Abstract

Reducing the amount of electricity used by cooling systems is essential for lowering CO 2 emissions; therefore suppressing increases in room temperature in an environmentally friendly manner requires the development of heat-shielding materials that autonomously control sunlight without the use of electricity. Hydroxypropyl cellulose (HPC) has attracted attention as a lower critical solution temperature (LCST) type of temperature-responsive polymer. HPC is a thermochromic material that changes its optical properties in response to changes in external temperature. In this study, acrylamide (AAm) and HPC with various molecular weights were used to prepare HPC-AAm hydrogels, and their optical, heat-shielding, and weathering-resistant properties were evaluated. UV–vis–NIR spectroscopy revealed that the solar transmittance ( αT sol ) of the HPC-AAm hydrogel decreased while its solar reflectance ( αR sol ) increased with increasing HPC concentration above LCST. The αT sol of low-molecular-weight HPC was found to be lower than that of high-molecular-weight HPC. In addition, the temperature inside a box constructed using an HPC-AAm hydrogel window was approximately 10 °C lower than that constructed using glass alone. Furthermore, the optical properties of the HPC-AAm hydrogel were found to hardly deteriorated even when continuously exposed to heat and UV radiation for 150 h. Therefore, the HPC-AAm hydrogel prepared in this study is expected to be useful as a heat-shielding material. • Hydrogels based on hydroxypropyl cellulose (HPC) acrylamide (AAm) were prepared. • HPC-AAm hydrogels show high αT sol values below the LCST. • αT sol decreases and αR sol increases with increasing HPC loading above the LCST. • The L-HPC-AAm hydrogel led to lower temperatures inside a simulated room. • The HPC-AAm hydrogel is stable when continuously heated and UV irradiated.

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