Vasilii Gromov, Atlas Noubir, F. Keshavarz, Ekaterina Laakso, B. Barbiellini, A. Bansil
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Abstract
Anhydrous ferrous (II) oxalate (AFO) outperforms its hydrated form when used as an anode material in Li-ion batteries (LIBs). With the increasing interest in Na-ion batteries (NIBs) in mind, we examine the potential of AFO as the anode in NIBs through first principles calculations involving both periodic and non-periodic structures. Our analysis based on periodic (non-periodic) modeling scheme shows that the AFO anode generates a low reaction potential of 1.22 V (1.45 V) in the NIBs, and 1.34 V (1.24 V) in the LIBs, which is much lower than the potential of NIBs with mixed oxalates. The conversion mechanism in the underlying electrochemical process involves the reduction of Fe2+ with the addition of Na or Li. Such conversion electrodes can achieve high capacities through the Fe2+ valence states of iron.
当用作锂离子电池(lib)的负极材料时,无水草酸亚铁(II) (AFO)的性能优于其水合形式。随着人们对钠离子电池(nib)的兴趣日益增加,我们通过涉及周期和非周期结构的第一性原理计算来研究AFO作为nib阳极的潜力。我们基于周期性(非周期性)建模方案的分析表明,AFO阳极在nib中产生的反应电位较低,为1.22 V (1.45 V),在lib中产生的反应电位为1.34 V (1.24 V),远低于混合草酸盐的nib。在潜在的电化学过程中的转化机制是通过添加Na或Li来还原Fe2+。这种转换电极可以通过铁的Fe2+价态获得高容量。
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