2021
DOI: 10.3389/fenrg.2021.657962
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Studies of Li2Fe0.9M0.1SO Antiperovskite Materials for Lithium–Ion Batteries: The Role of Partial Fe2+ to M2+ Substitution

Abstract: Cubic Li2Fe0.9M0.1SO antiperovskites with M–Co2+, or Mn2+ were successfully synthesized by a solid-state technique, and studied as cathode materials in Li-batteries. The influence of the Co, and Mn cation substitution of Fe in Li2FeSO on the resulting electrochemical performance was evaluated by galvanostatic cycling, while the reaction mechanism was explored by applying operando X-ray absorption and X-ray diffraction techniques using synchrotron radiation facilities. Even 10% Fe-substitution by these metals c… Show more

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Cited by 17 publications
(25 citation statements)
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“…Beyond the preliminary studies of Li 2 FeSO, anti-perovskite cathodes would be expected to benefit from the chemical flexibility of the structure to tune their properties via substitutions. 119,[169][170][171] Any transition metal with an accessible M 2+ -M 3+ redox pair is in principle usable, with Li 2 MnOS and Li 2 CoOS having already been synthesised 119 and the properties of the Cr, Cu, Mo, Ni and V analogues having been probed through DFT calculations. 169 Careful optimisation of the composition is expected to allow for the tailoring of properties, including the average operating voltage, electronic conductivity and phase stability, 169 in close analogy with commercial NMC electrodes.…”
Section: Anti-perovskite Cathodes and Their Potential Application In Solid-state Batteriesmentioning
confidence: 99%
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“…Beyond the preliminary studies of Li 2 FeSO, anti-perovskite cathodes would be expected to benefit from the chemical flexibility of the structure to tune their properties via substitutions. 119,[169][170][171] Any transition metal with an accessible M 2+ -M 3+ redox pair is in principle usable, with Li 2 MnOS and Li 2 CoOS having already been synthesised 119 and the properties of the Cr, Cu, Mo, Ni and V analogues having been probed through DFT calculations. 169 Careful optimisation of the composition is expected to allow for the tailoring of properties, including the average operating voltage, electronic conductivity and phase stability, 169 in close analogy with commercial NMC electrodes.…”
Section: Anti-perovskite Cathodes and Their Potential Application In Solid-state Batteriesmentioning
confidence: 99%
“…For example, small amounts of Co incorporation were shown to dramatically increase the accessible capacity to >250 mAh/g. 171 No reports of sodium equivalent versions (e.g., Na 2 FeOS) currently exist yet, with the exception of the recently discovered anti-Ruddlesden-Popper phase Na 2 Fe 2 OS 2 . 172 Moreover, anti-perovskite cathode materials possess certain intrinsic advantages with respect to their application in solid-state batteries.…”
Section: Anti-perovskite Cathodes and Their Potential Application In Solid-state Batteriesmentioning
confidence: 99%
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“…6 Recently, a novel class of Li-rich antiperovskite cathodes with a general formula (Li 2 TM)ChO (TM ¼ Fe, Mn, Co; Ch ¼ S, Se) was discovered and its electrochemical performance was evaluated. [7][8][9][10] These antiperovskite cathodes display a multielectron storage merit with a reversible transfer of 1.2 Li + per formula unit, resulting in an outstanding specic capacity. Besides, they offer other advantages such as reasonable working voltage ($1.2-3 V) and 3-dimensional (3D) Li + diffusion with a low diffusion barrier ($0.32 eV).…”
Section: Introductionmentioning
confidence: 99%
“…The Co substitution improves the cyclability, whereas Mn substitution deteriorates the cycling performance. 70,71 Theoretical study shows the Li-ion diffusion barrier in (Li 2 Fe)SO is only 0.32 eV, which may explain its good rate capacity. 72 73 For the Na-ion, although Na-containing analogues (Li 2−n Na n Fe)SO cannot be synthesized through solid-state reaction, Na 2 Fe 2 OS 2 with anti-RP structure can be synthesized through solid-state or mechanochemical synthesis.…”
Section: Cation Sublattice Meltingmentioning
confidence: 99%