2021 roadmap for sodium-ion batteries

Tapia‐Ruiz, Nuria; Armstrong, A. Robert; Alptekin, Hande; Amores, Marco; Au, Heather; Barker, J.; Boston, Rebecca; Brant, William R.; Brittain, Jake M; Chen, Yue; Chhowalla, Manish; Choi, Yong Seok; Costa, Silvana; Ribadeneyra, Maria Crespo; Cussen, Serena A.; Cussen, Edmund J.; David, William I. F.; Desai, Aamod V.; Dickson, Stewart A M; Eweka, E.I.; Forero-Saboya, Juan; Grey, Clare P.; Griffin, John M.; Groß, Peter; Hua, Xiao; Irvine, John T. S.; Johansson, Patrik; Jones, Martin O.; Karlsmo, Martin; Kendrick, Emma; Kim, Eun Jeong; Kolosov, Oleg; Li, Zhuangnan; Mertens, Stijn F. L.; Mogensen, Ronnie; Monconduit, Laure; Morris, Russell E.; Naylor, Andrew; Nikman, Shahin; O’Keefe, Christopher A.; Ould, Darren M. C.; Palgrave, Robert G.; Poizot, Philippe; Ponrouch, Alexandre; Renault, Stéven; Reynolds, Emily; Rudola, Ashish; Sayers, Ruth; Scanlon, David O.; Sen, Sudipta; Seymour, Valerie R.; Silván, Begoña; Sougrati, Moulay Tahar; Stievano, Lorenzo; Stone, Grant; Thomas, Christopher I.; Titirici, Maria Magdalena; Tong, Jincheng; Wood, Thomas J.; Wright, Dominic S.; Younesi, Reza

doi:10.1088/2515-7655/ac01ef

Cited by 159 publications

(119 citation statements)

References 278 publications

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“…[6] The possibility of obtaining additional capacity in Mn-based materials originating from oxygen redox chemistry has attracted considerable attention. [4,7] For example Na 4/7 [& 1/ 7 Mn 6/7 ]O 2 (where & represents a transition metal vacancy), contains Mn vacancies and therefore O 2p nonbonding orbitals which enable reversible oxygen redox. [7] Upon cycling Na 4/7 [& 1/ 7 Mn 6/7 ]O 2 , its layered structure and P3-type oxygen stacking sequence (ABBCCA) are maintained.…”

Section: Introductionmentioning

confidence: 99%

Enhanced Cycling Stability in the Anion Redox Material P3‐Type Zn‐Substituted Sodium Manganese Oxide

et al. 2022

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Sodium layered oxides showing oxygen redox activity are promising positive electrodes for sodium-ion batteries (SIBs). However, structural degradation typically results in limited reversibility of the oxygen redox activity. Herein, the effect of Zn-doping on the electrochemical properties of P3-type sodium manganese oxide, synthesised under air and oxygen is investigated for the first time. Air-Na 0.67 Mn 0.9 Zn 0.1 O 2 and Oxy-Na 0.67 Mn 0.9 Zn 0.1 O 2 exhibit stable cycling performance between 1.8 and 3.8 V, each maintaining 96 % of their initial capacity after 30 cycles, where Mn 3 + /Mn 4 + redox dominates. Increasing the voltage range to 1.8-4.3 V activates oxygen redox. For the material synthesised under air, oxygen redox activity is based on Zn, with limited reversibility. The additional transition metal vacancies in the material synthesised under oxygen result in enhanced oxygen redox reversibility with small voltage hysteresis. These results may assist the development of high-capacity and structurally stable oxygen redox-based materials for SIBs.

