Defining Diffusion Pathways in Intercalation Cathode Materials: Some Lessons from V<sub>2</sub>O<sub>5</sub> on Directing Cation Traffic

Jesús, Luis R. De; Andrews, Justin L.; Parija, Abhishek; Banerjee, Sarbajit

doi:10.1021/acsenergylett.8b00156

Cited by 84 publications

(142 citation statements)

References 122 publications

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“…59,60 Anatase TiO 2 has high thermal and chemical stability, does not readily undergo transformation to rutile, and is not generally considered 'metastable' in the same way as, for example, chemically de-intercalated tunnel bronze structures. 47 Anatase TiO 2 therefore provides a stable structure in which frustrated coordination of Mg (and Li-ions) occurs under dilute conditions and this leads to low migration barriers for the ions. The limitation of the anatase structure is therefore not its stability under cycling, but the loss of frustrated coordination at high Mg (or Li) concentrations.…”

Section: Discussion: the Role Of Frustrationmentioning

confidence: 99%

“…6 We note that such an assumption neglects any contribution from Coulombic interactions between Mg ions and electrons localised upon Ti 3+ ions (small polarons), which are known to contribute to limited diffusion for Li-ion cathode materials 45 and may affect the mobility of Mg ions. 46,47 For comparison with anatase, the Mg diffusion barriers in the a and d polymorphs of V 2 O 5 , which is considered one of the most promising oxides for Mg ion battery cathodes 2 are $1100 and $600 meV respectively. 48,49 Similarly low barriers to that of anatase, of $600-800 meV have been identied in spinel-structured oxides.…”

Section: Mg 2+ Activation Barriers At Dilute Concentrationsmentioning

confidence: 99%

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Mg²⁺storage and mobility in anatase TiO₂: the role of frustrated coordination

McColl

Corà

2019

J. Mater. Chem. A

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Section: Discussion: the Role Of Frustrationmentioning

confidence: 99%

Section: Mg 2+ Activation Barriers At Dilute Concentrationsmentioning

confidence: 99%

Mg²⁺storage and mobility in anatase TiO₂: the role of frustrated coordination

McColl

Corà

2019

J. Mater. Chem. A

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“…The coordination in the δ phase has also been described as 'tetrahedral', with the distances to the O3 ions considered too long to be real coordination lengths, leaving coordination to two O2 ions in one layer and two O1 ions in the adjacent layer. 28,33 The relative stability of the α and δ -phases is clearly linked with the size of the interlayer ion M: smaller M ions have a preference for the lower (4+2) coordination in the δ phase, and stabilise it, whilst larger M ions favour the higher coordination number (8) in the α phase.…”

Section: Relative Stability Of M-incorporated α and δ -V 2 Omentioning

confidence: 99%

“…23,24 Electronic conductivity and formation of stable localised lattice distortions (polarons) are additional factors proposed to affect mobility of intercalated ions in V 2 O 5 . [25][26][27][28][29] One key factor affecting intercalation in Mg x V 2 O 5 is the crystal structure at varying x compositions. The structure of V 2 O 5 has been investigated as a Li-ion battery cathode, and it is known to undergo multiple phase changes upon lithiation.…”

Section: Introductionmentioning

confidence: 99%

Phase stability of intercalated V₂O₅ battery cathodes elucidated through the Goldschmidt tolerance factor

McColl

Corà

2019

Phys. Chem. Chem. Phys.

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Orthorhombic V 2 O 5 is a promising Mg battery cathode material, and reversible intercalation in the layered α-phase has been claimed experimentally. However, these results, based on electrochemistry and XRD, are controversial. Previous computational studies have predicted high activation barriers (∼1 eV) for ionic migration in α-V 2 O 5 , although improved Mg 2+ mobility is expected in the δ -phase. Here, hybrid-exchange density functional theory is used to discuss structure, stability and intercalation in the α and δ phases, beginning with a model system with MV 2 O 5 stoichiometry, and varying ionic radius of the M cations. The relative stability of the two phases upon intercalation of M is rationalised through a tolerance factor-like behavioural trend, providing a framework for phase selection using intercalants of different ionic size. This tolerance factor behaviour is due to the presence of ferroelectrically distorted (2×2×2) perovskite blocks within the α-V 2 O 5 structure. The δ -phase is found to undergo a barrierless phase change to α in fully charged (de-intercalated) Mg x V 2 O 5 (x=0), indicating that stabilisation of δ -Mg x V 2 O 5 is required at low x if the δ phase is to be retained for higher Mg mobility. By employing dispersion interactions to accurately reproduce the interlayer distance, activation barriers for ion migration are found to be higher than reported in previous studies, clarifying questions regarding the extent of Mg intercalation that can be achieved experimentally. Interlayer ions are found to lower activation barriers for Mg 2+ mobility by up to ∼330 meV in the α phase by expanding the interlayer space. The results address open questions about the electrochemical performance of orthorhombic V 2 O 5 as Mg battery cathode material, and indicate atomic level mechanisms that activate ionic mobility in layered V 2 O 5 .One fundamental route to improving energy density is to move from sulphide to oxide based materials which have higher ionic character, thus providing higher voltages vs. Mg metal, whilst the lower atomic mass of O relative to S reduces weight. 7 However the very feature that enhances intercalation voltage, i.e. the stronger electrostatic interaction between the Mg ion and the anionic framework of the oxide cathode host, also increases acti-J o u r n a l N a me , [ y e a r ] , [ v o l . ] , 1-13 | 1 2 | 1-13 J o u r n a l N a me , [ y e a r ] , [ v o l . ] ,

