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44 results on '"Jeong, Wonseok"'

1. Spectroscopy-Guided Discovery of Three-Dimensional Structures of Disordered Materials with Diffusion Models

Author

Kwon, Hyuna, Hsu, Tim, Sun, Wenyu, Jeong, Wonseok, Aydin, Fikret, Chapman, James, Chen, Xiao, Carbone, Matthew R., Lu, Deyu, Zhou, Fei, and Pham, Tuan Anh

Subjects
Condensed Matter - Materials Science, Computer Science - Machine Learning
Abstract

The ability to rapidly develop materials with desired properties has a transformative impact on a broad range of emerging technologies. In this work, we introduce a new framework based on the diffusion model, a recent generative machine learning method to predict 3D structures of disordered materials from a target property. For demonstration, we apply the model to identify the atomic structures of amorphous carbons ($a$-C) as a representative material system from the target X-ray absorption near edge structure (XANES) spectra--a common experimental technique to probe atomic structures of materials. We show that conditional generation guided by XANES spectra reproduces key features of the target structures. Furthermore, we show that our model can steer the generative process to tailor atomic arrangements for a specific XANES spectrum. Finally, our generative model exhibits a remarkable scale-agnostic property, thereby enabling generation of realistic, large-scale structures through learning from a small-scale dataset (i.e., with small unit cells). Our work represents a significant stride in bridging the gap between materials characterization and atomic structure determination; in addition, it can be leveraged for materials discovery in exploring various material properties as targeted.

Published
2023

4. TUTORING: Instruction-Grounded Conversational Agent for Language Learners

Author

Chae, Hyungjoo, Kim, Minjin, Kim, Chaehyeong, Jeong, Wonseok, Kim, Hyejoong, Lee, Junmyung, and Yeo, Jinyoung

Subjects
Computer Science - Artificial Intelligence, Computer Science - Computation and Language
Abstract

In this paper, we propose Tutoring bot, a generative chatbot trained on a large scale of tutor-student conversations for English-language learning. To mimic a human tutor's behavior in language education, the tutor bot leverages diverse educational instructions and grounds to each instruction as additional input context for the tutor response generation. As a single instruction generally involves multiple dialogue turns to give the student sufficient speaking practice, the tutor bot is required to monitor and capture when the current instruction should be kept or switched to the next instruction. For that, the tutor bot is learned to not only generate responses but also infer its teaching action and progress on the current conversation simultaneously by a multi-task learning scheme. Our Tutoring bot is deployed under a non-commercial use license at https://tutoringai.com.

Published
2023

5. E-beam-enhanced solid-state mechanical amorphization of alpha-quartz: Reducing deformation barrier via localized excess electrons as mobile anions

Author

Kang, Sung-Gyu, Jeong, Wonseok, Kim, Hwangsun, Paeng, Jeongin, Han, Seungwu, Han, Heung Nam, and Choi, In-Suk

Subjects
Condensed Matter - Materials Science
Abstract

Under hydrostatic pressure, alpha-quartz undergoes solid-state mechanical amorphization wherein the interpenetration of SiO4 tetrahedra occurs and the material loses crystallinity. This phase transformation requires a high hydrostatic pressure of 14 GPa because the repulsive forces resulting from the ionic nature of the Si-O bonds prevent the severe distortion of the atomic configuration. Herein, we experimentally and computationally demonstrate that e-beam irradiation changes the nature of the interatomic bonds in alpha-quartz and enhances the solid-state mechanical amorphization at nanoscale. Specifically, during in situ uniaxial compression, a larger permanent deformation occurs in alpha-quartz micropillars compressed during e-beam irradiation than in those without e-beam irradiation. Microstructural analysis reveals that the large permanent deformation under e-beam irradiation originates from the enhanced mechanical amorphization of alpha-quartz and the subsequent viscoplastic deformation of the amorphized region. Further, atomic-scale simulations suggest that the delocalized excess electrons introduced by e-beam irradiation move to highly distorted atomic configurations and alleviate the repulsive force, thus reducing the barrier to the solid-state mechanical amorphization. These findings deepen our understanding of electron-matter interactions and can be extended to new glass forming and processing technologies at nano- and microscale., Comment: 24 pages, 6 figures

Published
2022

6. Guidelines for the Regularization of Gammas in Batch Normalization for Deep Residual Networks

Author

Kim, Bum Jun, Choi, Hyeyeon, Jang, Hyeonah, Lee, Dong Gu, Jeong, Wonseok, and Kim, Sang Woo

