The structural origin of enhanced stability of Na3.32Fe2.11Ca0.23(P2O7)2 cathode for Na-ion batteries

Liu, Yumei; Wu, Zhenguo; Indris, Sylvio; Hua, Weibo; Casati, Nicola; Tayal, Akhil; Darma, Mariyam Susana Dewi; Wang, Gongke; Liu, Yuxia; Wu, Chunjin; Xiao, Yao; Zhong, Benhe; Guo, Xiaodong

doi:10.1016/j.nanoen.2020.105417

Cited by 30 publications

(21 citation statements)

References 45 publications

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“…Note that the energy of Fe K‐edge at the pristine state is higher than that of the standard FeO but lower than Fe 2 O 3 , implying the coexistence of Fe 2+ and Fe 3+ ions. [ 42 ] Because of the sensitivity of Fe 2+ to air, this inevitable oxidation phenomenon has also been observed in other similar cathodes, such as Na 4−δ FeV(PO 4 ) 3 , [ 13 ] Na 3.32 Fe 2.34 (P 2 O 7 ) 2 , [ 42 ] etc. Similarly, the corresponding ex situ Fe 2p XPS spectra also reveal the reversible Fe 2+ /Fe 3+ redox during charge/discharge process.…”

Section: Resultsmentioning

confidence: 86%

Reversible Activation of V⁴⁺/V⁵⁺ Redox Couples in NASICON Phosphate Cathodes

Zhao

Wang

et al. 2022

Advanced Energy Materials

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101

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Na-ions batteries (NIBs) is greatly hindered by the limited capacity delivery and voltage output due to the high redox potential of Na + /Na and large radius of Na + ions. [1][2][3][4][5] Among the previously exploited cathode materials for NIBs, the polyanion-type cathodes with a Na superionic conductor (NASICON) structure proposed by John B. Goodenough since 1976 have received extensive interests, considering their robust 3D framework, unique inductive effect and thereby enhanced comprehensive performance. [2,3,5] The open framework structure not only furnishes the 3D Na + diffusion pathway, but also renders restricted lattice volume variations during Na + extraction/insertion, which is responsible for the decent rate capability and superior cycle stability. [2,5] Besides, the strong inductive effect and covalent bonds from the polyanionic groups (e.g., PO 4 3− ) allows access to a higher working potential and inhibits oxygen evolution, thus contributing to the increased energy density and high safety of NASICON polyanionic cathodes. [4] Na superionic conductor structured Na 3 V 2 (PO 4 ) 3 cathodes have attracted great interest due to their long cycling lifespan and high thermal stability rendered by the robust 3D framework. However, their practical application is still hindered by the high cost of raw materials and limited energy density. Herein, a doping strategy with low-cost Fe 2+ is developed to activate V 4+ /V 5+ redox, in an attempt to increase the energy density of phosphate cathodes. It is also revealed that reversible activation of V 4+ /V 5+ redox is related to the Na positions (Na1, 6b; Na2, 18e). Only the V-based compounds with enough Na2 content can activate the V 4+ /V 5+ reversibly. More importantly, without presodiation treatment and addition of any sodiation agent, Na 3.4 V 1.6 Fe 0.4 (PO 4 ) 3 is delicately designed as both cathode and the Na self-compensation agent in full cells, allowing a promising energy density of ≈260 Wh kg −1 . This work sheds light on enhancing the energy density, and designing Na self-compensation for practical Na-ions batteries.

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Section: Resultsmentioning

confidence: 86%

Reversible Activation of V⁴⁺/V⁵⁺ Redox Couples in NASICON Phosphate Cathodes

Zhao

Wang

et al. 2022

Advanced Energy Materials

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101

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“…With the development of large-scale energy storage equipment, the demand for high energy density materials is increasing. − Li- and Mn-rich (LMR) layered oxides, x Li 2 MnO 3 ·(1 – x )LiTMO 2 (0 < x < 1, TM = Ni, Co, Mn, etc.) have attracted great attention owing to their large reversible capacity (≥250 mAh g –1 ). − It is generally agreed that such a high capacity originates from the extra anion redox rather than the sole cation redox process. − Different from Li–O–TM configurations in traditional LiTMO 2 materials, the O 2– ion in Li 2 MnO 3 is surrounded by four Li and two Mn, which represents a different local environment with Li–O–Li configuration due to the honeycomb-like ordering of cations in the TM layer. − Along the Li–O–Li direction, the O 2p orbital generates a nonbonding state located at a high energy band near the Fermi level. , These nonbonding O 2p orbitals are preferentially oxidized above 4.5 V (versus Li/Li + ) during charging and make contribution to the additional capacity in the Li-excess material. , Notably, this O redox is a dynamic redox process related to structure evolution, which is represented by {O 2– + TM} → {O – + TM mig } + e – …”

Section: Introductionmentioning

confidence: 99%

Microstructure-Controlled Li-Rich Mn-Based Cathodes by a Gas–Solid Interface Reaction for Tackling the Continuous Activation of Li₂MnO₃

