Abstract:
Since most of the efficient electrochromic devices (ECDs) consist of
expensive rare earth materials such as Tungsten (VI) oxide, (WO3) and
Cerium (IV) oxide, (CeO2) and liquid electrolytes comprising with volatile
solvents such as acetonitrile, there exist some significant technological
problems associated with the fabrication cost and the encapsulation of these
devices. Therefore, there is a considerable interest in both the development
of a solid or quasi solid electrolyte and replacement of these expensive
materials with possible low cost alternatives. By considering these facts, we
have explored the possibility of use of natural polymer, Chitosan (Poly D glucosamine) containing Li+
ions as the quasi solid polymer electrolyte and
at the same time replacement of expensive WO3 and CeO2 with low cost
Titanium dioxide (TiO2) and Tin oxide (SnO2) respectively as alternatives.
The EC devices with dimensions, 2.1x1.4 cm2 with configuration FTO
glass/TiO2/Chitosan polymer electrolyte /SnO2/FTO were fabricated.
Temperature dependence of DC conductivity of the polymer electrolyte,
containing either LiClO4 or LiCF3SO3 salts, was measured with varying the
salt concentration. The best room temperature ionic conductivities found are
in the order of 5.17x10-2
S cm-1
and 4.09 x 10-2
S cm-1 with corresponding
lithium concentration 0.5M and 1M for LiClO4 and LiCF3SO3 respectively.
Electrochemical and optical properties of the electrolyte and ECDs were
measured by cyclic voltammetry and UV-visible spectroscopy. The average
transmittance in the visible region of the spectrum is about 58% at the
bleached state and below 15% at the colored state for all the samples studied.