Towards Reversible High-Voltage Multi-Electron Reactions in Alkali-Ion Batteries Using Vanadium Phosphate Positive Electrode Materials

Towards Reversible High-Voltage Multi-Electron Reactions in Alkali-Ion Batteries Using Vanadium Phosphate Positive Electrode Materials

Vanadium phosphate positive electrode materials attract great interest in the field of Alkali-ion (Li, Na and K-ion) batteries due to their ability to store several electrons per transition metal. These multi-electron reactions (from V<sup>2+</sup> to V<sup>5+</sup>) combined...

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Main Authors: Edouard Boivin, Jean-Noël Chotard, Christian Masquelier, Laurence Croguennec
Format: Article
Language:English
Published: MDPI AG 2021-03-01
Series:Molecules
Subjects:
batteries
positive electrode
vanadium phosphates
covalent vanadyl bond
mixed anion
Online Access:https://www.mdpi.com/1420-3049/26/5/1428
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spelling doaj-df9f6223689d446b912cf4b3dbf59b312021-03-07T00:01:09ZengMDPI AGMolecules1420-30492021-03-01261428142810.3390/molecules26051428Towards Reversible High-Voltage Multi-Electron Reactions in Alkali-Ion Batteries Using Vanadium Phosphate Positive Electrode MaterialsEdouard Boivin0Jean-Noël Chotard1Christian Masquelier2Laurence Croguennec3Laboratoire de Réactivité et de Chimie des Solides, CNRS-UMR 7314, Université de Picardie Jules Verne, CEDEX 1, F-80039 Amiens, FranceLaboratoire de Réactivité et de Chimie des Solides, CNRS-UMR 7314, Université de Picardie Jules Verne, CEDEX 1, F-80039 Amiens, FranceLaboratoire de Réactivité et de Chimie des Solides, CNRS-UMR 7314, Université de Picardie Jules Verne, CEDEX 1, F-80039 Amiens, FranceCNRS, Université Bordeaux, Bordeaux INP, ICMCB UMR 5026, F-33600 Pessac, FranceVanadium phosphate positive electrode materials attract great interest in the field of Alkali-ion (Li, Na and K-ion) batteries due to their ability to store several electrons per transition metal. These multi-electron reactions (from V<sup>2+</sup> to V<sup>5+</sup>) combined with the high voltage of corresponding redox couples (e.g., 4.0 V vs. for V<sup>3+</sup>/V<sup>4+</sup> in Na<sub>3</sub>V<sub>2</sub>(PO<sub>4</sub>)<sub>2</sub>F<sub>3</sub>) could allow the achievement the 1 kWh/kg milestone at the positive electrode level in Alkali-ion batteries. However, a massive divergence in the voltage reported for the V<sup>3+</sup>/V<sup>4+</sup> and V<sup>4+</sup>/V<sup>5+</sup> redox couples as a function of crystal structure is noticed. Moreover, vanadium phosphates that operate at high V<sup>3+</sup>/V<sup>4+</sup> voltages are usually unable to reversibly exchange several electrons in a narrow enough voltage range. Here, through the review of redox mechanisms and structural evolutions upon electrochemical operation of selected widely studied materials, we identify the crystallographic origin of this trend: the distribution of PO<sub>4</sub> groups around vanadium octahedra, that allows or prevents the formation of the vanadyl distortion (O<b><sup>…</sup></b>V<sup>4+</sup>=O or O<b><sup>…</sup></b>V<sup>5+</sup>=O). While the vanadyl entity massively lowers the voltage of the V<sup>3+</sup>/V<sup>4+</sup> and V<sup>4+</sup>/V<sup>5+</sup> couples, it considerably improves the reversibility of these redox reactions. Therefore, anionic substitutions, mainly O<sup>2−</sup> by F<sup>−</sup>, have been identified as a strategy allowing for combining the beneficial effect of the vanadyl distortion on the reversibility with the high voltage of vanadium redox couples in fluorine rich environments.https://www.mdpi.com/1420-3049/26/5/1428batteriespositive electrodevanadium phosphatescovalent vanadyl bondmixed anion
collection DOAJ
language English
format Article
sources DOAJ
author Edouard Boivin
Jean-Noël Chotard
Christian Masquelier
Laurence Croguennec
spellingShingle Edouard Boivin
Jean-Noël Chotard
