage cell in a three-dimensional MSSC array, enables in-memory computing for applications such as data processing for machine learning and artificial intelligence.

The present disclosure provides a manufacturing method of a thin film transistor, including: selecting a substrate, and forming a bottom gate, a gate insulating layer and a source-drain above the selected substrate, wherein the bottom gate and the source-drain adopts a conductive metal oxide with an adjustable work function as a metal conducting electrode; rinsing and drying the source-drain of the selected substrate, and ozone cleaning dried source-drain for a predetermined time under a predetermined illumination condition, bombarding the source-drain with oxygen plasma for a period of time, forming an active layer made of a carbon material over the source-drain; forming a passivation layer over the active layer. The implementation of the disclosure can reduce the contact resistance and improve the performance of the carbon-based thin film transistor device by adjusting the work function of the contact surface between the conductive metal and the active layer.

A method for manufacturing an organic thin film transistor includes steps of: forming a graphene layer on a surface of a metal substrate; covering a surface of the graphene layer with an organic solution and heating the graphene layer to form organic semiconductor nano lines on the surface of the graphene layer; and transferring the organic semiconductor nano lines to a target substrate. The graphene layer is formed on the surface of the metal substrate in mass production. The organic semiconductor nano lines (monocrystalline semiconductor) are grown in mass production by the graphene layer. The semiconductor layer having organic thin film transistors is formed after transferring the organic semiconductor nano lines on the target substrate. A large amount of the organic semiconductor nano lines can be formed simultaneously on the surface of the metal substrate with a large area.

A method and structure for providing uniform, large-area graphene by way of a transfer-free, direct-growth process. In some embodiments, a SAM is used as a carbon source for direct graphene synthesis on a substrate. For example, a SAM is formed on an insulating surface, and a metal layer is formed over the SAM. The metal layer may serve as a catalytic metal, whereby the SAM is converted to graphene following an annealing process. The SAM is deposited using a VPD process (e.g., an ALD process and/or an MLD process). In some embodiments, a CNT having a controlled diameter may be formed on the surface of a nanorod by appropriately tuning the geometry of the nanorod. Additionally, in some embodiments, a curved graphene transistor may be formed over a curved oxide surface, thereby providing a band gap in a channel region of the graphene transistor.

Provided is a display device. The display device includes a light emitting element layer including a plurality of light emitting elements, and a light control layer on the light emitting element layer and overlapping the light emitting element layer on a plane. At least one of the light emitting elements and the light control layer includes an amorphous carbon light emitter.

The embodiment of this invention lies on experimental evidence of photoconductivity activity of a hybrid solar cell, organic/chalcogenide. The device is made of thin layers of conductive indium-tin-oxide (ITO) on glass with a 100 nm layer of chalcogenide molybdenum di-sulfide (MoS2) and a thin layer of about 50 nm of complex organic compound assembled at room temperature. The device was tested to conventional electrical transport measurements in the regime of 1V to 1V under electromagnetic radiation simulator at 100 mW/cm2. Results indicate solar conversion efficiency of 2.48% and current density of 6.35 mA/cm2.