Journal
INORGANIC CHEMISTRY
Volume 61, Issue 9, Pages 4092-4101Publisher
AMER CHEMICAL SOC
DOI: 10.1021/acs.inorgchem.1c03861
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Funding
- Czech Science Foundation (GACR) [19-26910X, 20-16124J]
- MS.MT Project [LM2015056]
- Ministry of Education, Youth and Sports [LM2015074]
- [A2_FCHT_2021_055]
- [A2_FCHT_2021_049]
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High-entropy materials have gained significant attention, particularly in the field of energy storage. This study successfully fabricated two high-entropy phosphates and evaluated their performance for batteries and solid-state electrolytes.
High-entropy materials, with complex compositions and unique cocktail characteristics, have recently drawn significant attention. Additionally, a family of sodium super ion conductors (NASICONs)-structured phosphates in energy storage areas shows a comprehensive application for traditional alkaline ion batteries and, in particular, solid-state electrolytes. However, there is no precedent in fabricating this kind of NASICON-type high-entropy phase. Here, we report the successful fabrication of two well-crystallized high-entropy phosphates, namely, Na-3(Ti0.2V0.2Mn0.2Cr0.2Zr0.2)(2)(PO4)(3) (HE-N3M2P3) and Na(Ti0.2V0.2Mn0.2Cr0.2Zr0.2)(2)PO4Ox (HE-NMP). The prepared materials in which the transition metals (TMs) of Ti, V, Mn, Cr, and Zr occupy the same 12c Wykoff position can form a structure analogous to R (3) over barc Na3V2(PO4)(3) that is carefully determined by X-ray diffraction, neutron diffraction, and transmission electron microscopy. Further, their performance for sodium ion batteries and sodium-based solid-state electrolytes was evaluated. The HE-N3M2P3 might exhibit a promising electrochemical performance for sodium storage in terms of its structure resembling that of Na3V2(PO4)(3). Meanwhile, the HE-NMP shows considerable electrochemical activity with numerous broad redox ranges during extraction and insertion of Na+, related to the coexistence of several TM elements. The evaluated temperature-dependent ionic conductivity for HE-NMP solid electrolyte varies from 10(-6) to 10(-5) S cm(-1) from room temperature to 398.15 K, offering high potential for energy storage applications as a new high-entropy system.
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