Zhang

Qiu

Sun

et al. 2021

ACS Appl. Mater. Interfaces

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Li-rich Mn-based cathodes have attracted much attention due to their high capacity stemming from anion redox above 4.5 V. However, the continuous activation of Li 2 MnO 3 in Lirich Mn-based materials, which correlates with O 2 release and TM migration, is usually unfavorable to structural stability. Herein, based on a gas−solid interface reaction, we tackle this continuous activation phenomenon by restricting the capacity release of Li 2 MnO 3 via NH 4 HCO 3 treatment in the Li 1.2 Ni 0.36 Mn 0.44 O 2 cathode. After modification, oxygen vacancies associated with the spinel phase are introduced on the surface. The 4 mol % NH 4 HCO 3 -modified material's capacity starts at 182 mAh g −1 at 1 C instead of increasing from 173 to 186 mAh g −1 for 25 cycles in the pristine material. Meanwhile, it also exhibits an excellent capacity retention of 93.24% after 200 cycles (at 1 C), with a small voltage decay rate of 1.19 mV cycle −1 .

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“…Magnesium substitution for nickel is a useful strategy to solve the problem of complex phase transitions and poor electrochemical performance by which the triphase heterostructured oxide cathode LLS-NaNCMM15 was fabricated. [44][45][46][47] The chemical composition of the LLS-NaNCM and LLS-NaNCMM15 samples measured by inductively coupled plasma mass spectrometry (ICP-MS) are shown in Table S1, Supporting Information, which demonstrates that the ratio of metal elements is highly consistent with the designed theoretical value. Meanwhile, as illustrated in Figure 2a and Figure S4, Supporting Information, in situ XRD results and the corresponding intensity contour maps confirmed the structural evolution of the LLS-NaNCMM15 electrode during the cycling process at 0.1 C in a voltage range of 1.5-4.0 V. A thorough systematic understanding of the crystal structural evolution is also discussed in detail.…”

Section: Crystal-structural Evolution Of Lls-nancmm15 Electrodementioning

confidence: 80%

Strain Engineering by Local Chemistry Manipulation of Triphase Heterostructured Oxide Cathodes to Facilitate Phase Transitions for High‐Performance Sodium‐Ion Batteries

Zhu

Xiao

et al. 2022

Advanced Energy Materials

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Sodium‐ion oxide cathodes with triphase heterostructures have attracted intensive attention, since the sodium‐storage performance can be enhanced by utilizing the synergistic effect of different phases. However, the composite structures generally suffer from multiple irreversible phase transitions and high lattice strain because of interlayer‐gliding during the charge/discharge process. Here, the concept of strain engineering via manipulating the local chemistry of heterostructured oxide cathode is proposed to regulate the relevant physical and chemical properties, resulting in highly reversible structural evolution (P2/P3/spinel → P2/P3″/spinel) and low intrinsic stress in the potential window of 1.5–4.0 V. Also, the simple structural evolution at a relatively high cut‐off potential of 4.3 V can be detected by in situ X‐ray diffraction and other electrochemical characterization techniques during Na+ extraction/insertion. Meanwhile, the electrode exhibits a high reversible capacity (169.4 mAh g−1 at 0.2 C) and excellent rate performance from 1.5 to 4.3 V. Overall, this study reveals the mechanisms of regulating local chemistry to realize strain engineering of the cathode materials and paves the way for the further improvement of high‐performance sodium‐ion batteries.

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The structural origin of enhanced stability of Na3.32Fe2.11Ca0.23(P2O7)2 cathode for Na-ion batteries

Cited by 30 publications

References 45 publications

Reversible Activation of V⁴⁺/V⁵⁺ Redox Couples in NASICON Phosphate Cathodes

Reversible Activation of V⁴⁺/V⁵⁺ Redox Couples in NASICON Phosphate Cathodes

Microstructure-Controlled Li-Rich Mn-Based Cathodes by a Gas–Solid Interface Reaction for Tackling the Continuous Activation of Li₂MnO₃

Strain Engineering by Local Chemistry Manipulation of Triphase Heterostructured Oxide Cathodes to Facilitate Phase Transitions for High‐Performance Sodium‐Ion Batteries

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The structural origin of enhanced stability of Na3.32Fe2.11Ca0.23(P2O7)2 cathode for Na-ion batteries

Cited by 30 publications

References 45 publications

Reversible Activation of V4+/V5+ Redox Couples in NASICON Phosphate Cathodes

Reversible Activation of V4+/V5+ Redox Couples in NASICON Phosphate Cathodes

Microstructure-Controlled Li-Rich Mn-Based Cathodes by a Gas–Solid Interface Reaction for Tackling the Continuous Activation of Li2MnO3

Strain Engineering by Local Chemistry Manipulation of Triphase Heterostructured Oxide Cathodes to Facilitate Phase Transitions for High‐Performance Sodium‐Ion Batteries

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Reversible Activation of V⁴⁺/V⁵⁺ Redox Couples in NASICON Phosphate Cathodes

Reversible Activation of V⁴⁺/V⁵⁺ Redox Couples in NASICON Phosphate Cathodes

Microstructure-Controlled Li-Rich Mn-Based Cathodes by a Gas–Solid Interface Reaction for Tackling the Continuous Activation of Li₂MnO₃