Abstract
A short overview is given on existing phase relations in the four related ternary diagrams, setting the frame for a quaternary phase diagram. On the basis of published data the three-dimensional phase region of NASICON materials is constructed and phase relations to ternary and binary systems as well as to single oxides are presented. To date, the NASICON region can be described as a compressed tetrahedron within the tetrahedral phase diagram. However, the three-dimensional presentation clearly elucidates that few reported compositions exist outside this compressed tetrahedron indicating that the phase region of NASICON materials may be larger than the solid solutions known so far. The three-dimensional representation also better elucidates the regions connecting the edges of the NASICON tetrahedron with ternary and binary compounds as well as single oxides, i.e., ZrO2 and ZrSiO4, Na3PO4, sodium silicates and sodium zirconium silicates and gives a better understanding of phase formations during the processing of the ceramics. The implications of the formation of secondary phases and glass-ceramic composites are discussed in terms of technological applications.
Highlights
The increasing need to harvest energy from fluctuating energy sources has placed energy storage into a central position for future energy technology scenarios
The three-dimensional presentation clearly elucidates that few reported compositions exist outside this compressed tetrahedron indicating that the phase region of NASICON materials may be larger than the solid solutions known so far
The three-dimensional representation better elucidates the regions connecting the edges of the NASICON tetrahedron with ternary and binary compounds as well as single oxides, i.e., ZrO2 and ZrSiO4, Na3PO4, sodium silicates and sodium zirconium silicates and gives a better understanding of phase formations during the processing of the ceramics
Summary
The increasing need to harvest energy from fluctuating energy sources has placed energy storage into a central position for future energy technology scenarios. In all sodium battery systems Na+-ß’’-alumina has been employed for the solid electrolyte membrane This is insofar surprising, as the processing of ß’’-alumina to ceramic tubes is more elaborate, sophisticated and energy-consuming due to the high sintering temperatures [4] than for the only existing alternative: ceramics in the Na2O-P2O5-SiO2-ZrO2 system. These materials have been known since 40 years [5,6], to our knowledge there has never been a technological approach to replace ß’’-alumina in sodium batteries apart from a very recent comparison of a ZEBRA battery cells [7]. We do summarize existing knowledge, and try to harmonize the individual results
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