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Section: Introductionmentioning

confidence: 99%

Enhanced Cycling Stability in the Anion Redox Material P3‐Type Zn‐Substituted Sodium Manganese Oxide

et al. 2022

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“…However, achieving this capacity is extremely difficult due to the presence of [Fe(CN) 6 ] n− vacancies (Hurlbutt et al, 2018). Furthermore, the presence of severe phase transitions which damage the structure during operation in a battery is strongly dependent on the A + cation and [M′(CN) 6 ] n− vacancy content (Rudola et al, 2017;Tapia-Ruiz et al, 2021;Boström and Brant 2022). Despite the importance of PBAs, their accurate and consistent compositions are rarely reported.…”

Section: Introductionmentioning

confidence: 99%

Investigation of Valence Mixing in Sodium-Ion Battery Cathode Material Prussian White by Mössbauer Spectroscopy

et al. 2022

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Prussian white (PW), Na2Fe [Fe(CN)6], is a highly attractive cathode material for sustainable sodium-ion batteries due to its high theoretical capacity of ∼170 mAhg−1 and low-cost synthesis. However, there exists significant variability in the reported electrochemical performance. This variability originates from compositional flexibility possible for all Prussian blue analogs (PBAs) and is exasperated by the difficulty of accurately quantifying the specific composition of PW. This work presents a means of accurately quantifying the vacancy content, valence distribution, and, consequently, the overall composition of PW via Mössbauer spectroscopy. PW cathode material with three different sodium contents was investigated at 295 and 90 K. The observation of only two iron environments for the fully sodiated compound indicated the absence of [Fe(CN)6]4- vacancies. Due to intervalence charge transfer between iron centers at 295 K, accurate determination of valences was not possible. However, by observing the trend of spectral intensities and center shift for the nitrogen-bound and carbon-bound iron, respectively, at 90 K, valence mixing between the iron sites could be quantified. By accounting for valence mixing, the sum of iron valences agreed with the sodium content determined from elemental analysis. Without an agreement between the total valence sum and the determined composition, there exists uncertainty around the accuracy of the elemental analysis and vacancy content determination. Thus, this study offers one more stepping stone toward a more rigorous characterization of composition in PW, which will enable further optimization of properties for battery applications. More broadly, the approach is valuable for characterizing iron-based PBAs in applications where precise composition, valence determination, and control are desired.

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“…Moreover, the chemical similarities of Li and Na coupled with the already well-established knowledge in lithium-ion battery (LIB) technology allow for rapid implementation of SIBs in applications such as the grid or low-cost transportation. 1,2 Among the cathode materials researched in the field of SIBs, layered Na–Mn–O ternary compounds have been particularly relevant due to their high capacity, abundance, non-toxicity and low cost. The Na x MnO 2 ( x > 0.5) composition has been the most studied, showing a maximum theoretical capacity of 244 mA h g −1 based on the Mn 3+/4+ redox-active couple.…”

Section: Introductionmentioning

confidence: 99%

Na_2.4Al_0.4Mn_2.6O₇ anionic redox cathode material for sodium-ion batteries – a combined experimental and theoretical approach to elucidate its charge storage mechanism

et al. 2022

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2021 roadmap for sodium-ion batteries

Cited by 159 publications

References 278 publications

Enhanced Cycling Stability in the Anion Redox Material P3‐Type Zn‐Substituted Sodium Manganese Oxide

Enhanced Cycling Stability in the Anion Redox Material P3‐Type Zn‐Substituted Sodium Manganese Oxide

Investigation of Valence Mixing in Sodium-Ion Battery Cathode Material Prussian White by Mössbauer Spectroscopy

Na_2.4Al_0.4Mn_2.6O₇ anionic redox cathode material for sodium-ion batteries – a combined experimental and theoretical approach to elucidate its charge storage mechanism

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2021 roadmap for sodium-ion batteries

Cited by 159 publications

References 278 publications

Enhanced Cycling Stability in the Anion Redox Material P3‐Type Zn‐Substituted Sodium Manganese Oxide

Enhanced Cycling Stability in the Anion Redox Material P3‐Type Zn‐Substituted Sodium Manganese Oxide

Investigation of Valence Mixing in Sodium-Ion Battery Cathode Material Prussian White by Mössbauer Spectroscopy

Na2.4Al0.4Mn2.6O7 anionic redox cathode material for sodium-ion batteries – a combined experimental and theoretical approach to elucidate its charge storage mechanism

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Na_2.4Al_0.4Mn_2.6O₇ anionic redox cathode material for sodium-ion batteries – a combined experimental and theoretical approach to elucidate its charge storage mechanism