The invention describes a device for emitting or detecting electromagnetic radiation. The device has a first and a second electrode which are connected to each other via an electrically conductive nanostructure. The electrically conductive nanostructure is configured to receive electrons and holes from the first and second electrode or transport same to the first and second electrode. In addition, the device has a radiation molecule arranged at a circumferential surface of the electrically conductive nanostructure. The radiation molecule is configured to absorb electrons and holes or electromagnetic radiation and emit the electromagnetic radiation with recombination of electrons absorbed and holes absorbed, or emit electrons and holes based on the electromagnetic radiation absorbed. The electrically conductive nanostructure is, in the region of a circumferential surface, surrounded at least partly by the first or second electrode at an end arranged at the first or second electrode in order to provide electrical contact of the first or second electrode and the electrically conductive nanostructure.

The present invention provides an array substrate, a method for manufacturing the array substrate, and a display panel. The array substrate includes a driving transistor, and the driving transistor includes: a gate electrode; an active layer arranged opposite to a position of the gate electrode, the active layer includes a first semiconductor and second semiconductors, the second semiconductors are in contact with the first semiconductor to form a first PN junction and a second PN junction respectively, and the first PN junction corresponds to the source electrode; and a source drain layer, including a source electrode and a drain electrode. The second semiconductors are electrically connected with the source electrode and drain electrode, respectively.

Embodiments of a method for packaging Integrated Circuit (IC) dies and an IC device are described. In an embodiment, a method for packaging IC dies involves creating openings on a substrate, where side surfaces of the openings on the substrate are covered by metal layers, placing the IC dies into the openings on the substrate, applying a second metal layer to the substrate, where the IC dies are electrically connected to at least a portion of the second metal layer, and cutting the substrate into IC devices.

Certain examples include an elastic transistor having multiple layers, as a monolithic IC, to provide a stretchable high-k multi-layer dielectric that in response to a low-drive voltage, operates to provide (stable or steady-state) operation. The stretchable layers include: a high-k dielectric layer, and another dielectric layer, with the high-k dielectric layer being between the gate of the elastic transistor and the other dielectric layer. More-specific examples, useful in combination, have two types of the above-characterized elastic transistors cooperatively arranged and respectively implemented as a semiconductor with multiple different dielectric materials and as a synaptic transistor with the high-k dielectric layer including a border interface region characterized as one of a polycation interface and a polyanion interface and with the other dielectric layer corresponding to an interfacial portion along an outer border of the high-k dielectric layer.

A compound, an organic light-emitting device, and a flat panel display apparatus, the compound being represented by the following Formula 1: ##STR00001##

An electronic element (10) comprising a plurality of cells (100) arranged in a three dimensional array of cells (100) is provided, wherein the cells (100) are located at crossings between two crossed electrode lines (30, 31). Each cell (100) of the electronic component (100) comprises in this order a first electrode (102), a part (104) of a molecular layer (20) and a second electrode (106), wherein the molecular layer (20) is a self-assembled monolayer of organic molecules having an anchoring group connected to a dipolar unit by means of a conformationally flexible unit.

Further aspects of the invention relate to a method and a compound for producing such an electronic element (10) and the use of such an electronic element (10).

A logic-gated protein device in which proximity-gated protein trans-splicing governs formation of an active protein from two otherwise inactive fragments.