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Your search keyword '"Manna, Sukriti"' showing total 10 results
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10 results on '"Manna, Sukriti"'

1. Development of a Machine Learning Potential to Study Structure and Thermodynamics of Nickel Nanoclusters

Author

Banik, Suvo, Dutta, Partha Sarathi, Manna, Sukriti, and Sankaranarayanan, Subramanian KRS

Subjects
Condensed Matter - Materials Science
Abstract

Machine Learning (ML) potentials such as Gaussian Approximation Potential (GAP) have demonstrated impressive capabilities in mapping structure to properties across diverse systems. Here, we introduce a GAP model for low-dimensional Ni nanoclusters and demonstrate its flexibility and effectiveness in capturing the energetics, structural diversity and thermodynamic properties of Ni nanoclusters across a broad size range. Through a systematic approach encompassing model development, validation, and application, we evaluate the model's efficacy in representing energetics and configurational features in low-dimensional regimes, while also examining its extrapolative nature to vastly different spatiotemporal regimes. Our analysis and discussion shed light on the data quality required to effectively train such models. Trajectories from large scale MD simulations using the GAP model analyzed with data-driven models like Graph Neural Networks (GNN) reveal intriguing insights into the size-dependent phase behavior and thermo-mechanical stability characteristics of porous Ni nanoparticles. Overall, our work underscores the potential of ML models which coupled with data-driven approaches serve as versatile tools for studying low-dimensional systems and complex material dynamics.

Published
2024

6. Subnanometer Scale Mapping of Hydrogen Doping in Vanadium Dioxide

Author

Pofelski, Alexandre, primary, Jia, Haili, additional, Deng, Sunbin, additional, Yu, Haoming, additional, Park, Tae Joon, additional, Manna, Sukriti, additional, Chan, Maria K.Y., additional, Sankaranarayanan, Subramanian K. R. S., additional, Ramanathan, Shriram, additional, and Zhu, Yimei, additional

Published
2024
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7. Infrared Nanoimaging of Hydrogenated Perovskite Nickelate Memristive Devices

Author

Gamage, Sampath, primary, Manna, Sukriti, additional, Zajac, Marc, additional, Hancock, Steven, additional, Wang, Qi, additional, Singh, Sarabpreet, additional, Ghafariasl, Mahdi, additional, Yao, Kun, additional, Tiwald, Tom E., additional, Park, Tae Joon, additional, Landau, David P., additional, Wen, Haidan, additional, Sankaranarayanan, Subramanian K. R. S., additional, Darancet, Pierre, additional, Ramanathan, Shriram, additional, and Abate, Yohannes, additional

Published
2024
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9. Ab Initio-Based Bond Order Potential for Arsenene Polymorphs Developed via Hierarchical Reinforcement Learning

Author

Koneru, Aditya, Muhammed, Adil, Balasubramanian, Karthik, Sasikumar, Kiran, Manna, Sukriti, Chan, Henry, and Sankaranarayanan, Subramanian K. R. S.

Abstract

Arsenene, a less-explored two-dimensional material, holds the potential for applications in wearable electronics, memory devices, and quantum systems. This study introduces a bond-order potential model with Tersoff formalism, the ML-Tersoff, which leverages multireward hierarchical reinforcement learning (RL), trained on an ab initio data set. This data set covers a spectrum of properties for arsenene polymorphs, enhancing our understanding of its mechanical and thermal behaviors without the complexities of traditional models requiring multiple parameter sets. Our RL strategy utilizes decision trees coupled with a hierarchical reward strategy to accelerate convergence in high-dimensional continuous search spaces. Unlike the Stillinger–Weber approach, which demands separate formalisms for buckled and puckered forms, the ML-Tersoff model concurrently captures multiple properties of the two polymorphs by effectively representing the local environment, thereby avoiding the need for different atomic types. We apply the ML model to understand the mechanical and thermal properties of the arsenene polymorphs and nanostructures. We observe an inverse relationship between the critical strain and temperature in arsenene. Thermal conductivity calculations in nanosheets show good agreement with ab initio data, reflecting a decrease in thermal conductivity attributable to increased anharmonic effects at higher temperatures. We also apply the model to predict the thermal behavior of arsenene nanotubes.

Published
2024
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10. Machine Learning a Simple Interpretable Short-Range Potential for Silica.

Author

Koneru A, Chan H, Manna S, Banik S, Molinero V, and Sankaranarayanan SKRS

Abstract

A wide array of models, spanning from computationally expensive ab initio methods to a spectrum of force-field approaches, have been developed and employed to probe silica polymorphs and understand growth processes and atomic-level dynamical transitions in silica. However, the quest for a model capable of making accurate predictions with high computational efficiency for various silica polymorphs is still ongoing. Recent developments in short-range machine-learned models, such as GAP and NNPScan, have shown promise in providing reasonable descriptions of silica, but their computational cost remains high compared to force fields such as BKS which are based on simple interpretable functional forms. Here, we build on the recent success of our reinforcement learning (RL) workflow to derive a new set of optimal parameters for a promising short-range BKS-based model proposed by Soules. We use RL to navigate the eight-dimensional parameter space of the Soules potential using an experimental training data set that includes both local and global structural features from approximately 21 experimentally realized silica polymorphs, including high density phases and porous zeolites. We compare the performance of our machine-learned ML-Soules model with other high quality models including our recent machine-learned parametrization of BKS (ML-BKS), a machine-learned potential (GAP), as well as predictions of ab initio calculations with the highly fidelity SCAN functional. The ML-Soules accurately captures the relative energetic ordering of various polymorphs as well as their structural features at a significantly reduced computational expense. The ML-Soules model also reasonably captures the structure, density, and elastic constants of quartz, as well as metastable silica polymorphs. We further discuss the limitations of the Soules functional form and propose potential enhancements, including the incorporation of additional three-body terms and/or the utilization of different short-ranged functional forms to achieve greater accuracy for both global and local features in the modeling of silica while retaining low computational cost.

Published
2024
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