Described is a flowable preparation for depositing a passivation layer on an organic electronic (OE) device containing an organic layer; the organic layer is selected from an organic semiconductor (OSC) layer and an organic gate insulator (OGI) layer; the preparation comprises a passivating material and a solvent; the solvent includes lactate and/or derivatives thereof. Further described are an OE device and a manufacture method therefor.

A transistor manufacturing method includes forming a source electrode and a drain electrode on a substrate, forming a layer including an insulator layer to cover the source electrode and the drain electrode, and forming a gate electrode on the layer including the insulator layer, wherein the forming the gate electrode includes forming a plating base film, forming a protection layer of the plating base film, forming a photoresist layer on the protection layer to expose the photoresist layer with desired patterning light, causing the exposed photoresist layer to come into contact with a developer to remove the photoresist layer and the protection layer until the plating base film is uncovered corresponding to the patterning light, and after depositing a metal on the uncovered plating base film, causing an electroless plating solution to come into contact with the plating base film to perform electroless plating.

A display device according to an embodiment of the present invention includes: a base material including a display region and a curved region; a wiring line disposed on the base material and disposed from the display region over the curved region; and a heat dissipating layer formed corresponding to a position at which the wiring line is disposed in the curved region.

A biosensor for an analyte monitoring system. In one embodiment, the biosensor includes a cascode common source transimpedance amplifier circuit, an analog to digital converter, and an output circuit. The cascode common source transimpedance amplifier circuit is configured to receive an electrical current generated by an electrochemical reaction of an analyte on a test strip. The cascode common source transimpedance amplifier circuit is also configured to convert the electrical current to an analog voltage signal. The analog to digital converter is configured to convert the analog voltage signal to a digital voltage signal. The output circuit is configured to transmit a signal indicating a measured level of the analyte based on the digital voltage signal.

A method is disclosed for aligning layers in fabricating a multilayer printable electronic device. The method entails providing a transparent substrate upon which a first metal layer is deposited, providing a transparent functional layer over the first metal layer, depositing metal nano particles over the functional layer to form a second metal layer, exposing the metal nano particles to intense pulsed light via an underside of the substrate to partially sinter exposed particles to the functional layer whereby the first metal layer acts as a photo mask, and washing away unexposed particles using a solvent to leave partially sintered metal nano particles on the substrate.

A display device according to an embodiment of the present invention includes: a base material including a display region and a curved region; a wiring line disposed on the base material and disposed from the display region over the curved region; and a heat dissipating layer formed corresponding to a position at which the wiring line is disposed in the curved region.

Provided are an organic thin film transistor, an organic semiconductor film, a compound, an organic thin film transistor-forming composition, and a method of manufacturing the organic thin film transistor. The organic thin film transistor includes the organic semiconductor film. The organic semiconductor film includes a compound represented by a specific formula. The organic semiconductor film, the compound, and the organic thin film transistor-forming composition can be preferably used in the organic thin film transistor. The method of manufacturing the organic thin film transistor includes a step of forming an organic semiconductor film by applying the organic thin film transistor-forming composition to a substrate.

The present disclosure provides a display panel and an electronic device. The display panel comprises: a substrate, wherein a metal layer and an anti-reflection film are disposed on the substrate, the anti-reflection film is disposed on a light-emitting side of the metal layer, and the anti-reflection film comprises a protective layer and a darkening layer; wherein the protective layer is disposed between the darkening layer and the metal layer, and a material of the darkening layer comprises at least one of Mo.sub.aX.sub.bO.sub.c, Mo.sub.aX.sub.bN.sub.d, Mo.sub.aX.sub.bO.sub.cN.sub.d, Mo.sub.aX.sub.bW.sub.c, Mo.sub.aX.sub.bC.sub.c, or Al.sub.aO.sub.bN.sub.c, wherein a, c, and d are rational numbers greater than 0, b is a rational number greater than or equal to 0, and X is at least one of tantalum, vanadium, nickel, niobium, zirconium, tungsten, titanium, rhenium, or hafnium. The display panel and the electronic device of the present disclosure can improve display effect and display quality.

A technique, comprising: removing a protective film from one side of a polarisation filter component to expose a dichroic doped polymer active film or a layer formed in situ on the dichroic doped polymer active film; and thereafter forming in situ on the side of the polarisation filter component one or more functional layers of a liquid crystal device.

The present invention provides compounds comprising at least one unit of formula (1) or (1′) as well as a process for the preparation of the compounds, intermediates of this process, electronic devices comprising the compounds, and the use of the compounds as semiconducting materials. ##STR00001##