• Title of article

    Degradation studies of electrochromic all-solid-state switchable mirror glass under various constant temperature and relative humidity conditions

  • Author/Authors

    Tajima، نويسنده , , Kazuki and Hotta، نويسنده , , Hiromi and Yamada، نويسنده , , Yasusei and Okada، نويسنده , , Masahisa and Yoshimura، نويسنده , , Kazuki، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2010
  • Pages
    5
  • From page
    2411
  • To page
    2415
  • Abstract
    We have developed an electrochromic switchable mirror that consists of all-solid-state thin films. The device can be switched between reflective and transparent states by applying a voltage. This device can potentially be applied to new energy-saving windows because the reflective state of the mirror can effectively control the solar radiation coming into a room. To realize such practical applications, the effects of environmental factors such as temperature and humidity on the optical switching properties of the device should be investigated in detail. In this work, we evaluated the effects of the environment on the device for various constant temperature and relative humidity conditions, which were controlled by a thermostat/humidistat bath. When the device was stored at 50 °C and 80% relative humidity (RH) for only 7 days, its surface became much rougher (Ra=21.9 nm) as a result of degradation of the Mg4Ni thin film on the surface. Moreover, the degraded device lost its optical switching properties. The device was strongly affected by high temperatures and high relative humidity in the atmosphere, resulting in rapid degradation. To address this problem, a device with a protective surface layer was also fabricated, and its durability was evaluated by the same method. The device with the protective layer was found to retain its optical switching properties under a harsh environment.
  • Keywords
    Electrochromic , Environment , Switchable mirror , Degradation , Thin film
  • Journal title
    Solar Energy Materials and Solar Cells
  • Serial Year
    2010
  • Journal title
    Solar Energy Materials and Solar Cells
  • Record number

    1484589