서강대학교

초록/요약 도움말

The effect of laponite (R) clay dispersion on the electrical, structural, optical, thermal, and photovoltaic properties of [poly (ethylene oxide)-succinonitrile]-LiI-I-2 solid polymer electrolytes is reported for the first time. The nanoclay belongs to the family of smectite clay minerals and offers a high surface-to-volume ratio, charged surface, galleries, and ionic species. The dispersion has increased the room-temperature electrical conductivity to similar to 0.5 mS cm(-1) for the optimum conducting electrolyte (OCE; x = 2.5%) without altering the pseudo-activation energy. The change is explained using the percolation model utilizing the formation of a space-charge region by the clay. Fourier-transform infrared spectroscopy reveals the greater interaction between clay and succinonitrile than clay and poly (ethylene oxide) and the formation of amorphous domains for the OCE. X-ray diffractometry study shows a shift toward the lower angle for the amorphous hump of the OCE. The OCE exhibits a similar to 123% increase in short-circuit current density, similar to 28% decrease in open-circuit voltage, and 29-64% decrease in charge-transfer and Warburg resistances, inferring the active role of the clay in improving the Li+ ion intercalation into and/or adsorption onto the TiO2. This has resulted in 54% increase in cell efficiency (similar to 3.7% at solar irradiance of 100 mW cm(-2)).