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

L2 regularization for weights in neural networks is widely used as a standard training trick. However, L2 regularization for gamma, a trainable parameter of batch normalization, remains an undiscussed mystery and is applied in different ways depending on the library and practitioner. In this paper, we study whether L2 regularization for gamma is valid. To explore this issue, we consider two approaches: 1) variance control to make the residual network behave like identity mapping and 2) stable optimization through the improvement of effective learning rate. Through two analyses, we specify the desirable and undesirable gamma to apply L2 regularization and propose four guidelines for managing them. In several experiments, we observed the increase and decrease in performance caused by applying L2 regularization to gamma of four categories, which is consistent with our four guidelines. Our proposed guidelines were validated through various tasks and architectures, including variants of residual networks and transformers., Comment: 12 pages, 6 figures

Published
2022

7. Improved Robustness of Vision Transformer via PreLayerNorm in Patch Embedding

Author

Kim, Bum Jun, Choi, Hyeyeon, Jang, Hyeonah, Lee, Dong Gu, Jeong, Wonseok, and Kim, Sang Woo

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

Vision transformers (ViTs) have recently demonstrated state-of-the-art performance in a variety of vision tasks, replacing convolutional neural networks (CNNs). Meanwhile, since ViT has a different architecture than CNN, it may behave differently. To investigate the reliability of ViT, this paper studies the behavior and robustness of ViT. We compared the robustness of CNN and ViT by assuming various image corruptions that may appear in practical vision tasks. We confirmed that for most image transformations, ViT showed robustness comparable to CNN or more improved. However, for contrast enhancement, severe performance degradations were consistently observed in ViT. From a detailed analysis, we identified a potential problem: positional embedding in ViT's patch embedding could work improperly when the color scale changes. Here we claim the use of PreLayerNorm, a modified patch embedding structure to ensure scale-invariant behavior of ViT. ViT with PreLayerNorm showed improved robustness in various corruptions including contrast-varying environments., Comment: 7 pages, 8 figures. Work in Progress

Published
2021

8. Dead Pixel Test Using Effective Receptive Field

Author

Kim, Bum Jun, Choi, Hyeyeon, Jang, Hyeonah, Lee, Dong Gu, Jeong, Wonseok, and Kim, Sang Woo

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

Deep neural networks have been used in various fields, but their internal behavior is not well known. In this study, we discuss two counterintuitive behaviors of convolutional neural networks (CNNs). First, we evaluated the size of the receptive field. Previous studies have attempted to increase or control the size of the receptive field. However, we observed that the size of the receptive field does not describe the classification accuracy. The size of the receptive field would be inappropriate for representing superiority in performance because it reflects only depth or kernel size and does not reflect other factors such as width or cardinality. Second, using the effective receptive field, we examined the pixels contributing to the output. Intuitively, each pixel is expected to equally contribute to the final output. However, we found that there exist pixels in a partially dead state with little contribution to the output. We reveal that the reason for this lies in the architecture of CNN and discuss solutions to reduce the phenomenon. Interestingly, for general classification tasks, the existence of dead pixels improves the training of CNNs. However, in a task that captures small perturbation, dead pixels degrade the performance. Therefore, the existence of these dead pixels should be understood and considered in practical applications of CNN., Comment: 9 pages, 5 figures

Published
2021

9. Accelerated identification of equilibrium structures of multicomponent inorganic crystals using machine learning potentials

Author

Kang, Sungwoo, Jeong, Wonseok, Hong, Changho, Hwang, Seungwoo, Yoon, Youngchae, and Han, Seungwu

Subjects
Physics - Computational Physics, Condensed Matter - Materials Science
Abstract

The discovery of new multicomponent inorganic compounds can provide direct solutions to many scientific and engineering challenges, yet the vast size of the uncharted material space dwarfs current synthesis throughput. While the computational crystal structure prediction is expected to mitigate this frustration, the NP-hardness and steep costs of density functional theory (DFT) calculations prohibit material exploration at scale. Herein, we introduce SPINNER, a highly efficient and reliable structure-prediction framework based on exhaustive random searches and evolutionary algorithms, which is completely free from empiricism. Empowered by accurate neural network potentials, the program can navigate the configuration space faster than DFT by more than 10$^{2}$-fold. In blind tests on 60 ternary compositions diversely selected from the experimental database, SPINNER successfully identifies experimental (or theoretically more stable) phases for ~80% of materials within 5000 generations, entailing up to half a million structure evaluations for each composition. When benchmarked against previous data mining or DFT-based evolutionary predictions, SPINNER identifies more stable phases in the majority of cases. By developing a reliable and fast structure-prediction framework, this work opens the door to large-scale, unbounded computational exploration of undiscovered inorganic crystals., Comment: 3 figures

Published
2021
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10. Metadynamics sampling in atomic environment space for collecting training data for machine learning potentials

