📝 SummarXiv

Abstract

Enhancing heat transport within thermochemical heat storage (TCHS) materials is essential for improving the heat output. A common strategy is combining salts with highly conductive additives such as carbon or metals. However, such composites often suffer from drawbacks including interfacial instability and a reduction of gas permeability. In this work, we propose an alternative approach based on microstructural orientation control, aiming to create efficient heat transport pathways without relying on conductive additives. As a model material, La$_2$(SO$_4$)$_3$ was selected, which undergoes reversible hydration and dehydration below 250 {\deg}C. Centimeter-scale hexagonal prismatic La$_2$(SO$_4$)$_3\cdot$9H$_2$O grains were grown from solution and then formed into plate-shaped specimens either parallel to the longitudinal direction or transverse to it, and then dehydrated to $\beta$-La$_2$(SO$_4$)$_3$. Laser flash analysis revealed clear orientation-dependent thermal diffusivity of pre-dehydrated $\beta$-La$_2$(SO$_4$)$_3$, with values of about 0.24 mm$^2$/s for the longitudinal plate and about 0.15 mm$^2$/s for the transverse plate at room temperature. Microstructural observations indicated the formation of aligned rod-like domains, suggesting that orientation provides an efficient heat transport pathway. These findings demonstrate that controlling orientation provides a viable route to enhance heat transport in TCHS materials, offering a new design approach.