Reversible electrochemical mirrors can switch between transparent and reflective states and remain reflective for up to two hours without external electrical power.
Scientists in South Korea have developed a reversible electrochemical mirror (REM) that can switch between a transparent and reflective state, and remain reflective for up to two hours without external electrical power. Such mirrors could be used in smart windows to control lighting and reduce cooling costs for buildings.
The REM, developed by the group of Professor Eunkyoung Kim at Yonsei University in Seoul, South Korea, consists of a layer containing silver electrolyte which is sandwiched between two transparent electrode panes. When a reduction voltage is applied, a reflective layer of metallic silver is deposited onto the electrode surface. Applying an oxidising potential dissolves the mirror coating by ionising the metallic silver.
Previous mirrors based on metallic thin films were limited by the short lifetime of reflective layer once the power was switched off. Professor Eunkyoung and her co-workers solved the problem by using an ionic liquid as the electrolyte. “Because ionic liquid induces the development of an electric double layer, which repels anions from the metal surface, the electrodeposited metals can be maintained without external electrical power,” Professor Eunkyoung explained. The researchers also overcame the tendency of the metal coating to rupture during deposition by modifying the electrode surface with thiol groups.
Combining reflectivity and low energy consumption could be useful in building lighting and climate systems. According to Professor Eunkyoung, the REMs have advantages over other smart window materials, since their reflectivity can be used to redirect light for illumination or heating purposes in addition to simply blocking light.
The professor plans to focus her group next on the challenge of reducing the time needed for the switching process. “The switching speed of REM is rather slower than that of other ETS devices,” Professor Eunkyoung said. “Thus the remaining challenge will be a research on a fast switching and bistable REM.”