Akinori Hoshikawa scite author profile

A new and promising P2‐type layered oxide, Na5/6[Li1/4Mn3/4]O2 is prepared using a solid‐state method. Detailed crystal structures of the sample are analyzed by synchrotron X‐ray diffraction combined with high‐resolution neutron diffraction. P2‐type Na5/6[Li1/4Mn3/4]O2 consists of two MeO2 layers with partial in‐plane √3a × √3a‐type Li/Mn ordering. Na/Li ion‐exchange in a molten salt results in a phase transition accompanied with glide of [Li1/4Mn3/4]O2 layers without the destruction of in‐plane cation ordering. P2‐type Na5/6[Li1/4Mn3/4]O2 translates into an O2‐type layered structure with staking faults as the result of ion‐exchange. Electrode performance of P2‐type Na5/6[Li1/4Mn3/4]O2 and O2‐type Lix[Li1/4Mn3/4]O2 is examined and compared in Na and Li cells, respectively. Both samples show large reversible capacity, ca. 200 mA h g−1, after charge to high voltage regardless of the difference in charge carriers. Structural analysis suggests that in‐plane structural rearrangements, presumably associated with partial oxygen loss, occur in both samples after charge to a high‐voltage region. Such structural activation process significantly influences electrode performance of the P2/O2‐type phases, similar to O3‐type Li2MnO3‐based materials. Crystal structures, phase‐transition mechanisms, and the possibility of the P2/O2‐type phases as high‐capacity and long‐cycle‐life electrode materials with the multi‐functionality for both rechargeable Li/Na batteries are discussed in detail.

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Crystal structure analysis of β-tricalcium phosphate Ca3(PO4)2 by neutron powder diffraction

Yashima

Sakai

Kamiyama

et al. 2003

Journal of Solid State Chemistry

457

292

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Rietveld analysis software for J-PARC

Oishi

Yonemura

Nishimaki³

et al. 2009

Nuclear Instruments and Methods in Physics Research Section A:

478

258

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New Perovskite-Related Structure Family of Oxide-Ion Conducting Materials NdBaInO₄

Fujii¹,

Esaki²,

Omoto³

et al. 2014

Chem. Mater.

109

123

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