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Single-Crystal P2-Na0.67Mn0.67Ni0.33O2 Cathode Material with Improved Cycling Stability for Sodium-Ion Batteries

Pamidi, V and Naranjo, C and Fuchs, S and Stein, H and Diemant, T and Li, Y and Biskupek, J and Kaiser, U and Dinda, S and Reupert, A and Behara, S and Hu, Y and Trivedi, S and Munnangi, AR and Barpanda, P and Fichtner, M (2023) Single-Crystal P2-Na0.67Mn0.67Ni0.33O2 Cathode Material with Improved Cycling Stability for Sodium-Ion Batteries. In: ACS Applied Materials and Interfaces .

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Official URL: https://doi.org/10.1021/acsami.3c15348

Abstract

Layered oxides constitute one of the most promising cathode materials classes for large-scale sodium-ion batteries because of their high specific capacity, scalable synthesis, and low cost. However, their practical use is limited by their low energy density, physicochemical instability, and poor cycling stability. Aiming to mitigate these shortcomings, in this work, we synthesized polycrystalline (PC) and single-crystal (SC) P2-type Na0.67�δMn0.67Ni0.33O2 (NMNO) cathode materials through a solid-state route and evaluated their physicochemical and electrochemical performance. The SC-NMNO cathode with a large mean primary particle size (D50) of 12.7 μm was found to exhibit high cycling stability leading to 47 higher capacity retention than PC-NMNO after 175 cycles at 1C rate in the potential window 4.2-1.5 V. This could be attributed to the effective mitigation of parasitic side reactions at the electrode-electrolyte interface and suppressed intergranular cracking induced by anisotropic volume changes. This is confirmed by the lower volume variation of SC-NMNO (�V � 1.0) compared to PC-NMNO (�V � 1.4) upon charging to 4.2 V. Additionally, the SC-NMNO cathode displayed slightly higher thermal stability compared to PC-NMNO. Both cathodes exhibited good chemical stability against air and water exposure, thus enabling material storage/handling in the ambient atmosphere as well as making them suitable for aqueous processing. In this regard, PC-NMNO was investigated with two low-cost aqueous binders, carboxymethyl cellulose, and sodium trimetaphosphate, which exhibited higher binding strength and displayed excellent electrochemical performance compared to PVDF, which could potentially lead to significant cost reduction in electrode manufacturing. © 2024 The Authors. Published by American Chemical Society.

Item Type: Journal Article
Publication: ACS Applied Materials and Interfaces
Publisher: American Chemical Society
Additional Information: The copyright for this article belongs to author.
Keywords: Binders; Chemical stability; Cost reduction; Electrolytes; Metal ions; Particle size; Single crystals; Sodium compounds; Sodium-ion batteries; Textures; Thermodynamic stability, Cathodes material; Cycling stability; Inorganic aqueous binder; Inorganics; Layered oxides; Low-costs; Polycrystalline; Single-crystal cathode; Sodium ion batteries; Sodium trimetaphosphates, Cathodes
Department/Centre: Division of Chemical Sciences > Materials Research Centre
Date Deposited: 26 May 2024 06:47
Last Modified: 26 May 2024 06:47
URI: https://eprints.iisc.ac.in/id/eprint/85160

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