![]() ![]() ![]() īarpanda P, Ye T, Avdeev M, Chung SC, Yamada A (2013) A new polymorph of Na2MnP2O7 as a 3.6 V cathode material for sodium-ion batteries. Yuvaraj S, Oh W, Yoon W-S (2019) Recent progress on sodium vanadium fluorophosphates for high voltage sodium-ion battery application. Lu Y, Zhang S, Li Y, Xue L, Xu G, Zhang X (2014) Preparation and characterization of carbon-coated NaVPO4F as cathode material for rechargeable sodium-ion batteries. Lee KT, Ramesh TN, Nan F, Botton G, Nazar LF (2011) Topochemical synthesis of sodium metal phosphate olivines for sodium-ion batteries. īarpanda P, Lander L, Nishimura SI, Yamada A (2018) Polyanionic insertion materials for sodium-ion batteries. Zhou A, Xu Z, Gao H, Xue L, Li J, Goodenough JB (2019) Size-, water-, and defect-regulated potassium manganese hexacyanoferrate with superior cycling stability and rate capability for low-cost sodium-ion batteries. Kubota K, Kumakura S, Yoda Y, Kuroki K, Komaba S (2018) Electrochemistry and solid-state chemistry of NaMeO2 (Me = 3d transition metals). Rodriguez JR, Aguirre SB, Pol VG (2019) Role of operando microscopy techniques on the advancement of sustainable sodium-ion battery anodes. Rodriguez JR, Aguirre SB, Pol VG (2019) Understanding sodium-ion battery anodes through operando spectroscopic techniques. Īdams RA, Varma A, Pol VG (2019) Carbon anodes for nonaqueous alkali metal-ion batteries and their thermal safety aspects. Wahid M, Puthusseri D, Gawli Y, Sharma N, Ogale S (2018) Hard carbons for sodium-ion battery anodes: synthetic strategies, material properties, and storage mechanisms. Hwang JY, Myung ST, Sun YK (2017) Sodium-ion batteries: present and future. Lee JD (1999) Concise inorganic chemistry, 4Th edn. Įftekhari A, Kim D-W (2018) Sodium-ion batteries: new opportunities beyond energy storage by lithium. Wiley Interdiscip Rev Energy Environ 4:253–278. Nithya C, Gopukumar S (2015) Sodium ion batteries: a newer electrochemical storage. Tang J, Dysart AD, Pol VG (2015) Advancement in sodium-ion rechargeable batteries. Palomares V, Casas-Cabanas M, Castillo-Martínez E, Han MH, Rojo T (2013) Update on Na-based battery materials. Pan H, Hu YS, Chen L (2013) Room-temperature stationary sodium-ion batteries for large-scale electric energy storage. Slater MD, Kim D, Lee E, Johnson CS (2013) Sodium-ion batteries. Palomares V, Serras P, Villaluenga I, Hueso KB, Javier CG, Rojol T (2012) Na-ion batteries, recent advances and present challenges to become low cost energy storage systems. Qi S, Wu D, Dong Y, Liao J, Foster CW, Dwyer CO, Feng Y, Liu C, Ma J (2019) Cobalt-based electrode materials for sodium-ion batteries. Nayak PK, Yang L, Brehm W, Adelhelm P (2018) From lithium-ion to sodium-ion batteries: advantages, challenges, and surprises. ĭelmas C (2018) Sodium and sodium-ion batteries: 50 years of research. Vaalma C, Buchholz D, Weil M, Passerini S (2018) A cost and resource analysis of sodium-ion batteries. īelharouak I (2012) – Lithium ion batteries – new developments Edited by Ilias Belharouak ĭirective RE (2017) Renewables get mature. Larcher D, Tarascon JM (2015) Towards greener and more sustainable batteries for electrical energy storage. We present a comprehensive analysis of the recent developments in Na xCoO 2 and its derivative cathode materials and propose various approaches to mitigate the challenges for the near future successful commercialization of SIBs. This review discusses recent advancement in Na xCoO 2 cathode in terms of the effect of particle morphology, size, crystal structure, electronic structure, cation and anion doping, sacrificial salt, Na deficiency, effect of electrolyte salts and solvents, and thermal safety. Charge/discharge profiles of these systems exhibit plateaus, continuous changes in voltage and voltage drop, which impacts the electrochemical performance. Among the various phases of Na xCoO 2 cathode, the P2 is the most favored, because of low polarization with enhanced structural stability and high theoretical capacity of 183 mAhg −1 for the empirical formula of Na 0.74CoO 2. Among various cathodes systems, layered oxide cathodes are of great interest due to 230–245 mAhg −1 theoretical capacity with facile structure forming ability. However, the discovery of reliable cathodes, tailored amorphous carbon anodes, and compatible electrolytes is required to yield safer, longer lasting SIBs with wide operating temperature. Global interest in the development of sodium-ion batteries (SIBs) continues, largely due to the advantage of the affordable cost of sodium resources (compared to lithium), which could produce cost-effective rechargeable batteries for large-scale applications. ![]()
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