A view angle control device includes light transmission layers that are arranged at intervals and through which light passes, electrochromic layers having light absorption spectrum characteristics according to voltages applied thereto, the electrochromic layers and the light transmission layers being arranged alternately, first electrodes disposed on one side with respect to the electrochromic layers and arranged to be overlapped with the respective electrochromic layers and contacted with the respective electrochromic layers, and a second electrode disposed on an opposite side from the first electrodes with respect to the electrochromic layers and arranged to be overlapped with and contacted with the electrochromic layers.

Disclosed is an electrochromic device including an electrolyte layer having first and second surfaces directed in opposite directions, an electrochromic layer provided on the first surface of the electrolyte layer, a counter electrode layer provided on the second surface of the electrolyte layer, a first transparent electrode layer provided on a surface opposite to the electrolyte layer based on the electrochromic layer, and a second transparent electrode layer provided on a surface opposite to the electrolyte layer based on the counter electrode layer, in which the first and second transparent electrode layers are each provided as a composite layer in which an oxide-based electrode layer made of a material selected from a group consisting of AZO, FTO, and ITO and a metal-based electrode layer made of a material selected from a group consisting of nanowires (AgNWs), PEDOT:PSS, graphene, and a metal mesh are laminated.

Provided is a multilayered thin film transparent electrode for an electrochromic device including: a substrate; a lower oxide layer located on the substrate; a metal layer located on the lower oxide layer; and an upper oxide layer located on the metal layer, and a thickness of a center portion of the metal layer is larger than a thickness of an edge.

A monolithic tandem electrochromic device, comprising a central transparent conductor ion blocking layer, a first electrochromic multilayer stack arranged on a first surface of the central transparent conductor ion blocking layer, and a second electrochromic multilayer stack arranged on a second surface of the central transparent conductor ion blocking layer is described. The central transparent conductor ion blocking layer can comprise ion conductivities between 10.sup.−4 and 10.sup.−20 S/cm, and electrical resistivity less than 100 Ohm-cm.

A long-range electrochromic fiber for infrared camouflage and preparation method thereof are disclosed. The method includes: coating indium tin oxide dispersion, electrolyte solution, and electrochromic material on the surface of the metal fiber sequentially, and preparing counter electrodes and polymer protective layer on the outside of the electrochromic layer to obtain the long-range electrochromic fiber. The obtained long-range electrochromic fiber can realize the regulation of infrared emissivity, can be continuously prepared for more than 100 meters and has a good application prospect in infrared camouflage, wearable display, etc.

An electrochromic device is provided. The device includes a first transparent substrate and a second transparent substrate and a first electrically conductive layer and a second electrically conductive layer. A first bus bar is in contact with the first electrically conductive layer and a second bus bar in contact with the second electrically conductive layer. The first and second electrically conductive layers are patterned with sets of scribed lines substantially parallel to the corresponding bus bar, wherein the sets of scribed lines are made up of a series of collinear segments, which are gaps in the electrically conductive layer, wherein the length of the collinear segments, the period, the valve width and the offset between segments in adjacent scribed lines determines the resistance to the flow of electrons traversing a set of scribed lines in the direction substantially perpendicular to the corresponding bus bar.

Disclosed are an electrochromic photonic-crystal reflective display device and a method of manufacturing the same. The electrochromic photonic-crystal reflective display device includes a substrate having lower electrodes, a first solid polymer electrolyte thin film, a block copolymer photonic-crystal thin film, a second solid polymer electrolyte thin film, and upper electrodes. The first solid polymer electrolyte thin film is formed on the top of the substrate, and is made from a mixed solution including a polymer electrolyte and an ionic liquid. The block copolymer photonic-crystal thin film is formed on the top of the first solid polymer electrolyte thin film. The second solid polymer electrolyte thin film is formed on the top of the block copolymer photonic-crystal thin film, and is made from a mixed solution including a polymer electrolyte and an ionic liquid. The upper electrodes are formed on the top of the second solid polymer electrolyte thin film.

Chromatic systems and structures are presented that operate without external electrical supply, which enable changes in color or transparency of a substrate material, such as glass. Various configurations provide a mechanism to activate an oxidation-reduction reaction in a chromatic material, so as to change from transparent to opaque or from one color to another. These structures may be used in applications from windows for buildings and homes, camera lenses, automotive displays and windows, mobile device displays, and other applications where chromatic change is desired.

Provided is a complex display device Including a first substrate and an opposed second substrate, a first electrode, an electrochromic layer, a common electrode, an emission part and a second electrode, laminated between the first substrate and the second substrate one by one, and an organic layer disposed between the first electrode and the electrochromic layer, or between the electrochromic layer and the common electrode. The organic layer of the complex display device may include at least one of a hole injection material, a hole transport material and a mixture thereof, or at least one of an electron injection material, an electron transport material or a mixture thereof.

A liquid crystal display device includes a first substrate, a second substrate facing the first substrate, a dual passivation layer disposed between the first substrate and the second substrate. The dual passivation layer includes a first passivation layer and a second passivation layer. A refractive index of the first passivation layer is different from a refractive index of the second passivation layer.