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J. Phys. Energy 3 (2021) 031503 N Tapia-Ruiz et al [13] Li Z-Y, Gao R, Zhang J, Zhang X, Hu Z and Liu X 2016 New insights into designing high-rate performance cathode materials for sodium ion batteries by enlarging the slab-spacing of the Na-ion diffusion layer J. Mater. Chem. A 4 3453–61 [14] Yoshida H, Yabuuchi N, Kubota K, Ikeuchi I, Garsuch A, Schulz-Dobrick M and Komaba S 2014 P2-type Na2/3Ni1/3Mn2/3–xTixO2 as a new positive electrode for higher energy Na-ion batteries Chem. Commun. 50 3677–80 [15] Barker J and Heap R 2019 O3/P2 mixed phase sodium-containing doped layered oxide materials Patent WO 2019/197812 [16] Assat G and Tarascon J-M 2018 Fundamental understanding and practical challenges of anionic redox activity in Li-ion batteries Nat. Energy 3 373 [17] Maitra U et al 2018 Oxygen redox chemistry without excess alkali-metal ions in Na2/3[Mg0.28Mn0.72]O2 Nat. Chem. 10 288 [18] Zheng W, Liu Q, Wang Z, Wua Z, Gu S, Cao L, Zhang K, Fransaer J and Lu Z 2020 Oxygen redox activity with small voltage hysteresis in Na0.67Cu0.28Mn0.72O2 for sodium-ion batteries Energy Storage Mater. 28 300 [19] House R A et al 2020 Superstructure control of first-cycle voltage hysteresis in oxygen-redox cathodes Nature 577 502 [20] Parant J-P, Olazcuaga R, Devalette M, Fouassier C and Hagenmuller P 1971 Sur quelques nouvelles phases de formule NaxMnO2 (x ⩽ 1) J. Solid State Chem. 3 1 [21] House R A et al 2019 What triggers oxygen loss in oxygen redox cathode materials? Chem. Mater. 31 3293 [22] Radin M D, Vinckeviciute J, Seshadri R and Van der Ven A 2019 Manganese oxidation as the origin of the anomalous capacity of Mn-containing Li-excess cathode materials Nat. Energy 4 639 [23] Ma L A, Massel F, Naylor A J, Duda L-C and Younesi R 2019 Understanding charge compensation mechanisms in Na0.56Mg0.04Ni0.19Mn0.70O2 Commun. Chem. 2 125 [24] Mortemard De Boisse B, Nishimura S, Watanabe E, Lander L, Tsuchimoto A, Kikkawa J, Kobayashi E, Asakura D, Okubo M and Yamada A 2018 Highly reversible oxygen-redox chemistry at 4.1 V in Na4/7−x [□1/7Mn6/7]O2 (□: Mn vacancy) Adv. Energy Mater. 8 1800409 [25] Wang P-F et al 2020 Both cationic and anionic redox chemistry in a P2-type sodium layered oxide Nano Energy 69 104474 [26] Sharifi-Asl S, Lu J, Amine K and Shahbazian-Yassar R 2019 Oxygen release degradation in Li-ion battery cathode materials: mechanisms and mitigating approaches Adv. Energy Mater. 9 1900551 [27] Chen S, Wen K, Fan J, Bando Y and Golberg D 2018 Progress and future prospects of high-voltage and high-safety electrolytes in advanced lithium batteries: from liquid to solid electrolytes J. Mater. Chem. A 6 11631 [28] Barpanda P, Lander L, Nishimura S and Yamada A 2018 Polyanionic insertion materials for sodium-ion batteries Adv. Energy Mater. 8 17030550–26 [29] Li H, Xu M, Zhang Z, Lai Y and Ma J 2020 Engineering of polyanion type cathode materials for sodium-ion batteries: toward higher energy/power density Adv. Funct. Mater. 30 2000473-1–29 [30] Chotard J-N, Rousse G, David R, Mentré O, Courty M and Masquelier C 2015 Discovery of a sodium-ordered form of Na3V2(PO4)3 below ambient temperature Chem. Mater. 27 5982–7 [31] Bianchini M, Brisset N, Fauth F, Weill F, Elkaim E, Suard E, Masquelier C and Croguennec L 2014 Na3V2(PO4)2F3 revisited: a high-resolution diffraction study Chem. Mater. 26 4238–47 [32] Bianchini M, Xiao P, Wang Y and Ceder G 2017 Additional sodium insertion into polyanionic cathodes for higher-energy Na-ion batteries Adv. Energy Mater. 