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1. New applications of Bayesian optimization based on element mapping to design high-capacity NASICON-type cathode of sodium-ion battery

Author

Park, Sanghyeon, Shim, Yoonsu, Hur, Junpyo, Jeon, Dongmin, Yuk, Jong Min, and Lee, Chan-Woo

Subjects
Condensed Matter - Materials Science
Abstract

Sodium-ion batteries are emerging as promising alternatives to lithium-ion batteries due to the abundance of sodium resources. Na3V2(PO4)2F3 (NVPF), a cathode material for sodium ion batteries, is attracting attention from its rate capability and high working voltage, but its low discharge capacity is one of the challenges. In this work, we aim to design a high-capacity NASICON-type cathode of sodium-ion battery by discovering element combinations that can stabilize the sodium excess phase in NVPFs. For the efficient discovery of element combinations, we propose a Bayesian optimization-based algorithm for chemical composition discovery. Specifically, we propose an element mapping technique to solve the limitation of Bayesian optimization in discovering chemical composition. By constructing a chemical space applicable to Bayesian optimization through element mapping and optimizing the constructed chemical space, we found optimal binary element combinations. This work not only offers insights into designing high-capacity cathodes, but also demonstrates the efficacy of the proposed algorithm in data-driven materials design., Comment: 20 pages, 5 figures

Published
2024

25. Convolutional Attention Networks for Multimodal Emotion Recognition from Speech and Text Data

Author

Lee, Chan Woo, Song, Kyu Ye, Jeong, Jihoon, and Choi, Woo Yong

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

Emotion recognition has become a popular topic of interest, especially in the field of human computer interaction. Previous works involve unimodal analysis of emotion, while recent efforts focus on multi-modal emotion recognition from vision and speech. In this paper, we propose a new method of learning about the hidden representations between just speech and text data using convolutional attention networks. Compared to the shallow model which employs simple concatenation of feature vectors, the proposed attention model performs much better in classifying emotion from speech and text data contained in the CMU-MOSEI dataset., Comment: Inaccurate scientific facts listed in document

Published
2018

26. AI4AI: Quantitative Methods for Classifying Host Species from Avian Influenza DNA Sequence

Author

Choi, Woo Yong, Song, Kyu Ye, and Lee, Chan Woo

Subjects
Quantitative Biology - Quantitative Methods, Computer Science - Learning, Statistics - Machine Learning
Abstract

Avian Influenza breakouts cause millions of dollars in damage each year globally, especially in Asian countries such as China and South Korea. The impact magnitude of a breakout directly correlates to time required to fully understand the influenza virus, particularly the interspecies pathogenicity. The procedure requires laboratory tests that require resources typically lacking in a breakout emergency. In this study, we propose new quantitative methods utilizing machine learning and deep learning to correctly classify host species given raw DNA sequence data of the influenza virus, and provide probabilities for each classification. The best deep learning models achieve top-1 classification accuracy of 47%, and top-3 classification accuracy of 82%, on a dataset of 11 host species classes.

Published
2018

27. Theoretical insights into selective electrochemical conversion of carbon dioxide

Author

Lee, Chan Woo, Kim, Chanyeon, and Min, Byoung Koun

Subjects
Affordable and Clean Energy, Electrocatalysis, CO2 reduction, Intermediate binding energy, Theoretical calculation
Abstract

Electrochemical conversion of CO2 and water to valuable chemicals and fuels is one of the promising alternatives to replace fossil fuel-based processes in realizing a carbon-neutral cycle. For practical application of such technologies, suppressing hydrogen evolution reaction and facilitating the activation of stable CO2 molecules still remain major challenges. Furthermore, high production selectivity toward high-value chemicals such as ethylene, ethanol, and even n-propanol is also not easy task to achieve. To settle these challenges, deeper understanding on underlying basis of reactions such as how intermediate binding affinities can be engineered at catalyst surfaces need to be discussed. In this review, we briefly outline recent strategies to modulate the binding energies of key intermediates for CO2 reduction reactions, based on theoretical insights from density functional theory calculation studies. In addition, important design principles of catalysts and electrolytes are also provided, which would contribute to the development of highly active catalysts for CO2 electroreduction.