Christian Masquelier
Laurence Croguennec
Towards Reversible High-Voltage Multi-Electron Reactions in Alkali-Ion Batteries Using Vanadium Phosphate Positive Electrode Materials
Molecules
batteries
positive electrode
vanadium phosphates
covalent vanadyl bond
mixed anion
author_facet Edouard Boivin
Jean-Noël Chotard
Christian Masquelier
Laurence Croguennec
author_sort Edouard Boivin
title Towards Reversible High-Voltage Multi-Electron Reactions in Alkali-Ion Batteries Using Vanadium Phosphate Positive Electrode Materials
title_short Towards Reversible High-Voltage Multi-Electron Reactions in Alkali-Ion Batteries Using Vanadium Phosphate Positive Electrode Materials
title_full Towards Reversible High-Voltage Multi-Electron Reactions in Alkali-Ion Batteries Using Vanadium Phosphate Positive Electrode Materials
title_fullStr Towards Reversible High-Voltage Multi-Electron Reactions in Alkali-Ion Batteries Using Vanadium Phosphate Positive Electrode Materials
title_full_unstemmed Towards Reversible High-Voltage Multi-Electron Reactions in Alkali-Ion Batteries Using Vanadium Phosphate Positive Electrode Materials
title_sort towards reversible high-voltage multi-electron reactions in alkali-ion batteries using vanadium phosphate positive electrode materials
publisher MDPI AG
series Molecules
issn 1420-3049
publishDate 2021-03-01
description Vanadium phosphate positive electrode materials attract great interest in the field of Alkali-ion (Li, Na and K-ion) batteries due to their ability to store several electrons per transition metal. These multi-electron reactions (from V<sup>2+</sup> to V<sup>5+</sup>) combined with the high voltage of corresponding redox couples (e.g., 4.0 V vs. for V<sup>3+</sup>/V<sup>4+</sup> in Na<sub>3</sub>V<sub>2</sub>(PO<sub>4</sub>)<sub>2</sub>F<sub>3</sub>) could allow the achievement the 1 kWh/kg milestone at the positive electrode level in Alkali-ion batteries. However, a massive divergence in the voltage reported for the V<sup>3+</sup>/V<sup>4+</sup> and V<sup>4+</sup>/V<sup>5+</sup> redox couples as a function of crystal structure is noticed. Moreover, vanadium phosphates that operate at high V<sup>3+</sup>/V<sup>4+</sup> voltages are usually unable to reversibly exchange several electrons in a narrow enough voltage range. Here, through the review of redox mechanisms and structural evolutions upon electrochemical operation of selected widely studied materials, we identify the crystallographic origin of this trend: the distribution of PO<sub>4</sub> groups around vanadium octahedra, that allows or prevents the formation of the vanadyl distortion (O<b><sup>…</sup></b>V<sup>4+</sup>=O or O<b><sup>…</sup></b>V<sup>5+</sup>=O). While the vanadyl entity massively lowers the voltage of the V<sup>3+</sup>/V<sup>4+</sup> and V<sup>4+</sup>/V<sup>5+</sup> couples, it considerably improves the reversibility of these redox reactions. Therefore, anionic substitutions, mainly O<sup>2−</sup> by F<sup>−</sup>, have been identified as a strategy allowing for combining the beneficial effect of the vanadyl distortion on the reversibility with the high voltage of vanadium redox couples in fluorine rich environments.
topic batteries
positive electrode
vanadium phosphates
covalent vanadyl bond
mixed anion
url https://www.mdpi.com/1420-3049/26/5/1428
work_keys_str_mv AT edouardboivin towardsreversiblehighvoltagemultielectronreactionsinalkaliionbatteriesusingvanadiumphosphatepositiveelectrodematerials
AT jeannoelchotard towardsreversiblehighvoltagemultielectronreactionsinalkaliionbatteriesusingvanadiumphosphatepositiveelectrodematerials
AT christianmasquelier towardsreversiblehighvoltagemultielectronreactionsinalkaliionbatteriesusingvanadiumphosphatepositiveelectrodematerials
AT laurencecroguennec towardsreversiblehighvoltagemultielectronreactionsinalkaliionbatteriesusingvanadiumphosphatepositiveelectrodematerials
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