A Quantum Monte Carlo Study of the Structural, Energetic, and Magnetic Properties of Two-Dimensional H and T Phase VSe<sub>2</sub>

Wines, Daniel; Tiihonen, Juha; Saritas, Kayahan; Krogel, Jaron T.; Ataca, Can

doi:10.1021/acs.jpclett.3c00497

Cited by 5 publications

(2 citation statements)

References 45 publications

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“…We follow the former approach. In diffusion Monte Carlo calculations of correlated oxides, a U value between 2 and 6 eV is often found 38–51 with a value near 3 eV occurring most often, and so we selected U = 3.0 eV in all calculations. In SCF and structural relaxation calculations a k -point grid of 13 × 13 × 13 per ABO 2 primitive cell (or finer) was used and relaxed structures were obtained with 10 −6 eV and 0.01 eV Å −1 tolerances on the total energy and maximum atomic force, respectively.…”

Section: Methodsmentioning

confidence: 99%

Predictions of delafossite-hosted honeycomb and kagome phases

Krogel,

Ichibha,

Saritas

et al. 2024

Phys. Chem. Chem. Phys.

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Section: Methodsmentioning

confidence: 99%

Predictions of delafossite-hosted honeycomb and kagome phases

Krogel,

Ichibha,

Saritas

et al. 2024

Phys. Chem. Chem. Phys.

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“…Nonetheless, many magnetic 2D materials exhibit strongly correlated effects and are better suited for more advanced methods that account for correlation in the outer electronic shells, such as DFT + U , − dynamical mean field theory, and quantum Monte Carlo . These methods have proven to be more accurate in describing materials manifesting strong correlation effects. − …”

Section: Methodsmentioning

confidence: 99%

Accelerated Data-Driven Discovery and Screening of Two-Dimensional Magnets Using Graph Neural Networks

Elrashidy,

Della-Giustina,

Yan

2024

J. Phys. Chem. C

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In this study, we employ graph neural networks (GNNs) to accelerate the discovery of novel 2D magnetic materials which have transformative potential in spintronic applications. Using data from the Materials Project database and the Computational 2D materials database, we train three GNN architectures on a dataset of 1190 magnetic monolayers with energy above the convex hull (E hull ) less than 0.3 eV/atom. Our Crystal Diffusion Variational Autoencoder generates 11,100 candidate crystals. Subsequent training on two Atomistic Line GNNs achieves 93% accuracy in predicting magnetic monolayers and a mean average error of 0.039 eV/atom for E hull predictions. After narrowing down candidates based on magnetic likelihood and predicted energy, constraining the atom count in the monolayers to five or fewer, and performing dimensionality checks, we identified 190 candidates. These are validated using density-functional theory to confirm their magnetic and energetic favorability, resulting in 167 magnetic monolayers with E hull < 0.3 eV/atom and a total magnetization of ≥0.5 μ B . Our methodology offers a way to accelerate the exploration and prediction of potential 2D magnetic materials, contributing to the ongoing computational and experimental efforts aimed at the discovery of new 2D magnets.

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Force-Free Identification of Minimum-Energy Pathways and Transition States for Stochastic Electronic Structure Theories

Iyer,

Whelpley,

Tiihonen

et al. 2024

J. Chem. Theory Comput.

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The accurate mapping of potential energy surfaces (PESs) is crucial to our understanding of the numerous physical and chemical processes mediated by atomic rearrangements, such as conformational changes and chemical reactions, and the thermodynamic and kinetic feasibility of these processes. Stochastic electronic structure theories, e.g., Quantum Monte Carlo (QMC) methods, enable highly accurate total energy calculations that in principle can be used to construct the PES. However, their stochastic nature poses a challenge to the computation and use of forces and Hessians, which are typically required in algorithms for minimum-energy pathway (MEP) and transition state (TS) identification, such as the nudged elastic band (NEB) algorithm and its climbing image formulation. Here, we present strategies that utilize the surrogate Hessian line-search method, previously developed for QMC structural optimization, to efficiently identify MEP and TS structures without requiring force calculations at the level of the stochastic electronic structure theory. By modifying the surrogate Hessian algorithm to operate in path-orthogonal subspaces and at saddle points, we show that it is possible to identify MEPs and TSs by using a force-free QMC approach. We demonstrate these strategies via two examples, the inversion of the ammonia (NH 3 ) molecule and the nucleophilic substitution (S N 2) reaction F − + CH 3 F → FCH 3 + F − . We validate our results using Density Functional Theory (DFT)-and Coupled Cluster (CCSD, CCSD(T))-based NEB calculations. We then introduce a hybrid DFT-QMC approach to compute thermodynamic and kinetic quantities, free energy differences, rate constants, and equilibrium constants that incorporates stochastically optimized structures and their energies, and show that this scheme improves upon DFT accuracy. Our methods generalize straightforwardly to other systems and other high-accuracy theories that similarly face challenges computing energy gradients, paving the way for highly accurate PES mapping, transition state determination, and thermodynamic and kinetic calculations at significantly reduced computational expense.

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A Quantum Monte Carlo Study of the Structural, Energetic, and Magnetic Properties of Two-Dimensional H and T Phase VSe₂

Cited by 5 publications

References 45 publications

Predictions of delafossite-hosted honeycomb and kagome phases

Predictions of delafossite-hosted honeycomb and kagome phases

Accelerated Data-Driven Discovery and Screening of Two-Dimensional Magnets Using Graph Neural Networks

Force-Free Identification of Minimum-Energy Pathways and Transition States for Stochastic Electronic Structure Theories

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A Quantum Monte Carlo Study of the Structural, Energetic, and Magnetic Properties of Two-Dimensional H and T Phase VSe2

Cited by 5 publications

References 45 publications

Predictions of delafossite-hosted honeycomb and kagome phases

Predictions of delafossite-hosted honeycomb and kagome phases

Accelerated Data-Driven Discovery and Screening of Two-Dimensional Magnets Using Graph Neural Networks

Force-Free Identification of Minimum-Energy Pathways and Transition States for Stochastic Electronic Structure Theories

Contact Info

Product

Resources

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A Quantum Monte Carlo Study of the Structural, Energetic, and Magnetic Properties of Two-Dimensional H and T Phase VSe₂