[100]-Oriented LiFePO<sub>4</sub> Nanoflakes toward High Rate Li-Ion Battery Cathode

Li, Zhaojin; Peng, Zhenzhen; Zhang, Hui; Hu, Tao; Hu, Minmin; Zhu, Kongjun; Wang, Xiaohui

doi:10.1021/acs.nanolett.5b04855

Cited by 85 publications

(71 citation statements)

References 47 publications

(95 reference statements)

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“…Even at the rates larger than 20 C, the plateaus still can be clearly presented. The result even compares well with the current stateof-the-art cathodes such as LiNi 0.5 Mn 0.5 O 2 , [54] LiFePO 4 /C, [56] LiFePO 4 nanoflakes, [57] amorphous FePO 4 , [58] Na 3 Ni 2 SbO 6 , [59] Na 3 V 2 (PO 4 ) 2 F 3 , [60] Na 2 Fe 2 (SO 4 ) 3 , [23] and Na 3 V 2 (PO 4 ) 2 /C/rGO. The polarization is much smaller than those for the NVP-NPs and NVP-BPs electrodes (Figures S13b, S14b, and Table S1, Supporting Information).…”

Section: Figure 2asupporting

confidence: 79%

“…Even at an ultrahigh rate of 200C, a reversible capacity of 75.9 mA h g −1 is available. c) Cycling performance at the current density of 1 C. d) Rate capability and the corresponding e) galvanostatic discharge profiles at various current densities from 1 C to 200 C. f) Ragone plots of our NVP-NFs cathode, compared with some advanced LIBs and SIBs cathode materials (LiNi 0.5 Mn 0.5 O 2 ‖Li, [54] LiFePO 4 /C‖Li, [56] LiFePO 4 nanoflakes‖Li, [57] amorphous FePO 4 ‖Li, [58] Na 3 Ni 2 SbO 6 ‖Na, [59] Na 3 V 2 (PO 4 ) 2 F 3 ‖Na, [60] Na 2 Fe 2 (SO 4 ) 3 ‖Na, [23] and Na 3 V 2 (PO 4 ) 2 /C/rGO‖Na). [54,55] Notably, even after long cycles with different rates, when the current rate is reverted to 1 C, a high discharge capacity of 114.5 mA h g −1 (99.4% of the initial capacity) is recovered.…”

Section: Figure 2amentioning

confidence: 99%

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Chemical Synthesis of 3D Graphene‐Like Cages for Sodium‐Ion Batteries Applications

Cao

Pan

Liu

et al. 2017

Advanced Energy Materials

114

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sodium hosts. Among these, sodium (Na) super ion conductor (NASICON) structured Na 3 V 2 (PO 4 ) 3 (NVP) is a good candidate cathode material due to its excellent structural stability, good thermal stability, and high energy density. [18,32] In addition, the NASICON structure also has an open 3D framework and large interstitial channels for fast Na + ion diffusion. However, similar to other polyanion compounds (i.e., Li 3 V 2 (PO 4 ) 3 and K 3 V 2 (PO 4 ) 3 ), [33,34] NVP suffers from intrinsically inferior electronic conductivity (about 10 −9 S cm −1 ).Two key strategies are applied to improve the conductivity of NVP. First, nanostructured NVP has been demonstrated to improve the sodium ion diffusion kinetics due to the reduced ion diffusion distance. [35][36][37] Zhou et al. reported template-assisted synthesis of nanostructured NVP 3D foams, which exhibit a capacity of 73 mA h g −1 at a rate of 100 C. [35] An et al. prepared NVP/C nanoflakes with high rate capability and excellent cycling stability. [36] Making NVP and carbon composites can also improve the electronic conductivity and electrochemical performances. Saravanan et al. reported the preparation of porous NVP/C with good rate capability and long cycle life (30000 cycles at 40C). [38] Zhu et al. designed NVP embedded in a porous carbon matrix with high rate capability of 44 mA h g −1 at 200C. [39] Klee et al. recently reported an oleic acid-based surfactant-assisted solid reaction method, which produced a uniform carbon coating on NVP nanoparticles and improved properties. [40] In addition, graphite-like carbon coating was applied by chemical vapor deposition or mechanical mixing. [21,22,[41][42][43] Herein, we report a detailed study of the formation of graphene-like cages structures on NVP nanoflake (NVP-NFs) arrays using the solid-state reaction approach in a molten surfactant-paraffin media. [44,45] As illustrated in Figure 1a, The NVP nanoflakes are uniformly capped with a graphene-like carbon layer, which are in situ generated in the calcination process. The graphene-like layers are connected each other to form a 3D conductive carbon network. The unique architecture provides a large contact area between electrode and electrolyte and fast electron diffusion pathway. As a cathode material for SIBs, the NVP-NFs encapsulated in the 3D graphene-like cages manifest close to theoretical capacity, excellent rate capability, and ultralong-life cycling performance. In addition, the NVP can Sodium (Na) super ion conductor structured Na 3 V 2 (PO 4 ) 3 (NVP) is extensively explored as cathode material for sodium-ion batteries (SIBs) due to its large interstitial channels for Na + migration. The synthesis of 3D graphene-like structure coated on NVP nanoflakes arrays via a one-pot, solid-state reaction in molten hydrocarbon is reported. The NVP nanoflakes are uniformly coated by the in situ generated 3D graphene-like layers with the thickness of 3 nm. As a cathode material, graphene covered NVP nanoflakes exhibit excellent electrochemical performances, includ...

