Atomistic Simulations of the Defect Chemistry and Self-Diffusion of Li-ion in LiAlO2

Kuganathan, Navaratnarajah; Dark, James; Sgourou, E. N.; Panayiotatos, Y.; Chroneos, Alexander

doi:10.3390/en12152895

Cited by 10 publications

(11 citation statements)

References 57 publications

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“…In the present study, charged particles interact via the long-range Coulomb potential supplemented by the short-range Buckingham potential (eq ) V i j = 1 4 π ε 0 q i q j r i j + [ A i j exp true( − r i j ρ i j true) − C i j r i j 6 ] here i and j denote an interacting pair of two ions among lithium, aluminum, and oxygen separated by a distance r ij , ε 0 stands for the dielectric constant. The Buckingham potential parameters are taken from Kuganathan et al and are listed in Table . Oxygen atoms’ polarizability is included using the core–shell model, in which a harmonic spring connects the positive core (charge +0.8) with the negative shell (charge −2.8).…”

Section: Experimental and Computational Methodsmentioning

confidence: 99%

“…MD studies found that networks present in TiO 2 –FeO–Na 2 O melt significantly impact viscosity and solidification processes in slags . MD simulations of lithium aluminum oxides have been used to study the defect chemistry and sophisticated potentials could be developed due to the simple crystal structures and strong ionicity among ternary lithium-containing oxides. , However, less attention was paid to transport properties, such as viscosity. Here, we study individual ion diffusivity and viscosity of Li–Al–O-compounds with different Li/Al ratios according to their thermodynamically predicted phase diagram.…”

Section: Introductionmentioning

confidence: 99%

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Engineering Compounds for the Recovery of Critical Elements from Slags: Melt Characteristics of Li₅AlO₄, LiAlO₂, and LiAl₅O₈

Hampel,

Alhafez,

Schirmer

et al. 2024

ACS Omega

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Engineered artificial minerals (EnAMs) are the core of a new concept of designing scavenger compounds for the recovery of critical elements from slags. It requires a fundamental understanding of solidification from complex oxide melts. Ion diffusivity and viscosity play vital roles in this process. In the melt, phase separations and ion transport give rise to gradients/ increments in composition and, with it, to ion diffusivity, temperature, and viscosity. Due to this complexity, solidification phenomena are yet not well understood. If the melt is understood as increments of simple composition on a microscopic level, then the properties of these are more easily accessible from models and experiments. Here, we obtain these data for three stoichiometric lithium aluminum oxides. LiAlO 2 is a promising EnAM for the recovery of lithium from lithium-ion battery pyrometallurgical processing. It is obtained through the addition of aluminum to the recycling slag melt. The high temperature properties spanning from below to above the liquidus temperature of three stoichiometric Li−Al−Oxides: Li 5 AlO 4 , LiAlO 2 , and LiAl 5 O 8 are determined using molecular dynamic simulations. The compounds are also synthesized via the sol−gel route. The Li + ion exhibits the largest diffusivity. They are quite mobile already below the liquidus temperature, i.e., for LiAlO 2 at T = 1700 K, the diffusion coefficient of the lithium ion equals D = 3.0 × 10 −9 m 2 s −1 . The other ions Al 3+ and O 2− do not move considerably at that temperature. The diffusivity of Li + is largest in the lithium-rich compound Li 5 AlO 4 with D = 32 × 10 −9 m 2 s −1 at 2500 K. The lower the viscosity, the higher the lithium content. The Li 5 AlO 4 exhibits a viscosity of η = 2.2 mPa s at 1328 K which matches well with the experimentally determined 2.5 mPa s at this temperature. The viscosity of LiAlO 2 at 1800 K is more than two times higher. These data sets can help to describe the melts on a microscopic level and understand how the melt properties will change due to gradients in the Li/Al concentration.

