Critical overview of polyanionic frameworks as positive electrodes for Na-ion batteries

Deb, Debolina; Gautam, Gopalakrishnan Sai

doi:10.1557/s43578-022-00646-7

Cited by 10 publications

(10 citation statements)

References 277 publications

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“…In the case of layered and disordered cathodes, anionic redox is almost always associated with irreversible structural changes, leading to voltage hysteresis/fading, and also oxygen evolution (resulting from oxygen dimerization). [8][9][10] Polyanionic cathodes, which are typically resistant to ''large'' structural changes, 54,55 can provide a platform for a different anionic redox mechanism. For example, the strong, covalent X-O bonds within the XO 4 polyhedral units may resist oxygen dimerization and evolution, resulting in minimal irreversible structural changes and voltage fade.…”

Section: Discussionmentioning

confidence: 99%

First principles investigation of anionic redox in bisulfate lithium battery cathodes

Jha

Singh

Shrivastava

et al. 2022

Phys. Chem. Chem. Phys.

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Section: Discussionmentioning

confidence: 99%

First principles investigation of anionic redox in bisulfate lithium battery cathodes

Jha

Singh

Shrivastava

et al. 2022

Phys. Chem. Chem. Phys.

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“…The Natrium Super-Ionic CONdcutor (NaSICON) with the composition Na 1+ x Zr 2 Si x P 3– x O 12 is a well-known ceramic solid-electrolyte for all-solid-state Na-ion batteries, ,− with impressive ion-conductivities of ∼4 mS cm –1 at 298 K (for composition Na 3.4 Zr 2 Si 2.4 P 0.6 O 12 ) . NaSICON provides a versatile framework, incorporating both cations (Na + and Zr 4+ ) and anion ( normalS normali O 4 4 − and normalP O 4 3 − ) moieties, which enable the number of Na + ions to vary between 1 and 4 per f.u.…”

Section: Kinetic Monte Carlo Applied To Na1+x Zr2si X P3–x O12 Ion-co...mentioning

confidence: 99%

Pushing Forward Simulation Techniques of Ion Transport in Ion Conductors for Energy Materials

Canepa

2022

ACS Mater. Au

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Simulation techniques are crucial to establish a firm link between phenomena occurring at the atomic scale and macroscopic observations of functional materials. Importantly, extensive sampling of space and time scales is paramount to ensure good convergence of physically relevant quantities to describe ion transport in energy materials. Here, a number of simulation methods to address ion transport in energy materials are discussed, with the pros and cons of each methodology put forward. Emphasis is given to the stochastic nature of results produced by kinetic Monte Carlo, which can adequately account for compositional disorder across multiple sublattices in solids.

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“…Having achieved widespread commercialization, rechargeable lithium (Li)-ion batteries (LIBs) are now at the risk of geopolitically constrained supply chains of key raw materials, such as cobalt, nickel, and Li. − Sodium (Na)-ion batteries (SIBs) appear to be promising alternatives to the LIB analogs, as Na-metal can be harvested directly from seawater. − Extensive research is underway to optimize electrodes and electrolytes for SIBs. − One of the material classes for NIBs is the polyanionic sodium superionic conductor (NaSICON), discovered by Hong et al, , a framework studied for its fast Na-conducting properties. Electrodes crystallizing in the NaSICON framework, with formula Na x M 2 (PO 4 ) 3 (where M = transition metal), can be highly tuned to achieve promising energy densities, ,, by changing the ratio and types of transition metals in the NaSICON, such as Na x TiV(PO 4 ) 3 , Na x TiMn(PO 4 ) 3 , Na x VMn(PO 4 ) 3 , and Na x CrMn(PO 4 ) 3 . , …”

Section: Introductionmentioning

confidence: 99%

Kinetic Monte Carlo Simulations of Sodium Ion Transport in NaSICON Electrodes

Wang,

Mishra,

Xie

et al. 2023

ACS Materials Lett.

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The development of high-performance sodium (Na) ion batteries requires improved electrode materials. The energy and power densities of Na superionic conductor (NaSICON) electrode materials are promising for large-scale energy storage applications. However, several practical issues limit the full utilization of the theoretical energy densities of the NaSICON electrodes. A pressing challenge lies in the limited sodium extraction in low Na content NaSICONs, e.g., Na1VIVVIV(PO4)3 ↔ VVVIV(PO4)3 + e– + Na+. Therefore, it is important to quantify the Na-ion mobility in a broad range of NaSICON electrodes. Using a kinetic Monte Carlo approach bearing the accuracy of first-principles calculations, we elucidate the variability of Na-ion transport vs Na content in three important NaSICON electrode materials, Na x Ti2(PO4)3, Na x V2(PO4)3, and Na x Cr2(PO4)3. We show Na+ transport in NaSICON electrode materials is almost entirely determined by the local electrostatic and chemical environment set by the transition metals and the polyanionic scaffold. The competition with the ordering-disordering phenomena of Na vacancies also plays a role in influencing Na transport. We identify the Na content providing the highest room-temperature diffusivities in these electrodes, i.e., Na2.7Ti2(PO4)3, Na2.9V2(PO4)3, and Na2.6Cr2(PO4)3. We link the variations in the Na+ kinetic properties by analyzing the competition of ligand field stabilization transition metal ions and their ionic radii. We interpret the limited Na extraction at x = 1 observed experimentally by gaining insights into the local Na vacancy interplay. Targeted chemical substitutions of transition metals disrupting local charge arrangements will be critical to reducing the occurrence of strong Na+-vacancy orderings at low Na concentrations, thus expanding the accessible capacities of these electrode materials.

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Critical overview of polyanionic frameworks as positive electrodes for Na-ion batteries

Cited by 10 publications

References 277 publications

First principles investigation of anionic redox in bisulfate lithium battery cathodes

First principles investigation of anionic redox in bisulfate lithium battery cathodes

Pushing Forward Simulation Techniques of Ion Transport in Ion Conductors for Energy Materials

Kinetic Monte Carlo Simulations of Sodium Ion Transport in NaSICON Electrodes

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