Abstract: Electrochromic device laminates and their method of manufacture are disclosed.

Abstract: Electrochromic device laminates and their method of manufacture are disclosed.

Abstract: Electrochromic device laminates and their method of manufacture are disclosed.

Abstract: Electrochromic device laminates and their method of manufacture are disclosed.

Abstract: Electrochromic device laminates and their method of manufacture are disclosed.

Abstract: Electrochromic device laminates and their method of manufacture are disclosed.

Abstract: Electrochromic device laminates and their method of manufacture are disclosed.

Abstract: Electrochromic device laminates and their method of manufacture are disclosed.

Abstract: Electrochromic device laminates and their method of manufacture are disclosed.

Abstract: Electrochromic device laminates and their method of manufacture are disclosed.

Abstract: Electrochromic device laminates and their method of manufacture are disclosed.

Abstract: Electrochromic device laminates and their method of manufacture are disclosed.

Abstract: A sealed insulated glass unit is provided with an electrochromic device for modulating light passing through the unit. The electrochromic device is controlled from outside the unit by a remote control electrically unconnected to the device. Circuitry within the unit may be magnetically controlled from outside. The electrochromic device is powered by a photovoltaic cells. The photovoltaic cells may be positioned so that at least a part of the light incident on the cell passes through the electrochromic device, providing a form of feedback control. A variable resistance placed in parallel with the electrochromic element is used to control the response of the electrochromic element to changes in output of the photovoltaic cell.

Abstract: Electrochromic devices are disclosed which may be used for large surface area applications. The devices utilize optical tuning to minimize optical interference between layers of the structure and to maximize uniform optical transparency. Optical tuning also enables transparent conductive oxide layers to be replaced by thin conductive metal layers, thereby reducing the overall thickness of these devices and facilitating the manufacturing process.

Abstract: Electrochromic devices are disclosed which may be used for large surface area applications. The devices utilize optical tuning to minimize optical interference between layers of the structure and to maximize uniform optical transparency. Optical tuning also enables transparent conductive oxide layers to be replaced by thin conductive metal layers, thereby reducing the overall thickness of these devices and facilitating the manufacturing process.

Abstract: Electrochromic devices applied to a substrate are disclosed, including an electrochromic electrode layer, a counterelectrode layer, and an ion-conducting layer sandwiched between those two layers and electrically isolating them from each other, in which the ion-conducting layer is substantially uniform across the substrate and comprises an inorganic superstructure with associated organic material and with a microstructure which facilitates the transfer of ions. Methods for producing these devices are also disclosed, including depositing the ion-conducting layer on the substrate in the form of a solution, and effecting gelation of that solution.

Abstract: Electrochromic devices applied to a substrate are disclosed, including an electrochromic electrode layer, a counterelectrode layer, and an ion-conducting layer sandwiched between those two layers and electrically isolating them from each other, in which the ion-conducting layer is substantially uniform across the substrate and comprises an inorganic superstructure with associated organic material and with a microstructure which facilitates the transfer of ions. Methods for producing these devices are also disclosed, including depositing the ion-conducting layer on the substrate in the form of a solution, and effecting gelation of that solution.

Abstract: The invention provides for the simplified production of chromogenic devices, including relatively large scale devices in panel form. One or more of the layers of the invention are formed from heated, hydrolyzed gel reaction product of one or more dissolved organo-inorganics, such as alkoxides, which may be metallic. The invention includes an ion-conducting layer which comprises a lithium based ceramic material containing residual organic impurities.

Abstract: A chromogenic device with a chromogenic material facing a conductive layer, in which the transmission of incident radiation through the conductive layer and the chromogenic material is enhanced. The enhancement is achieved by adjusting indices of refraction of layers embracing the conductive layer.

Abstract: Directed energy conversion of semiconductors by the directed energy fusion of a selective region of a semiconductor layer to provide a conductive path through the layer. A conductive path is formed through a semiconductive layer through opposed electrodes by conversion of the semiconductive region, for example, by laser energy applied to change the structure in the region extending between the electrodes. The change in conductivity of the path is monitored and used to control the formation of the conductive path by controlling the directed energy source.