Abstract: The present application provides an electrochromic device, which comprises a first substrate layer, a first conductive layer, a solid-state color changing layer, a second conductive layer and a second substrate layer which are stacked in sequence. A varnish layer is disposed at an edge region of the first conductive layer and/or an edge region of the second conductive layer. The Dyne value of the varnish layer minus the surface tension of a slurry of a structure layer in the solid-state color changing layer which is in contact with the first conductive layer or the second conductive layer is less than or equal to 5 mN/m. Since the varnish layer is arranged, when the solid-state color changing layer is coated, the slurry of the solid-state color changing layer cannot be attached to the varnish surface. Therefore, wiping is not required, and a number of problems caused by wiping are avoided. Otherwise, the adhesion of the solid-state color changing layer to the varnish surface is reduced.

Abstract: A thermally stable and solvent resistant conductive polymer composite and its manufacturing friendly preparation method are disclosed. The disclosed composite presents great electrical conductivity with thermal stability and solvent resistance. A method of mixing a host thiophene conjugated polymer and a crosslinkable silane precursor simultaneously introduces both dopant and rigid cross-linked siloxane network into polymer system. The thin film made by the disclosed thermally stable and solvent resistant conductive polymer composite can be applied to fabricate various devices.

Abstract: Provided is an electrochromic device. The electrochromic device includes a first additional layer, a first base layer, an electrochromic layer, a second base layer, and a second additional layer stacked in sequence. Two ends of the electrochromic layer are flush with two ends of the first base layer. Two ends of the second base layer and two ends of the second additional layer are disposed beyond the two ends of the electrochromic layer. A first sealing element is disposed around the electrochromic layer and on the second base layer.

Abstract: An electrochromic device having the adjustable reflectivity, and an electronic terminal comprising same. The electrochromic device comprises a first transparent substrate layer (1), an electrochromic stack (2), a metal ion stack (3), and a second substrate layer (4) which are stacked in sequence. The electrochromic stack (2) comprises a first transparent conductive layer (21) and a first electrochromic functional layer (22) which are stacked. The metal ion stack (3) comprises a second transparent conductive layer (31), a metal ion layer (32), and an electrodeposition suppression layer (33) which are stacked in sequence. The first electrochromic functional layer (22) is adjacent to the electrodeposition suppression layer (33). The visual effect of the electrochromic device is enhanced by the cooperation of the change in the transmittance of the electrochromic stack (2) and the change in the reflectivity of the metal ion stack (3).

Abstract: A method of making an electrochromic device, includes: providing an electrochromic layer comprising a p-type electrochromic material; providing an ion-storage layer comprising an n-type metal oxide; and tuning the ion-storage layer, the electrochromic layer, or both the ion-storage layer and the electrochromic layer, so that when the electrochromic device is operating, the ion-storage layer operates in a minimally color changing mode.

Abstract: An electrochromic device and an electrochromic method therefor are disclosed. The electrochromic device comprises a first substrate, a first transparent conductive layer, a first electrochromic layer, an electrolyte layer, a second electrochromic layer, a second transparent conductive layer, and a second substrate which are sequentially stacked. Both the first electrochromic layer and the second electrochromic layer are made of a cathode electrochromic material or made of an anodic electrochromic material. The electrochromic method for the electrochromic device comprises: circularly applying a voltage having a direction opposite to and same as that of a first voltage to a pretreated electrochromic device.

Abstract: An electrochromic aperture, which comprises a first transparent substrate (11), a first transparent conductive layer (12), an ion storage layer (13), an ion transfer layer (14), an electrochromic layer (15), a second transparent conductive layer (16), and a second transparent substrate (17). The ion transfer layer (14) is a solid electrolyte layer. Also provided is a method for manufacturing the electrochromic aperture, relating to an etching operation after coating on the ion storage layer (13) and the electrochromic layer (15) is finished. Also provided is a lens modules having the electrochromic aperture.

Abstract: A control method for the an electrochromic device includes: determining whether a current transmittance of the electrochromic device reaches a preset transmittance; when determining that the current transmittance does not reach the preset transmittance, controlling an external power supply to perform a first mode charging and discharging on the electrochromic device until the current transmittance reaches the preset transmittance; when determining that the current transmittance reaches the preset transmittance, suspending the charging and discharging, and continuously monitoring whether a current open circuit potential of the electrochromic device is within a preset open circuit potential threshold range; and if the current open circuit potential is not within the preset open circuit potential threshold range, controlling the external power supply to perform a second mode charging and discharging on the electrochromic device to enable the current open circuit potential to be continuously within the preset ope

Abstract: An electrochromic device, a preparation method therefor and an application thereof are disclosed. The electrochromic device comprises a first conductive layer, a color-changing layer and a second conductive layer that are arranged in succession, wherein at least one first electrode lead is connected on the first conductive layer, and the first electrode lead passes through the color-changing layer and the second conductive layer; and at least one second electrode lead is connected on the second conductive layer, and the second electrode lead passes through the color-changing layer and the first conductive layer. The electrochromic device can achieve the application of the electrochromic device under the premise that the two conductive layers are not staggered, and on the basis of implementing electrochromism, the technical effect of gradual color change can be achieved by means of changing the magnitude of the power supply voltage and/or current.

