NiFe-NO3 Layered Double Hydroxide as a Novel Anode for Sodium Ion Batteries

IF 4.7 4区材料科学 Q2 ELECTROCHEMISTRY Batteries & Supercaps Pub Date : 2024-12-04 DOI:10.1002/batt.202400451

Marco Fortunato, Angelina Sarapulova, Björn Schwarz, Anna Maria Cardinale, Sonia Dsoke

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Abstract

2D materials are emerging materials for energy storage and among these layered double hydroxides (LDHs) seem particularly promising due to their structure, easily adjustable composition, and cheapness. This study marks the first reported application of an LDH, specifically NiFe-NO₃ LDH, as conversion anode material in a sodium half-cell, to the best of our knowledge. Despite an initial loss in capacity, the material demonstrates notable stability, retains a high specific capacity even after 50 discharge/charge cycles (~500 mAh/g). The intricate reaction mechanism was explored using various ex-situ techniques such as DC magnetometry and FTIR, as well as in-operando X-ray Absorption Spectroscopy (XAS). The proposed Na-storage mechanism in NiFe-NO₃ LDH involves an initial irreversible “activation” during the first sodiation, characterized by a phase change reaction that leads to the formation of NiO_x and Fe₃O₄, followed by a reversible mechanism involving both intercalation and conversion in subsequent cycles.

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nfe - no3层状双氢氧化物作为钠离子电池的新型阳极

二维材料是新兴的储能材料，在这些层状双氢氧化物（LDHs）中，由于它们的结构、易于调节的成分和便宜的价格，它们似乎特别有前途。据我们所知，这项研究标志着LDH，特别是nfe - no3 LDH，在钠半电池中作为转化阳极材料的首次报道。尽管初始容量有所损失，但该材料表现出显著的稳定性，即使在50次放电/充电循环（~500 mAh/g）后仍保持较高的比容量。利用各种非原位技术，如直流磁强计和FTIR，以及运行中的x射线吸收光谱（XAS），探索了复杂的反应机理。nfe - no3 LDH中的na存储机制包括在第一次碱化过程中初始的不可逆“激活”，其特征是相变反应导致NiOx和Fe3O4的形成，随后在随后的循环中涉及插入和转化的可逆机制。

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来源期刊

Batteries & Supercaps Multiple-

CiteScore

8.60

自引率

5.30%

发文量

223

期刊介绍： Electrochemical energy storage devices play a transformative role in our societies. They have allowed the emergence of portable electronics devices, have triggered the resurgence of electric transportation and constitute key components in smart power grids. Batteries & Supercaps publishes international high-impact experimental and theoretical research on the fundamentals and applications of electrochemical energy storage. We support the scientific community to advance energy efficiency and sustainability.