Effect of Eliminating Water in Prussian Blue Cathode for Sodium‐Ion Batteries

Wang, Wanlin; Gang, Yong; Peng, Jian; Hu, Zhe; Yan, Zichao; Lai, Wei‐Hong; Zhu, Yanfang; Appadoo, Dominique; Ye, Mao; Cao, Yong; Gu, Qinfen; Liu, Huan; Dou, S. X.; Chou, Shulei

doi:10.1002/adfm.202111727

Cited by 124 publications

(145 citation statements)

References 43 publications

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“…From synchrotron XRD (figures S5 and S6), CP-PW undergoes the same phase transition from P2 1 /n to R 3 between 30 to 40 • C. Hence, the phase transition near RT for Na-rich PW is independent of the synthesis method. The existence of both structures for the same compound near to RT has not been reported previously, although the two structures have been reported independently at RT [7,13,15].…”

Section: Near Room Temperature Octahedral Tilt Transition In Pwmentioning

confidence: 64%

“…In this case, the ND experiment used a larger sample volume compared to the XRD experiment (∼2 g vs ∼2 mg) potentially leading to lower heating efficiency through the whole sample. Previous work on Na 1.76 Fe[Fe(CN) 6 ]•2.6H 2 O revealed that the cubic Fm 3m phase appears at 150 • C when heated at 3 • C min −1 and continues to coexist with a high-temperature R 3 phase until 300 • C [15].…”

Section: Variable Temperature Studies Of Pwmentioning

confidence: 98%

“…Moreover, a rhombohedral R 3 structure has been reported for Na 1.76 Fe[Fe(CN) 6 ]•2.6H 2 O with Na + ions distributed over three different sites indicating Na + disorder [14]. Later, the same group carried out another study on a similar compound Na 1.76 Fe[Fe(CN) 6 ]•2.6H 2 O and found a rhombohedral R 3 structure with two oxygen sites randomly distributed over the six faces of the subcube and Na + ions located in the center of the subcube [15]. Thus, there is not yet consensus in the literature regarding the structure and, in particular, the position of water in hydrated PW.…”

Section: Introductionmentioning

confidence: 99%

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Water driven phase transitions in Prussian white cathode materials

Nielsen¹,

Dzodan²,

Ojwang³

et al. 2022

J. Phys. Energy

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Prussian White (PW, Na2Fe[Fe(CN)6]∙zH2O) is a promising cathode material for use in sodium-ion batteries (SIBs) for large-scale energy storage applications which demand long cycling life-times. For use in non-aqueous battery applications PW must not contain any water, and yet its removal induces a large volume change destabilizing the structure and reducing cycling life. Indeed, the material undergoes multiple phase transitions depending upon both the sodium and water content. Due to the extensive use of X ray diffraction, the mechanism behind the observed phase transitions is poorly understood. Here, we show a neutron diffraction study exploring the influence of water on the structure of PW. For the first time, two temperature dependent and composition independent structures were observed near room temperature which differ in the FeN6 and FeC6 octahedral tilting configurations. The fundamental nature of this distortion, which drives the large volume changes, was determined to be connected to water ordering in the framework. Further, using distortion mode analysis during the dehydration process, it was determined that water does not modify the nature of the distortions present. Rather, water was found to modulate the magnitude of pre-existing structural distortions. These results provide a robust fundamental understanding to the chemical driving forces impacting the nature and magnitude of structural distortions in PBAs. The insight provides guidance for designing and quantifying tilt-engineering in PBAs ultimately enabling new materials with enhanced long-term electrochemical performance in battery applications.

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Section: Near Room Temperature Octahedral Tilt Transition In Pwmentioning

confidence: 64%

Section: Variable Temperature Studies Of Pwmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

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Water driven phase transitions in Prussian white cathode materials

Nielsen¹,

Dzodan²,

Ojwang³

et al. 2022

J. Phys. Energy

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“…Crystal water in organic battery systems is generally considered to have a negative effect on electrochemical performance . However, a new discovery was found in K 2 [(VOHPO 4 ) 2 (C 2 O 4 )]·4.5H 2 O for MIBs.…”

Section: Magnesium-ion Batteriesmentioning

confidence: 99%

Transition Metal Oxalate-Based Materials: An Emerging Material Family for Alkali-Ion Battery Cathodes

Sun

Long

2022

ACS Appl. Energy Mater.

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Alkali-ion rechargeable batteries, including Li + /Na + /K + /Mg 2+ -ion batteries, etc., are promising technologies for energy storage applications. Polyanion compounds (PCs) represent an important cathode material category by virtue of their robust framework structures with facile alkali-ion migration paths and high-voltage properties derived from the inductive effect of anion groups. Many PCs have been well-studied, but the exploration of PCs is still fundamentally important for high-performance batteries. Recently, transition metal oxalate-based materials (TMOBMs) have emerged as a competitive cathode material family for diverse alkali-ion batteries. Oxalate anions (C 2 O 4 2− ) demonstrate strong and flexible coordinating ability with both redox-active transition metals and various anion groups (e.g., PO 4 3− , SO 4 2− , F − ), leading to the exploration of many TMOBMs with diverse framework structures (including 1D chained, 2D layered, and 3D tunneled) and intriguing electrochemical properties. This review first focuses on the development of TMOBMs as cathode materials. Their classification, crystal structures, synthesis methods, physiochemical properties, and applications in Li + /Na + /K + /Mg 2+ -ion batteries are comprehensively introduced. Investigation of TMOBMs cathodes is at the early stage. We believe that this review is timely and of great significance to further enrich the family of PCs and promote their development and applications.

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“…In some cases studies have reported that reducing the water content in PBAs leads to more stable cycling performance, whereas others report that the presence of water leads to a higher capacity. [16][17][18][19] Thus, further work is required for clarity regarding the role of guest water species on sodium ion mobility and cycling reversibility. The present paper seeks to demonstrate the beneficial effect of water removal on the sodium mobility and improvement of the cycling stability using Berlin green (BG).…”

Section: Introductionmentioning

confidence: 99%