Author

Yoo, Dongsun, Jung, Jisu, Jeong, Wonseok, and Han, Seungwu

Subjects
Physics - Computational Physics
Abstract

The universal mathematical form of machine-learning potentials (MLPs) shifts the core of development of interatomic potentials to collecting proper training data. Ideally, the training set should encompass diverse local atomic environments but the conventional approach is prone to sampling similar configurations repeatedly, mainly due to the Boltzmann statistics. As such, practitioners handpick a large pool of distinct configurations manually, stretching the development period significantly. Herein, we suggest a novel sampling method optimized for gathering diverse yet relevant configurations semi-automatically. This is achieved by applying the metadynamics with the descriptor for the local atomic environment as a collective variable. As a result, the simulation is automatically steered toward unvisited local environment space such that each atom experiences diverse chemical environments without redundancy. We apply the proposed metadynamics sampling to H:Pt(111), GeTe, and Si systems. Throughout the examples, a small number of metadynamics trajectories can provide reference structures necessary for training high-fidelity MLPs. By proposing a semi-automatic sampling method tuned for MLPs, the present work paves the way to wider applications of MLPs to many challenging applications.

Published
2020
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11. Training machine-learning potentials for crystal structure prediction using disordered structures

Author

Hong, Changho, Choi, Jeong Min, Jeong, Wonseok, Kang, Sungwoo, Ju, Suyeon, Lee, Kyeongpung, Jung, Jisu, Youn, Yong, and Han, Seungwu

Subjects
Physics - Computational Physics, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Materials Science
Abstract

Prediction of the stable crystal structure for multinary (ternary or higher) compounds with unexplored compositions demands fast and accurate evaluation of free energies in exploring the vast configurational space. The machine-learning potential such as the neural network potential (NNP) is poised to meet this requirement but a dearth of information on the crystal structure poses a challenge in choosing training sets. Herein we propose constructing the training set from densityfunctional-theory (DFT) based dynamical trajectories of liquid and quenched amorphous phases, which does not require any preceding information on material structures except for the chemical composition. To demonstrate suitability of the trained NNP in the crystal structure prediction, we compare NNP and DFT energies for Ba2AgSi3, Mg2SiO4, LiAlCl4, and InTe2O5F over experimental phases as well as low-energy crystal structures that are generated theoretically. For every material, we find strong correlations between DFT and NNP energies, ensuring that the NNPs can properly rank energies among low-energy crystalline structures. We also find that the evolutionary search using the NNPs can identify low-energy metastable phases more efficiently than the DFTbased approach. By proposing a way to developing reliable machine-learning potentials for the crystal structure prediction, this work will pave the way to identifying unexplored multinary phases efficiently., Comment: 8 pages, 5 figures

Published
2020
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13. Atomic energy mapping of neural network potential

Author

Yoo, Dongsun, Lee, Kyuhyun, Jeong, Wonseok, Watanabe, Satoshi, and Han, Seungwu

Subjects
Physics - Computational Physics, Condensed Matter - Materials Science, Physics - Chemical Physics
Abstract

We show that the intelligence of the machine-learning potential arises from its ability to infer the reference atomic-energy function from a given set of total energies. By utilizing invariant points in the feature space at which the atomic energy has a fixed reference value, we examine the atomic energy mapping of neural network potentials. Through a series of examples on Si, we demonstrate that the neural network potential is vulnerable to 'ad hoc' mapping in which the total energy appears to be trained accurately while the atomic energy mapping is incorrect in spite of its capability. We show that the energy mapping can be improved by choosing the training set carefully and monitoring the atomic energy at the invariant points during the training procedure.

Published
2019
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25. Harnessing Neural Networks for Elucidating X-ray Absorption Structure–Spectrum Relationships in Amorphous Carbon

Author

Kwon, Hyuna, primary, Sun, Wenyu, additional, Hsu, Tim, additional, Jeong, Wonseok, additional, Aydin, Fikret, additional, Sharma, Shubham, additional, Meng, Fanchen, additional, Carbone, Matthew R., additional, Chen, Xiao, additional, Lu, Deyu, additional, Wan, Liwen F., additional, Nielsen, Michael H., additional, and Pham, Tuan Anh, additional

Published
2023
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44. Reliability Characteristics of TANOS (TaN/AlO/SiN/Oxide/Si)NAND Flash Memory with Rounded Corner (RC) Structure

Author

Chang, Sung-Il, primary, Lee, Chang-Hyun, additional, Kang, Changseok, additional, Jeon, Sanghun, additional, Kim, Juhyung, additional, Choi, Byeong-In, additional, Park, Youngwoo, additional, Park, Jintaek, additional, Jeong, Wonseok, additional, You, Janghyun, additional, Choi, Bonghyun, additional, Sel, Jongsun, additional, Sim, Jae Sung, additional, Shin, Yoocheol, additional, Choi, Jungdal, additional, and Lee, Won-Seong, additional

Published
2008
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