Visible light sensitive photoliquefiable arylazoisoxazoles for the molecular solar thermal energy storage under solvent-free conditions at room temperature and lower temperatures

Solar energy can be transformed into heat energy using molecular solar thermal (MOST) energy storage materials, which can then store the heat energy and release it in response to an external stimulus like light or heat. Arylazoisoxazoles, unlike analogous arylazopyrazoles, fail to draw much attention as MOST materials due to poor photoisomerization yields in both directions and utilization of UV light for trans-cis isomerization. With the para-thioalkyl substitution in the phenyl ring, we have demonstrated that the photoswitching yields in both directions can be drastically improved under visible light irradiations. Additionally, the long thioalkyl chain permitted solid-liquid phase transition followed by very high trans-cis photoisomerization and liquid-solid transition associated with high cis-trans photoconversion at various temperatures (10-35oC). The solid liquefication enabled the storage of the latent heat along with the isomerization energy in the charged state. The compound with a C6 alkyl chain could store ̴ 196 J/g of thermal energy for nearly three weeks at 10 oC and three months at 0 oC; the liquidity of the charged state can be retained at lower temperature down to -15 oC. We further showed that the reverse cis-trans isomerization-related heat release triggered by green light can be monitored by directly recording the sample surface temperature with a high-resolution IR camera. Our results demonstrate that arylazoisoxazoles have the potential to serve as MOST materials.