7 1700514-1–9 [33] Liang Z, Zhang X, Liu R, Ortiz G F, Zhong G, Xiang Y, Chen S, Mi J, Wu S and Yang Y 2020 New dimorphs of Na5V(PO4)2F2 as an ultrastable cathode material for sodium-ion batteries ACS Appl. Energy Mater. 3 1181–9 [34] Kim M, Kim D, Lee W, Jang H M and Kang B 2018 New class of 3.7 V Fe-based positive electrode materials for Na-ion battery based on cation-disordered polyanion framework Chem. Mater. 30 6346–52 [35] Plewa A, Kulka A, Hanc E, Zaja ̨c W, Sun J, Lu L and Molenda J 2020 Facile aqueous synthesis of high performance Na2FeM(SO4)3 (M=Fe, Mn, Ni) alluaudites for low cost Na-ion batteries J. Mater. Chem. A 8 2728–40 [36] Song T, Yao W, Kiadkhunthod P, Zheng Y, Wu N, Zhou X, Tunmee S, Sattayaporn S and Tang Y 2020 A low-cost and environmentally friendly mixed polyanionic cathode for sodium-ion storage Angew. Chem., Int. Ed. 59 740–5 [37] Mattei G S et al 2020 Enumeration as a tool for structure solution: a materials genomic approach to solving the cation-ordered structure of Na3V2(PO4)2F3 Chem. Mater. 32 8981–92 [38] Nguyen L H B, Iadecola A, Belin S, Olchowka J, Masquelier C, Carlier D and Croguennec L 2020 A combined operando synchrotron X-ray absorption spectroscopy and first-principles density functional theory study to unravel the vanadium redox paradox in the Na3V2(PO4)2F3-Na3V2(PO4)2FO2 compositions J. Phys. Chem. C 124 23511–22 [39] Liu Q, Hu Z, Chen M, Zou C, Jin H, Wang S, Chou S-L, Liu Y and Dou S-X 2020 The cathode choice for commercialization of sodium-ion batteries: layered transition metal oxides versus Prussian blue analogs Adv. Funct. Mater. 30 1909530 [40] You Y, Wu X-L, Yin Y-X and Guo Y-G 2014 High-quality Prussian blue crystals as superior cathode materials for room-temperature sodium-ion batteries Energy Environ. Sci. 7 1643–7 [41] Wang L et al 2015 Rhombohedral Prussian white as cathode for rechargeable sodium-ion batteries J. Am. Chem. Soc. 137 2548–54 [42] Li W-J, Han C, Cheng G, Chou S-L, Liu H-K and Dou S-X 2019 Chemical properties, structural properties, and energy storage applications of Prussian blue analogues Small 15 1900470 [43] Shen L, Jiang Y, Liu Y, Ma J, Sun T and Zhu N 2020 High-stability monoclinic nickel hexacyanoferrate cathode materials for ultrafast aqueous sodium ion battery Chem. Eng. J. 388 124228 [44] Rudola A, Du K and Balaya P 2017 Monoclinic sodium iron hexacyanoferrate cathode and non-flammable glyme-based electrolyte for inexpensive sodium-ion batteries J. Electrochem. Soc. 164 A1098 [45] You Y, Yao H-R, Xin S, Yin Y-X, Zuo T-T, Yang C-P, Guo Y-G, Cui Y, Wan L-J and Goodenough J B 2016 Subzero-temperature cathode for a sodium-ion battery Adv. Mater. 28 7243–8 [46] Guo X, Wang Z, Deng Z, Li X, Wang B, Chen X and Ong S P 2019 Water contributes to higher energy density and cycling stability of Prussian blue analogue cathodes for aqueous sodium-ion batteries Chem. Mater. 31 5933–42 [47] Ojwang D O, Häggström L, Ericsson T, Ångström J and Brant W R 2020 Influence of sodium content on the thermal behavior of low vacancy Prussian white cathode material Dalton Trans. 49 3570–9 [48] Chen M, Zhang Z, Liu X, Li Y, Wang Y, Fan H, Liang X and Chen Q 2020 Prussian blue coated with reduced graphene oxide as high-performance cathode for lithium–sulfur batteries RSC Adv. 10 31773–9 [49] Dehghani-Sanij A R, Tharumalingam E, Dusseault M B and Fraser R 2019 Study of energy storage systems and environmental challenges of batteries Renew. Sustain. Energy Rev. 104 192–208 [50] Peters J F, Baumann M, Zimmermann B, Braun J and Weil M 2017 The environmental impact of Li-ion batteries and the role of key parameters—a review Renew. Sustain. Energy Rev. 67 491–506 81PDF Image | roadmap for sodium-ion batteries
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