An AC electroluminescent power cord includes at least two electrode wires and a luminescent layer. The electrode wire is coated with the luminescent layer; the transparent or translucent plastic layer is coated on an outer wall of the luminescent layer; and each of the at least one electrode wire includes at least one metal wire; the at least two electrode wires are insulated with each other. When the electrode wires are conducted with an AC power source, the luminescent layer emits light. The AC electroluminescent power cord of the disclosure not only has a simple and reliable structure, but also has a display function. When applied for various electronic devices, the AC electroluminescent power cord of the disclosure integrally emits light or sequentially emits light in sections to simulate and display the current flow.

An AC electroluminescent power cord includes at least two electrode wires and a luminescent layer. The electrode wire is coated with the luminescent layer; the transparent or translucent plastic layer is coated on an outer wall of the luminescent layer; and each of the at least one electrode wire includes at least one metal wire; the at least two electrode wires are insulated with each other. When the electrode wires are conducted with an AC power source, the luminescent layer emits light. The AC electroluminescent power cord of the disclosure not only has a simple and reliable structure, but also has a display function. When applied for various electronic devices, the AC electroluminescent power cord of the disclosure integrally emits light or sequentially emits light in sections to simulate and display the current flow.

A light-emitting device includes a first electrode, a second electrode facing the first electrode, a light-emitting layer provided between the first electrode the second electrode and including a phosphor, a layered body including a metal layer, a first insulating layer provided on a second electrode side of the metal layer, and a second insulating layer provided on a light-emitting layer side of the metal layer, and having a thickness that allows electron injection from the second electrode to the light-emitting layer, a first power supply configured to apply a voltage between the first electrode and the second electrode, and a second power supply configured to apply, between the metal layer and the second electrode, a voltage of which polarity of the second polarity is opposite to a polarity of the second electrode of a voltage applied by the first power supply between the first electrode and the second electrode.

Various embodiments of solid state transducer (“SST”) devices are disclosed. In several embodiments, a light emitter device includes a metal-oxide-semiconductor (MOS) capacitor, an active region operably coupled to the MOS capacitor, and a bulk semiconductor material operably coupled to the active region. The active region can include at least one quantum well configured to store first charge carriers under a first bias. The bulk semiconductor material is arranged to provide second charge carriers to the active region under the second bias such that the active region emits UV light.

Various embodiments of solid state transducer (“SST”) devices are disclosed. In several embodiments, a light emitter device includes a metal-oxide-semiconductor (MOS) capacitor, an active region operably coupled to the MOS capacitor, and a bulk semiconductor material operably coupled to the active region. The active region can include at least one quantum well configured to store first charge carriers under a first bias. The bulk semiconductor material is arranged to provide second charge carriers to the active region under the second bias such that the active region emits UV light.

A composite material, quantum dot light-emitting diode and preparation method thereof. The preparation method includes: providing ZnO nanoparticles and Au source, Au source is at least one of bulk Au or Au particles; mixing ZnO nanoparticles, Au source, S source with first organic solvent, performing hydrothermal reaction to prepare composite material. By performing hydrothermal reaction in organic solvent using ZnO nanoparticles, bulk Au and/or Au particles, and S source, S source can vulcanize surface of ZnO nanoparticles to form ZnS layer on surface of ZnO nanoparticles, Au source can be thermally dissolved and diffused into isolated distribution of atomic-level Au to realize loading on surface of ZnS layer, to obtain composite material with ZnO nanoparticles as core material, ZnS and Au as shell material. ZnS and Au in composite material can synergistically increase electron transmission efficiency of LED adopting same.

A pixel circuit, a drive method, a display substrate, and a display device are provided. The pixel circuit includes a light emitting device, a current supply sub-circuit, and a time control sub-circuit. The current supply sub-circuit is connected to a scanning signal terminal, a data signal terminal, a light emitting control terminal, a first power voltage terminal, the time control sub-circuit, and the light emitting device, and is configured to receive a data voltage of the data signal terminal and provide a drive current for the light emitting device. The time control sub-circuit is connected to the scanning signal terminal, a time length signal terminal, a second power voltage terminal, a direct current control signal terminal, and a direct current voltage terminal, and is configured to receive a time length voltage of the time length signal terminal and a direct current voltage input by the direct current voltage terminal.

The present invention overcomes image defects such as the brightness inclination or smears by reducing the line resistance of a power source bus line which supplies electricity to organic EL elements. A plurality of pixels which are arranged in a matrix array is connected to power source lines, and the plurality of power source lines are connected to a power source bus line. Both ends of the power source bus line are connected to a power source part via a FPC. By supplying electricity to both ends of the power source bus line from the power source part, the line resistance of the power source bus line can be reduced.

The present invention overcomes image defects such as the brightness inclination or smears by reducing the line resistance of a power source bus line which supplies electricity to organic EL elements. A plurality of pixels which are arranged in a matrix array is connected to power source lines, and the plurality of power source lines are connected to a power source bus line. Both ends of the power source bus line are connected to a power source part via a FPC. By supplying electricity to both ends of the power source bus line from the power source part, the line resistance of the power source bus line can be reduced.

A mounting frame may be configured as a self-adjusting mounting frame that biases itself against a surface of structure. The mounting frame may be a component, for example, of a remote control device or a faceplate assembly. The mounting frame may be configured to bias a rear surface of the mounting frame against the surface of a structure. The mounting frame may include biasing members. Each biasing member may include an attachment portion and a pair of resilient spring arms that suspend the attachment portion relative to a perimeter wall of the mounting frame such that the attachment portion is spaced further from the rear surface of the mounting frame than locations where the spring arms extend from the mounting frame. The rear surface of the mounting frame may be defined by the perimeter wall.