Prospects in anode materials for sodium ion batteries - A review

Perveen, Tahira; Siddiq, Muhammad; Waqas, Adeel; Ihsan, Rida; Ahmad, Adil; Shahzad, Muhammad

doi:10.1016/j.rser.2019.109549

Cited by 343 publications

(202 citation statements)

References 230 publications

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“…1677 Wh/kg [31] , 工作温度在105~110℃之间, 不过现已开发出室温的钠空气电池 [6] . 目前, 钠空气电池的研究 Sb、P等)、转化类材料(过渡金属氧化物/硫化物)和有机类材料 [16] . 电解质主要分为液态和固态两大类, 细分包括有机溶剂、水溶液、离子液体、固体聚合物和无机固态电解质 [2,32] .…”

Section: 钠电池的种类及特点unclassified

“…钠离子电池的成本低、原材料储量丰富、分布广泛且钠的化学性质与锂相似, 是锂离子电池的理想替代者, 适于大规模储能 [34] . 但Na + 的Shannon离子半径(102 pm) 大于Li + (76 pm) [16] , 在电池循环充放电过程中, 其在电极材料间的嵌入和脱出更为困难, 对电极材料产生较大的应力变化, 使固体电解质界面(solid electrolyte interface, SEI)膜不断破碎与生成, 造成电池的能量密度降低和循环稳定性变差等问题 [35] . 目前的研究大多集中在合成高效稳定的正负极材料、优化电解质的组成、加入电解质添加剂等以提高电池的电化学性能 [16] .…”

Section: 钠电池的种类及特点unclassified

“…场地, 所以材料的孔隙率、孔分布与孔体积在很大程度上影响电池的放电容量与循环寿命 [52] . [11,16] . 对此, 可以利用真空干燥箱干燥以去除水分子 [55] , 或者采用离子掺杂 [56] 、聚合物包裹 [57] 等方式合理调控晶体结构以提高钠离子电池的电化学性能.…”

Section: 钠电池的种类及特点unclassified

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Progress of sodium battery failure research

Feng¹,

Yu²,

Cheng³

et al. 2020

Sci. Sin.-Chim

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Section: 钠电池的种类及特点unclassified

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Progress of sodium battery failure research

Feng¹,

Yu²,

Cheng³

et al. 2020

Sci. Sin.-Chim

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“…Despite the similarity in their electrochemical operation mechanisms of both LIBs and SIBs, however, the electrode materials of LIBs are incompatible with those of SIBs because of different ionic radii between the sodium ion (Na + : 0.102 nm) and the lithium ion (Li + : 0.076 nm) [ 4 ]. For instance, although crystalline graphite is adequate as a commercial LIB anode [ 5 , 6 ], the weak Na + intercalation into graphite [ 7 , 8 ] makes it inappropriate as an SIB anode [ 9 ]. Therefore, developing an excellent anode material is essential for demonstrating high-performance SIBs.…”

Section: Introductionmentioning

confidence: 99%

One-Pot Synthesized Biomass C-Si Nanocomposites as an Anodic Material for High-Performance Sodium-Ion Battery

Lee

Kim

2020

Nanomaterials

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Aiming at materializing an excellent anodic source material of the high-performance sodium-ion battery (SIB), we fabricated the biomass carbon-silicon (C-Si) nanocomposites by the one-pot synthesis of facile magnesiothermic reduction using brown rice husk ashes. The C-Si nanocomposites displayed an aggregated morphology, where the spherical Si nanoparticles (9 nm on average) and the C nanoflakes were encapsulated and decorated with each other. When utilizing the nanocomposites as an SIB anode, a high initial discharge capacity (i.e., 378 mAh/g at 100 mA/g) and a high reversible capacity (i.e., 122 mAh/g at 200 mA/g) were achieved owing to their enhanced electronic and ionic conductivities. Moreover, the SIB device exhibited a high cyclic stability in its Coulombic efficiency (i.e., 98% after 100 charge-discharge cycles at 200 mA/g). These outstanding results depict that the one-pot synthesized biomass C-Si nanocomposites are beneficial for future green energy-storage technology.

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“…Sodium-ion batteries (SIBs) are promising alternative for LIBs due to sodium’s higher abundance, more even distribution and lower price compared to lithium [ 5 ]. For the materials choices, the larger ionic radius of Na + versus Li + (0.102 nm versus 0.076 nm) makes it impracticable to simply adopt most of the current anodes such as graphite for LIBs, exploration of appropriate anodes for SIBs is thus still necessary [ 6 ].…”

Section: Introductionmentioning

confidence: 99%

Cr2P2O7 as a Novel Anode Material for Sodium and Lithium Storage

et al. 2020

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The development of new appropriate anode material with low cost is still main issue for sodium-ion batteries (SIBs) and lithium-ion batteries (LIBs). Here, Cr2P2O7 with an in-situ formed carbon layer has been fabricated through a facile solid-state method and its storage performance in SIBs and LIBs has been reported first. The Cr2P2O7@C delivers 238 mA h g−1 and 717 mA h g−1 at 0.05 A g−1 in SIBs and LIBs, respectively. A capacity of 194 mA h g−1 is achieved in SIBs after 300 cycles at 0.1 A g−1 with a high capacity retention of 92.4%. When tested in LIBs, 351 mA h g−1 is maintained after 600 cycles at 0.1 A g−1. The carbon coating layer improves the conductivity and reduces the side reaction during the electrochemical process, and hence improves the rate performance and enhances the cyclic stability.

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Prospects in anode materials for sodium ion batteries - A review

Cited by 343 publications

References 230 publications

Progress of sodium battery failure research

Progress of sodium battery failure research

One-Pot Synthesized Biomass C-Si Nanocomposites as an Anodic Material for High-Performance Sodium-Ion Battery

Cr2P2O7 as a Novel Anode Material for Sodium and Lithium Storage

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