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Section: Figure 2asupporting

confidence: 79%

Section: Figure 2amentioning

confidence: 99%

Chemical Synthesis of 3D Graphene‐Like Cages for Sodium‐Ion Batteries Applications

Cao

Pan

Liu

et al. 2017

Advanced Energy Materials

114

View full text Add to dashboard Cite

show abstract

“…In contrast, the state‐of‐the‐art reasoning argues that ultrathin [100]‐oriented LFP facilitates the single‐phase transformation and consequently is beneficial for the increase in active particles . Recently, [100]‐oriented LFP ultrathin nanoplatelets with a statistic thickness of 12 nm were synthesized under a water‐deficit acidic condition in our laboratory . The ultrathin nanoplatelets exhibited excellent electrochemical performance.…”

Section: Figurementioning

confidence: 99%

Precursor‐Directed Nucleation and Self‐Assembly Growth: From Hollow Microprisms to Nanoplatelets

Peng

et al. 2017

ChemNanoMat

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Directly controlling the morphology and orientation of nanocrystals is a key step for their tailored applications. Achieving such controlled synthesis requires insight into the formation mechanism. Using Li3PO4 microprisms as a solid precursor sealed in capillary tube, we unravel the structural and morphological evolution from the precursor to the resultant LiFePO4 nanoplatelets by means of in situ temperature monitoring, ex situ Raman spectroscopy and TEM/STEM. Under water‐deficient conditions, the precursor dissolves in a sluggish manner, facilitating simultaneous heterogeneous nucleation of LiFePO4 on undissolved Li3PO4 and homogeneous nucleation in solution. Vertically aligned nanoribbons consisting of primary LiFePO4 particles on the Li3PO4 surface undergo self‐assembly growth though oriented attachment. The [100]‐orientation is explained by the fact that H3O+ preferably adsorbed on the LiFePO4 (100) facet and suppressed the crystal growth more along the [100] direction than the others.

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“…LiNi1-x-yCoxMnyO2 combines the advantages of three elements, which has the advantages of large specific capacity, outstanding cycle performance and moderate price of cost, while it has the disadvantages of poor material surface stability due to property of hard oxidation of divalent Ni. LiFePO4 has the advantages of good cycle performance, good security performance but it has low mix conductivity, low energy density and poor rate performance [4] . The comparison of different cathode materials for lithium-ion batteries is listed below.…”

Section: Overview Of Lithium-ion Batteriesmentioning

confidence: 99%

Battery thermal management with phase change materials (PCMs)

Zhang¹

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[100]-Oriented LiFePO₄ Nanoflakes toward High Rate Li-Ion Battery Cathode

Cited by 85 publications

References 47 publications

Chemical Synthesis of 3D Graphene‐Like Cages for Sodium‐Ion Batteries Applications

Chemical Synthesis of 3D Graphene‐Like Cages for Sodium‐Ion Batteries Applications

Precursor‐Directed Nucleation and Self‐Assembly Growth: From Hollow Microprisms to Nanoplatelets

Battery thermal management with phase change materials (PCMs)

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[100]-Oriented LiFePO4 Nanoflakes toward High Rate Li-Ion Battery Cathode

Cited by 85 publications

References 47 publications

Chemical Synthesis of 3D Graphene‐Like Cages for Sodium‐Ion Batteries Applications

Chemical Synthesis of 3D Graphene‐Like Cages for Sodium‐Ion Batteries Applications

Precursor‐Directed Nucleation and Self‐Assembly Growth: From Hollow Microprisms to Nanoplatelets

Battery thermal management with phase change materials (PCMs)

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Product

Resources

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[100]-Oriented LiFePO₄ Nanoflakes toward High Rate Li-Ion Battery Cathode