Phase Behavior in NaSiCON Electrolytes and Electrodes
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Abstract
The replacement of the presently used liquid electrolytes by a non-flammable solid electrolyte is an important avenue to create safer batteries. The Natrium Superionic CONductor (NaSiCON) Na 1+x Zr 2 Si x P 3-x O 12 (0 <x <3) that displays high bulk ionic conductivity and good stability towards other NaSiCON-based electrodes is a good solid electrolyte in NaSiCON-based batteries. Despite the sizeable share of research on Na 1+x Zr 2 Si x P 3-x O 12 , the structural and thermodynamic properties of NaSiCON require better understanding for more efficient synthesis and optimization as a solid electrolyte, which often follows chemical intuition. Here, we analyze the thermodynamic properties of the NaSiCON electrolyte by constructing the Na 1+x Zr 2 Si x P 3-x O 12 phase diagram, based on density functional theory calculations, a cluster expansion framework, and Monte Carlo simulations. Specifically, we build the phase diagram as a function of temperature and composition (0 <x <3) for the high-temperature rhombohedral structure, which has been also observed in several positive electrode materials, such as Na 3 Ti 2 (PO 4 ) 3 , Na 3 V 2 (PO 4 ) 3 and Na 3 Cr 2 (PO 4 ) 3 . Through the phase diagram, we identify the concentration domains providing the highest Na + -ion conductivity and previously unreported phase-separation behavior across three different single-phase regions. Further, we note the similarities in the phase behavior between Na 1+x Zr 2 Si x P 3-x O 12 and other NaSiCON-based mono-transition metal electrodes and discuss the potential competition between thermodynamics and kinetics in experimentally observed phase separation. Our work is an important addition in understanding the thermodynamics of NaSiCON-based materials and in the development of inexpensive Na-ion batteries. From our results we propose that the addition of SiO 4 4– moieties to single-transition metal NaSiCON-phosphate-based electrodes will slow significantly the kinetics toward phase separation.
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- last seen: 2026-05-19T01:45:01.086888+00:00