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Section: Experimental and Computational Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Engineering Compounds for the Recovery of Critical Elements from Slags: Melt Characteristics of Li₅AlO₄, LiAlO₂, and LiAl₅O₈

Hampel,

Alhafez,

Schirmer

et al. 2024

ACS Omega

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“…The current simulation can provide useful information about migration paths and their activation energies. In a previous work, we used this methodology to identify diffusion paths and activation energies for a variety of Li-and Na-ion battery materials [18][19][20][21][22][23][24][25][26][27][28][29][30][31][32][33][34][35][36][37]. Using classical potential simulation, the Li-ion migration path and activation energy were calculated in LiFePO 4 by Fisher et al [48].…”

Section: Mg-ion Diffusionmentioning

confidence: 99%

Mg6MnO8 as a Magnesium-Ion Battery Material: Defects, Dopants and Mg-Ion Transport

2019

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Rechargeable magnesium ion batteries have recently received considerable attention as an alternative to Li- or Na-ion batteries. Understanding defects and ion transport is a key step in designing high performance electrode materials for Mg-ion batteries. Here we present a classical potential-based atomistic simulation study of defects, dopants and Mg-ion transport in Mg6MnO8. The formation of the Mg–Mn anti-site defect cluster is calculated to be the lowest energy process (1.73 eV/defect). The Mg Frenkel is calculated to be the second most favourable intrinsic defect and its formation energy is 2.84 eV/defect. A three-dimensional long-range Mg-ion migration path with overall activation energy of 0.82 eV is observed, suggesting that the diffusion of Mg-ions in this material is moderate. Substitutional doping of Ga on the Mn site can increase the capacity of this material in the form of Mg interstitials. The most energetically favourable isovalent dopant for Mg is found to be Fe. Interestingly, Si and Ge exhibit exoergic solution enthalpy for doping on the Mn site, requiring experimental verification.

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“…The present study aims to examine the crystallographic defects in Li-ion diffusion paths together with activation energies and the impact of dopants in these materials, using force field methods, as reported in previous studies [22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,38,39,40,41,42,43,44] for various battery materials. DFT method was applied to study the electronic structure of promising dopants substituted at the Ti site in Li 2 Ti 6 O 13 .…”

Section: Introductionmentioning

confidence: 99%

Defects, Diffusion, and Dopants in Li2Ti6O13: Atomistic Simulation Study

2019

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In this study, force field-based simulations are employed to examine the defects in Li-ion diffusion pathways together with activation energies and a solution of dopants in Li2Ti6O13. The lowest defect energy process is found to be the Li Frenkel (0.66 eV/defect), inferring that this defect process is most likely to occur. This study further identifies that cation exchange (Li–Ti) disorder is the second lowest defect energy process. Long-range diffusion of Li-ion is observed in the bc-plane with activation energy of 0.25 eV, inferring that Li ions move fast in this material. The most promising trivalent dopant at the Ti site is Co3+, which would create more Li interstitials in the lattice required for high capacity. The favorable isovalent dopant is the Ge4+ at the Ti site, which may alter the mechanical property of this material. The electronic structures of the favorable dopants are analyzed using density functional theory (DFT) calculations.

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Atomistic Simulations of the Defect Chemistry and Self-Diffusion of Li-ion in LiAlO2

Cited by 10 publications

References 57 publications

Engineering Compounds for the Recovery of Critical Elements from Slags: Melt Characteristics of Li₅AlO₄, LiAlO₂, and LiAl₅O₈

Engineering Compounds for the Recovery of Critical Elements from Slags: Melt Characteristics of Li₅AlO₄, LiAlO₂, and LiAl₅O₈

Mg6MnO8 as a Magnesium-Ion Battery Material: Defects, Dopants and Mg-Ion Transport

Defects, Diffusion, and Dopants in Li2Ti6O13: Atomistic Simulation Study

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Atomistic Simulations of the Defect Chemistry and Self-Diffusion of Li-ion in LiAlO2

Cited by 10 publications

References 57 publications

Engineering Compounds for the Recovery of Critical Elements from Slags: Melt Characteristics of Li5AlO4, LiAlO2, and LiAl5O8

Engineering Compounds for the Recovery of Critical Elements from Slags: Melt Characteristics of Li5AlO4, LiAlO2, and LiAl5O8

Mg6MnO8 as a Magnesium-Ion Battery Material: Defects, Dopants and Mg-Ion Transport

Defects, Diffusion, and Dopants in Li2Ti6O13: Atomistic Simulation Study

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Engineering Compounds for the Recovery of Critical Elements from Slags: Melt Characteristics of Li₅AlO₄, LiAlO₂, and LiAl₅O₈

Engineering Compounds for the Recovery of Critical Elements from Slags: Melt Characteristics of Li₅AlO₄, LiAlO₂, and LiAl₅O₈