Recently, Haifeng Yu’s group from Peking University, College of Engineering develops a kind of flexible and controllable solar thermal fuel (STF) cell. The STF cell is a composite of commercial fabric template and room temperature photo-liquefiable azobenzene derivative, which can store solar energy and release it as heat reversibly and controllably.
Solar energy gains extensive attention for its sustained and renewable properties. The key to utilizing the solar energy is realizing its controllable storage and release. At present, the solar energy has been utilized in several ways, such as photovoltaic power generation, photothermal conversion, photocatalytic water splitting and so on. There are already some commercial products like solar cells or solar water heaters derived from above techniques. In recent years, another way of using solar energy, solar thermal fuels (STFs) are interested by more and more researchers. The energy storage mechanism of STFs is transforming solar energy into chemical energy stored in the conformation of molecular isomers, such as cis/trans-azobenzene, and releasing it as heat under various stimuli. The working performance of STFs mainly relies on the energy storage substances. Azobenzene derivatives are promising candidates for STFs, attributed to their advantages of easier synthesis, lower cost, less degradation over other photoswitchable molecules, such as norbornadiene–quadricyclane system and (fulvalene)tetracarbonyldiruthenium.
In previous collaborative studies, a series of solid−solid phase-change material (SSPCM) of thermoset-ting polyurethane (TPU) nanoarrays were successfully fabricated by in-situ polymerization of poly(ethylene glycol) (PEG)-containing macromonomers in nanoporous alumina (anodized aluminum oxide, AAO) templates. The PEG segments act as heat storage units. The PEG blocks were oriented partly by the nanoconfinement in the AAO nanotemplates, leading to a higher melting point and an enhanced heat storage capacity. (ACS Applied Polymer Materials 2019, 1,(11), 2924-2932, Supplementary Cover Art)
Furthermore, Haifeng Yu’s group recently develops a solid-state STF device which is designed and fabricated by compositing one photo-liquefiable azobenzene (PLAZ) derivative with a flexible fabric template. The photoinduced phase transition of the PLAZ derivative enables the charging of the flexible STFs to be totally solvent-free and helps improving the energy-storage capacity of the azobenzene-based STFs. The fabric template not only helps increasing the energy density, but also prolonging the energy-storage half-life of flexible STFs comparing to the pristine PLAZ STFs. One infrared camera was used to visually demonstrate the exothermic situation of the flexible STF device under different stimuli. (Advanced Energy Materials, 2019, 9(37), 1901363(1-10). Back cover)