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Main Authors: Edelman, Dylan A., Cattermull, John, Liu, Jue, Jiang, Zhelong, Ramachandran, Hari, Mu, Edward, Li, Cheng, Van der Ven, Anton, Harmon, Katherine J., Chueh, William C.
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.22487
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author Edelman, Dylan A.
Cattermull, John
Liu, Jue
Jiang, Zhelong
Ramachandran, Hari
Mu, Edward
Li, Cheng
Van der Ven, Anton
Harmon, Katherine J.
Chueh, William C.
author_facet Edelman, Dylan A.
Cattermull, John
Liu, Jue
Jiang, Zhelong
Ramachandran, Hari
Mu, Edward
Li, Cheng
Van der Ven, Anton
Harmon, Katherine J.
Chueh, William C.
contents Sodium layered oxides often undergo phase transformations involving ordering or disordering of Na+ upon desodiation, i.e., when cycled as a battery electrode. Accurately characterizing these phases is crucial for understanding functional properties, such as chemical diffusivity. In this work, we reveal that Na+-vacancy (dis)ordering in a layered oxide is intrinsically coupled to continuous symmetry-changing transformations of the host structure. We examine the low-symmetry orthorhombic unit cell of P2-NaxNi1/3Mn2/3O2 (NNM) using both neutron and X-ray diffraction. Specifically, special sodium stoichiometries (x = 2/3 and 1/2) exhibit concomitant Na+-vacancy ordering and an orthorhombic distortion from the parent hexagonal unit cell. We then demonstrate that electrochemical desodiation drives symmetry-changing transformations in NNM that are linked to Na+-vacancy (dis)ordering, with evidence of second-order behavior observed near x = 2/3. Variable-temperature synchrotron X-ray diffraction further clarifies the coupling between Na+-vacancy disordering and orthorhombic-to-hexagonal phase transitions in NNM. The temperature-driven phase transitions at both x = 2/3 and 1/2 are also consistent with a second-order mechanism. Our analysis of the phase transitions in NNM has fundamental consequences for sodium chemical diffusivity in the vicinity of the ordered phases. The insights from this work are directly applicable to other layered oxides that exhibit alkali-metal-vacancy ordering.
format Preprint
id arxiv_https___arxiv_org_abs_2603_22487
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Electrochemical and thermal control of continuous phase transitions in P2-NaxNi1/3Mn2/3O2
Edelman, Dylan A.
Cattermull, John
Liu, Jue
Jiang, Zhelong
Ramachandran, Hari
Mu, Edward
Li, Cheng
Van der Ven, Anton
Harmon, Katherine J.
Chueh, William C.
Materials Science
Sodium layered oxides often undergo phase transformations involving ordering or disordering of Na+ upon desodiation, i.e., when cycled as a battery electrode. Accurately characterizing these phases is crucial for understanding functional properties, such as chemical diffusivity. In this work, we reveal that Na+-vacancy (dis)ordering in a layered oxide is intrinsically coupled to continuous symmetry-changing transformations of the host structure. We examine the low-symmetry orthorhombic unit cell of P2-NaxNi1/3Mn2/3O2 (NNM) using both neutron and X-ray diffraction. Specifically, special sodium stoichiometries (x = 2/3 and 1/2) exhibit concomitant Na+-vacancy ordering and an orthorhombic distortion from the parent hexagonal unit cell. We then demonstrate that electrochemical desodiation drives symmetry-changing transformations in NNM that are linked to Na+-vacancy (dis)ordering, with evidence of second-order behavior observed near x = 2/3. Variable-temperature synchrotron X-ray diffraction further clarifies the coupling between Na+-vacancy disordering and orthorhombic-to-hexagonal phase transitions in NNM. The temperature-driven phase transitions at both x = 2/3 and 1/2 are also consistent with a second-order mechanism. Our analysis of the phase transitions in NNM has fundamental consequences for sodium chemical diffusivity in the vicinity of the ordered phases. The insights from this work are directly applicable to other layered oxides that exhibit alkali-metal-vacancy ordering.
title Electrochemical and thermal control of continuous phase transitions in P2-NaxNi1/3Mn2/3O2
topic Materials Science
url https://arxiv.org/abs/2603.22487