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“…Unfortunately, a large capacity loss of almost 40% after only 30 cycles was observed, which definitely hindered the application for layered V 2 O 5 · n H 2 O as cathode for high energy and power SICs. Several investigations indicate that the origins of capacity loss for vanadium oxides are the collapse of layer structure, self‐trapping of polarons, and decrease of conductivity during Na + (de)intercalations . Hence, metal ions preintercalation as “pillar effect” was proposed to enhance the layered structure and restrain the “lattice breathing”, which has shown an enhancement of the cycling stability .…”

mentioning

confidence: 99%

Strongly Coupled Pyridine‐V₂O₅·nH₂O Nanowires with Intercalation Pseudocapacitance and Stabilized Layer for High Energy Sodium Ion Capacitors

Dong

Jiang

Wei

et al. 2019

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Developing pseudocapacitive cathodes for sodium ion capacitors (SICs) is very significant for enhancing energy density of SICs. Vanadium oxides cathodes with pseudocapacitive behavior are able to offer high capacity. However, the capacity fading caused by the irreversible collapse of layer structure remains a major issue. Herein, based on the Acid–Base Proton theory, a strongly coupled layered pyridine‐V2O5·nH2O nanowires cathode is reported for highly efficient sodium ion storage. By density functional theory calculations, in situ X‐ray diffraction, and ex situ Fourier‐transform infrared spectroscopy, a strong interaction between protonated pyridine and VO group is confirmed and stable during cycling. The pyridine‐V2O5·nH2O nanowires deliver long‐term cyclability (over 3000 cycles), large pseudocapacitive behavior (78% capacitive contribution at 1 mV s−1) and outstanding rate capability. The assembled pyridine‐V2O5·nH2O//graphitic mesocarbon microbead SIC delivers high energy density of ≈96 Wh kg−1 (at 59 W kg−1) and power density of 14 kW kg−1 (at 37.5 Wh kg−1). The present work highlights the strategy of realizing strong interaction in the interlayer of V2O5·nH2O to enhance the electrochemical performance of vanadium oxides cathodes. The strategy could be extended for improving the electrochemical performance of other layered materials.

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Defining Diffusion Pathways in Intercalation Cathode Materials: Some Lessons from V₂O₅ on Directing Cation Traffic

Cited by 84 publications

References 122 publications

Mg²⁺storage and mobility in anatase TiO₂: the role of frustrated coordination

Mg²⁺storage and mobility in anatase TiO₂: the role of frustrated coordination

Phase stability of intercalated V₂O₅ battery cathodes elucidated through the Goldschmidt tolerance factor

Strongly Coupled Pyridine‐V₂O₅·nH₂O Nanowires with Intercalation Pseudocapacitance and Stabilized Layer for High Energy Sodium Ion Capacitors

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Defining Diffusion Pathways in Intercalation Cathode Materials: Some Lessons from V2O5 on Directing Cation Traffic

Cited by 84 publications

References 122 publications

Mg2+storage and mobility in anatase TiO2: the role of frustrated coordination

Mg2+storage and mobility in anatase TiO2: the role of frustrated coordination

Phase stability of intercalated V2O5 battery cathodes elucidated through the Goldschmidt tolerance factor

Strongly Coupled Pyridine‐V2O5·nH2O Nanowires with Intercalation Pseudocapacitance and Stabilized Layer for High Energy Sodium Ion Capacitors

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Defining Diffusion Pathways in Intercalation Cathode Materials: Some Lessons from V₂O₅ on Directing Cation Traffic

Mg²⁺storage and mobility in anatase TiO₂: the role of frustrated coordination

Mg²⁺storage and mobility in anatase TiO₂: the role of frustrated coordination

Phase stability of intercalated V₂O₅ battery cathodes elucidated through the Goldschmidt tolerance factor

Strongly Coupled Pyridine‐V₂O₅·nH₂O Nanowires with Intercalation Pseudocapacitance and Stabilized Layer for High Energy Sodium Ion Capacitors