Electrochromism

[2] In this way, a smart window made of an electrochromic material can block specific wavelengths of ultraviolet, visible or (near) infrared light.

[11] As organic materials, viologens are seen as promising alternatives for electronic applications, compared to metal-based systems, which tend to be expensive, toxic, and a problem to recycle.

[16] Possible advantages of viologens include their optical contrast, coloration efficiency, redox stability, ease of design, and potential to scale up for large-area preparation.

[18] Viologens have been used with phenylenediamine by Gentex Corporation, which has commercialized auto-dimming rearview mirrors[18] and smart windows in Boeing 787 aircraft.

By applying a lower voltage (2.5 V for example) the concentration of Li-ions in the electrochromic layer decreases, thus activating (N)IR-active tungsten oxide.

[25][3] This activation causes reflection of infrared light, thus lowering the greenhouse effect, which in turn reduces the amount of energy needed for air conditioning.

[26] Depending on the electrochromic material used, different parts of the spectrum can be blocked, this way UV, visible and IR light can be independently reflected at the will of a user.

[27] NiO materials have been widely studied as counter electrodes for complementary electrochromic devices, particularly for smart windows.

[28][29] ICE 3 high speed trains use electrochromic glass panels between the passenger compartment and the driver's cabin.

Redox couple for a viologen . The 2+ species on the left is colorless, and the 1+ species on the right is deep blue or red, depending on the identity of R. [ 1 ]
Cross-section of an electrochromic panel changing from transparent to opaque. A voltage is applied across the conducting electrodes, and ions flow from the ion storage layer, through the electrolyte, and into the electrochromic layer.
Electrochromic glass installed in buildings
Electrochromatic window on an ANA Boeing 787-8 Dreamliner passenger jet