Thermal regimes of Li‐ion conductivity in β‐eucryptite

Chen, Yachao; Manna, Sukriti; Ciobanu, Cristian V.; Reimanis, Ivar E.

doi:10.1111/jace.15173

Cited by 14 publications

(14 citation statements)

References 58 publications

(197 reference statements)

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“…12 the Li-ion densities sampled during the dynamics. The unidimensional channels of ionic diffusion are compatible with published results [71,73]. The diffusion coefficient is hard to converge for the short dynamics we obtained for this system, and so quantifying the diffusion coefficient and its error cannot be done rigorously.…”

Section: B Analysis Of Lialsio4supporting

confidence: 85%

“…The structure of the β-eucryptite LiAlSiO 4 [66], referred to as LASO hereafter, is taken from COD [67] entry 9000368. It has been studied for its anisotropic expansion coefficient [68,69] and its ionic conductivity [70][71][72][73]. The structure can be described as an ordered β-quartz solid solution, with alternating aluminum and silicon planes.…”

Section: B Analysis Of Lialsio4mentioning

confidence: 99%

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Unsupervised landmark analysis for jump detection in molecular dynamics simulations

Kahle

Musaelian

Marzari

et al. 2019

Phys. Rev. Materials

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Molecular dynamics is a versatile and powerful method to study diffusion in solid-state ionic conductors, requiring minimal prior knowledge of equilibrium or transition states of the system's free energy surface. However, the analysis of trajectories for relevant but rare events, such as a jump of the diffusing mobile ion, is still rather cumbersome, requiring prior knowledge of the diffusive process in order to get meaningful results. In this work, we present a novel approach to detect the relevant events in a diffusive system without assuming prior information regarding the underlying process. We start from a projection of the atomic coordinates into a landmark basis to identify the dominant features in a mobile ion's environment. Subsequent clustering in landmark space enables a discretization of any trajectory into a sequence of distinct states. As a final step, the use of the smooth overlap of atomic positions descriptor allows distinguishing between different environments in a straightforward way. We apply this algorithm to ten Li-ionic systems and perform in-depth analyses of cubic Li7La3Zr2O12, tetragonal Li10GeP2S12, and the β-eucryptite LiAlSiO4. We compare our results to existing methods, underscoring strong points, weaknesses, and insights into the diffusive behavior of the ionic conduction in the materials investigated.

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Section: B Analysis Of Lialsio4supporting

confidence: 85%

Section: B Analysis Of Lialsio4mentioning

confidence: 99%

Unsupervised landmark analysis for jump detection in molecular dynamics simulations

Kahle

Musaelian

Marzari

et al. 2019

Phys. Rev. Materials

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“…Its generality, i.e., being applicable to a diverse range of materials (metals, ceramics, amorphous glasses, polymers, or biomolecules), along with its versatility, i.e, the ability to capture thermodynamic, mechanical, electrical and chemical behavior of materials, make it a pervasive and vital theoretical tool, as highlighted in Figure 1a. Increasingly, empirical findings are supported with analogous MD simulations to explain materials behavior at the electronic, atomistic or molecular level [12,13]. Beyond its scientific merit, the popularity of MD simulations is fueled by the advancements in the computational power, and the availability of efficient software packages (VASP [14], LAMMPS [15], ASE [16], NAMD [17], CHARMM [18], GROMACS [19], etc.)…”

Section: Introductionmentioning

confidence: 99%

Machine learning for multi-fidelity scale bridging and dynamical simulations of materials

Batra

Sankaranarayanan

2020

J. Phys. Mater.

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Molecular dynamics (MD) is a powerful and popular tool for understanding the dynamical evolution of materials at the nano and mesoscopic scales. There are various flavors of MD ranging from the high fidelity albeit computationally expensive ab-initio MD to relatively lower fidelity but much more efficient classical MD such as atomistic and coarse-grained models. Each of these different flavors of MD have been independently used by materials scientists to bring about breakthroughs in materials discovery and design. A significant gulf exists between the various MD flavors, each having varying levels of fidelity. The accuracy of DFT or ab-initio MD is generally much higher than that of classical atomistic simulations which is higher than that of coarse-grained models. Multi-fidelity scale bridging to combine the accuracy and flexibility of ab-initio MD with efficiency classical MD has been a longstanding goal. The advent of big-data analytics has brought to the forefront powerful machine learning methods that can be deployed to achieve this goal. Here, we provide our perspective on the challenges in multi-fidelity scale bridging and trace the developments leading up to the use of machine learning algorithms and data-science towards addressing this grand challenge. arXiv:2004.00232v1 [physics.comp-ph] 1 Apr 2020

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“…More importantly, while there has been a significant amount of computational effort, most have primarily involved the use of first-principles calculations based on DFT. Dynamical studies that aim at understanding the structural and phase transformation upon application of external stimuli (such as mechanical, thermal, , etc.) over time (picoseconds to microseconds) and length scales (≫tens of nanometers) are of significant importance.…”

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confidence: 99%

Multi-reward Reinforcement Learning Based Bond-Order Potential to Study Strain-Assisted Phase Transitions in Phosphorene

Koneru

Batra

Manna

et al. 2022

J. Phys. Chem. Lett.

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We introduce a multi-reward reinforcement learning (RL) approach to train a flexible bond-order potential (BOP) for 2D phosphorene based on ab initio training data sets. Our approach is based on a continuous action space Monte Carlo tree search algorithm that is general and scalable and presents an efficient multiobjective optimization scheme for highdimensional materials design problems. As a proof-of-concept, we deploy this scheme to parametrize multiple structural and dynamical properties of 2D phosphorene polymorphs. Our RL-trained BOP model adequately captures the structure, energetics, transformation barriers, equation of state, elastic constants, and phonon dispersions of various 2D P polymorphs. We use this model to probe the impact of temperature and strain rate on the phase transition from black (α-P) to blue phosphorene (β-P) through molecular dynamics simulations. A decrease in critical strain for this phase transition with increase in temperature is observed, and the underlying atomistic mechanisms are discussed.

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Thermal regimes of Li‐ion conductivity in β‐eucryptite

Cited by 14 publications

References 58 publications

Unsupervised landmark analysis for jump detection in molecular dynamics simulations

Unsupervised landmark analysis for jump detection in molecular dynamics simulations

Machine learning for multi-fidelity scale bridging and dynamical simulations of materials

Multi-reward Reinforcement Learning Based Bond-Order Potential to Study Strain-Assisted Phase Transitions in Phosphorene

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