Polyanionic Cathode Materials for Practical Na-Ion Batteries toward High Energy Density and Long Cycle Life

Xu, Chunliu; Zhao, Junmei; Yang, Chao; Hu, Yong-Sheng

doi:10.1021/acscentsci.3c00907

Cited by 27 publications

(15 citation statements)

References 108 publications

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“…The overuse of fossil fuels has caused severe energy shortages and environmental contamination problems. Nowadays, building a sustainable development human society via large-scale renewable energy storage technology has become a key to solving these problems. − Sodium-ion batteries (SIBs) had attracted wide attention because they work based on similar principles as lithium-ion batteries but replace lithium with sodium element to eliminate lithium dependence. − In the commercialization process of SIBs, cathode materials played a decisive role. − Up to now, these cathode materials with commercialized prospects were mainly divided into the following three categories: transition-metal oxides, − polyanion compounds, − and prussian blue analogues. − Polyanion-type Fe-based phosphate cathode materials have received extensive interest due to their nontoxic nature, high structural stability, and lower cost. − The widely utilized olivine lithium iron phosphate (LiFePO 4 ), known as LFP, has served as a representative polyanionic iron-based phosphate cathode for lithium-ion batteries (LIBs). However, its counterpart, olivine NaFePO 4 , is not suitable for SIBs due to its complex synthesis route.…”

Section: Introductionmentioning

confidence: 99%

Towards High-Performance Sodium-Ion Batteries via the Phase Regulation Strategy

Liu,

Cao,

Zhang

et al. 2024

ACS Sustainable Chem. Eng.

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The iron-based mixed-polyanionic cathode Na 4 Fe 3 (PO 4 ) 2 (P 2 O 7 ) (referred to as N4FP) has gained significant attention as an ideal candidate for commercial sodium-ion batteries (SIBs). Its advantages, such as cost-effectiveness, environmental friendliness, and excellent structural stability, make it highly attractive. However, the practical specific capacity of N4FP (approximately 100 mA h g −1 ) tends to fall short of its theoretical specific capacity (129 mA h g −1 ), resulting in a relatively low energy density at the cell level. This study aims to investigate the capacity limitations of the N4FP cathode and identify the formation of inactive maricite-type sodium iron phosphate, NaFePO 4 (termed NFP), as the primary cause for these limitations. To address this issue, a small amount of ferric sodium pyrophosphate (Na 2 FeP 2 O 7 , referred to as N2FP) is introduced into the N4FP cathode to eliminate the formation of inactive maricite NFP. The N4FP cathode modified with 5% N2FP (referred to as N4FP-5%N2FP) has a remarkable reversible specific capacity of 125.6 mA h g −1 at 0.1 C, equivalent to 97.4% of the theoretical specific capacity of N4FP. Additionally, the N4FP-5% N2FP cathode demonstrates excellent long cycle life and rate properties during testing.

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Section: Introductionmentioning

confidence: 99%

Towards High-Performance Sodium-Ion Batteries via the Phase Regulation Strategy

Liu,

Cao,

Zhang

et al. 2024

ACS Sustainable Chem. Eng.

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“…Na-ion batteries (NIBs) have received great attention in large-scale energy storage systems and smart grids because of huge abundance and low cost of sodium sources. − Substantial efforts have been devoted to developing cost-effective and high-performance cathodes these years toward commercially available NIBs. − Particularly, the benign and cheap iron-based phosphates were regarded as one of the best choices for NIBs as parallel LiFePO 4 cathodes have gained huge commercial success in lithium-ion batteries. However, the olivine-NaFePO 4 candidates could not be directly obtained by the conventional ceramic method due to the unfavorable thermodynamics feature and trend to transform into the more stable maricite phase. , Unfortunately, the maricite-type NaFePO 4 is usually believed to be of electrochemical inertness due to absence of effective Na + ion diffusion channels .…”

Section: Introductionmentioning

confidence: 99%

Development of High-Performance Iron-Based Phosphate Cathodes toward Practical Na-Ion Batteries

Xu,

Zhou,

Gao

et al. 2024

J. Am. Chem. Soc.

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Iron-based phosphate cathode of Na 4 Fe 3 (PO 4 ) 2 (P 2 O 7 ) has been regarded as a low-cost and structurally stable cathode material for Naion batteries (NIBs). However, their practical application is greatly hindered by the insufficient electrochemical performance and limited energy density. Here, we report a new iron-based phosphate cathode of Na 4.5 Fe 3.5 (PO 4 ) 2.5 (P 2 O 7 ) with the intergrown heterostructure of the maricite-type NaFePO 4 and orthorhombic Na 4 Fe 3 (PO 4 ) 2 (P 2 O 7 ) phases at a mole ratio of 0.5:1. Benefited from the increased composition ratio and the spontaneous activation of the maricite-type NaFePO 4 phase, the as-prepared Na 4.5 Fe 3.5 (PO 4 ) 2.5 (P 2 O 7 ) composites deliver a reversible capacity over 130 mA h g −1 and energy density close to 400 W h kg −1 , which is far beyond that of the single-phase Na 4 Fe 3 (PO 4 ) 2 (P 2 O 7 ) cathode (∼120 mA h g −1 and ∼350 W h kg −1 ). Moreover, the kg-level products from the scale-up synthesis demonstrate a stable cycling performance over 2000 times at 3 C in pouch cells. We believe that our findings could show the way forward the practical application of the iron-based phosphate cathodes for NIBs.