Abstract: A thermally stable and solvent resistant conductive polymer composite and its manufacturing friendly preparation method are disclosed. The disclosed composite presents great electrical conductivity with thermal stability and solvent resistance. A method of mixing a host thiophene conjugated polymer and a crosslinkable silane precursor simultaneously introduces both dopant and rigid cross-linked siloxane network into polymer system. The thin film made by the disclosed thermally stable and solvent resistant conductive polymer composite can be applied to fabricate various devices.

Abstract: Black-to-transmissive electrochromic polymers have superior properties such as absorbance of across the entire visible spectrum and an obvious color change from black to transmissive with an applied voltage. Methods for synthesizing or using the same include contacting monomers under polymerization conditions. Black-to-transmissive electrochromic polymer thin films include the black-to-transmissive electrochromic polymers, and electrochromic devices include the black-to-transmissive electrochromic polymers or thin films.

Abstract: Various photocrosslinkable electrochromic polymers are disclosed. The polymers are suitable for an electrochromic layer of an electrochromic device. The polymers are formed with a two-step synthesis method that includes forming a polymer precursor with one or more chromophore blocks, and mixing the polymer precursor with photocrosslinkable monomer units to form the polymer.

Abstract: A thermally stable and solvent resistant conductive polymer composite and its manufacturing friendly preparation method are disclosed. The disclosed composite presents great electrical conductivity with thermal stability and solvent resistance. A method of mixing a host conjugated polymer and a crosslinkable silane precursor simultaneously introduces both dopant and rigid cross-linked siloxane network into polymer system. The thin film made by the disclosed thermally stable and solvent resistant conductive polymer composite can be applied to fabricate various devices.

Abstract: A method of making an electrochromic device, includes: providing an electrochromic layer comprising a p-type electrochromic material; providing an ion-storage layer comprising an n-type metal oxide; and tuning the ion-storage layer, the electrochromic layer, or both the ion-storage layer and the electrochromic layer, so that when the electrochromic device is operating, the ion-storage layer operates in a minimally color changing mode.

Abstract: Ion-storage layers for electrochromic devices (ECDs) that are tuned to be minimally color changing (MCC) during operation of the ECDs. In some embodiments, an ion-storage layer is composed of an n-type metal oxide that complements a p-type electrochromic (EC) layer, such as an EC layer made of a p-type EC polymer. In some embodiments, an ion-storage layer may be tuned to be MCC by configuring an ion-storage layer to have a total charge density that is higher than the total charge density of a corresponding EC layer or to have a coloration efficiency lower than the coloration efficiency of the corresponding EC layer, or both. Methods for preparing ion-storage layers are disclosed, including methods for creating highly structured metal oxide having reduced coloration efficiencies. ECD devices incorporating MCC ion-storage layers are also disclosed.

Abstract: An electrochromic device includes a first flexible substrate, a first transparent electrode disposed on the first flexible substrate, an electrochromic layer disposed on the first transparent electrode, and a solid electrolyte layer disposed on the electrochromic layer. The solid electrolyte layer contains less than 20 wt % of neutral small organic molecules having a molecular weight of 3000 or less. The electrochromic device further includes an ion storage layer disposed on the solid electrolyte layer, a second transparent electrode disposed on the ion storage layer, and a second flexible substrate disposed on the second transparent electrode.

Abstract: The disclosure relates generally to electrochromic devices wherein the self-bleaching behavior of an electrochromic polymer (ECP) film is suppressed, and related methods. In some embodiments, provided are ECP films on modified transparent conductive oxide substrates, such as a partially octadecyltrichlorosilane (OTS) covered indium tin oxide (ITO) substrate (POTS-ITO substrate), methods of preparing the ECP films, and electrochromic devices comprising the films.

Abstract: An electrochromic apparatus includes a first glass, a first adhesive layer disposed on the first glass, a second glass, a second adhesive layer disposed on the second glass, a solid-state electrochromic device (ECD) interposed between the first adhesive layer and the second adhesive layer, and a sealant disposed at edges of the first glass and the second glass to seal the ECD. The first adhesive layer and the second adhesive layer are disposed between the first glass and the second glass. The first adhesive layer and the second adhesive layer are optically transparent. Edges of the adhesive layers are flush with or beyond edges of the ECD. The sealant is adhesive and waterproof.