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“…The air-stable additives tend to decompose at a high voltage above 4.0 V, even to 4.4 V, which is beyond the cutoff voltage of common layer oxide 21 or phosphate cathode. 22 To achieve controllable sodium compensation at a much-reduced decomposition voltage, researchers have focused on the relationship between the decomposition voltage and the electron structures of various sodium salts. According to the Kolbe electrolysis theory, 23,24 the decomposition potential is closely tied to the electron-donating effect of functional groups.…”

Section: Introductionmentioning

confidence: 99%

“…The sodium compensation strategy can effectively address the irreversible sodium loss during the formation process of SEI, thus promoting the electrochemical properties of SIBs. − To date, different self-sacrificial additives have been reported, including Na 2 S, Na 2 O 2 , NaN 3 , , Na 3 P, Na 2 NiO 2 , Na 2 C 2 O 4 , and Na 2 C 4 O 4 . , It is worth noting that the lower decomposition voltage additives like Na 2 S, NaN 3 , and Na 3 P are quite air-sensitive and not suitable for industrial use. The air-stable additives tend to decompose at a high voltage above 4.0 V, even to 4.4 V, which is beyond the cutoff voltage of common layer oxide or phosphate cathode . To achieve controllable sodium compensation at a much-reduced decomposition voltage, researchers have focused on the relationship between the decomposition voltage and the electron structures of various sodium salts.…”

Section: Introductionmentioning

confidence: 99%

Boosting Sodium Compensation Efficiency via a CNT/MnO₂ Catalyst toward High-Performance Na-Ion Batteries

He,

Guo,

Wang

et al. 2024

ACS Appl. Mater. Interfaces

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The formation of a solid electrolyte interphase on carbon anodes causes irreversible loss of Na + ions, significantly compromising the energy density of Na-ion full cells. Sodium compensation additives can effectively address the irreversible sodium loss but suffer from high decomposition voltage induced by low electrochemical activity. Herein, we propose a universal electrocatalytic sodium compensation strategy by introducing a carbon nanotube (CNT)/MnO 2 catalyst to realize full utilization of sodium compensation additives at a much-reduced decomposition voltage. The well-organized CNT/MnO 2 composite with high catalytic activity, good electronic conductivity, and abundant reaction sites enables sodium compensation additives to decompose at significantly reduced voltages (from 4.40 to 3.90 V vs Na + /Na for sodium oxalate, 3.88 V for sodium carbonate, and even 3.80 V for sodium citrate). As a result, sodium oxalate as the optimal additive achieves a specific capacity of 394 mAh g −1 , almost reaching its theoretical capacity in the first charge, increasing the energy density of the Na-ion full cell from 111 to 158 Wh kg −1 with improved cycle stability and rate capability. This work offers a valuable approach to enhance sodium compensation efficiency, promising high-performance energy storage devices in the future.

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Polyanionic Cathode Materials for Practical Na-Ion Batteries toward High Energy Density and Long Cycle Life

Cited by 27 publications

References 108 publications

Towards High-Performance Sodium-Ion Batteries via the Phase Regulation Strategy

Towards High-Performance Sodium-Ion Batteries via the Phase Regulation Strategy

Development of High-Performance Iron-Based Phosphate Cathodes toward Practical Na-Ion Batteries

Boosting Sodium Compensation Efficiency via a CNT/MnO₂ Catalyst toward High-Performance Na-Ion Batteries

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Polyanionic Cathode Materials for Practical Na-Ion Batteries toward High Energy Density and Long Cycle Life

Cited by 27 publications

References 108 publications

Towards High-Performance Sodium-Ion Batteries via the Phase Regulation Strategy

Towards High-Performance Sodium-Ion Batteries via the Phase Regulation Strategy

Development of High-Performance Iron-Based Phosphate Cathodes toward Practical Na-Ion Batteries

Boosting Sodium Compensation Efficiency via a CNT/MnO2 Catalyst toward High-Performance Na-Ion Batteries

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Boosting Sodium Compensation Efficiency via a CNT/MnO₂ Catalyst toward High-Performance Na-Ion Batteries