Published
2019

31. Empowering Tri‐Functional Palladium's Catalytic Activity and Durability in Electrocatalytic Formic Acid Oxidation Reaction via Innovative Self‐Caging and Alloying Strategies.

Author

Lee, Chan‐Woo, Jung, Sun Young, Ryu, Jeong Ho, Jeon, Gyeom Seong, Gaur, Ashish, Cho, Min Su, Ali, Ghulam, Kim, Mingony, Chung, Kyung Yoon, Nayak, Arpan Kumar, Shin, Seoyoon, Kwon, Jiseok, Song, Taeseup, Shin, Tae Ho, and Han, HyukSu

Abstract

Direct formic acid fuel cells (DFAFCs) stand out for portable electronic devices owing to their ease of handling, abundant fuel availability, and high theoretical open circuit potential. However, the practical application of DFAFCs is hindered by the unsatisfactory performance of electrocatalysts for the sluggish anodic formic acid oxidation reaction (FAOR). Palladium (Pd) based nanomaterials have shown promise for FAOR due to their highly selective reaction mechanism, but maintaining high electrocatalytic durability remains challenging. In this study, a novel Pd‐based electrocatalyst (UiO‐Pd‐E) is reported with exceptional durability and activity for FAOR, which can be attributed to the Pd nanoparticles encapsulated within a carbon framework where concurrent chemical alloying of Pd and Zr occurs. Further, the UiO‐Pd‐E demonstrates noteworthy multifunctionality in various electrochemical reactions including electrocatalytic ethanol oxidation reaction (EOR) and oxygen reduction reaction (ORR) in addition to the FAOR, highlighting its practical potentials. [ABSTRACT FROM AUTHOR]

Published
2024
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32. A Machine Learning‐Enhanced Framework for the Accelerated Development of Spinel Oxide Electrocatalysts.

Author

Jeong, Incheol, Shim, Yoonsu, Oh, Seeun, Yuk, Jong Min, Roh, Ki‐Min, Lee, Chan‐Woo, and Lee, Kang Taek

Subjects
CLEAN energy, DENSITY functional theory, ELECTROCHEMICAL apparatus, CATALYTIC activity, FUEL cells
Abstract

The surging demand for sustainable energy has spurred intensive research into electrochemical conversion devices such as fuel cells, water splitting, and metal‐air batteries. The performance of oxygen electrocatalysts significantly impacts overall electrochemical efficiency. Recently, spinel oxides (AB2O4) have emerged as promising candidates; however, the scarcity of prior studies underscores the need for a thorough and comprehensive exploration. This study presents a computational framework that integrates machine learning and density functional theory (DFT) calculations for the systematic screening of 1240 spinel oxides. The data scarcity is addressed while enhancing prediction accuracy. Selected candidates are identified to outperform the benchmarking perovskite oxide. Additionally, their potential as mixed ionic and electronic conductors with a 3D network of ion diffusion pathways is highlighted. To further enhance the understanding and prediction of stability, catalytic activity, and reaction mechanisms, a new undemanding descriptor is introduced: the covalency indicator. This study offers a design principle for the development of high‐performance spinel oxide oxygen electrocatalysts. [ABSTRACT FROM AUTHOR]

Published
2024
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33. Data‐Driven Design of NASICON‐Type Electrodes Using Graph‐Based Neural Networks.

Author

Shim, Yoonsu, Jeong, Incheol, Hur, Junpyo, Jeen, Hyoungjeen, Myung, Seung‐Taek, Lee, Kang Taek, Hong, Seungbum, Yuk, Jong Min, and Lee, Chan‐Woo

Subjects
GRAPH neural networks, SUPERIONIC conductors, DENSITY functional theory, DOPING agents (Chemistry), TRANSITION metals
Abstract

Sodium superionic conductor (NASICON)‐type cathode materials are considered promising candidates for high‐performance sodium‐ion batteries (SIBs) because of the abundance and low cost of raw materials. However, NASICON‐type cathodes suffer from low capacities. This limitation can be addressed through the activation of sodium‐excess phases, which can enhance capacities up to theoretical values. Thus, this paper proposes the use of transition metal (TM)‐substituted Na3V2(PO4)2F3 (NVPF) to induce sodium‐excess phases. To identify suitable doping elements, an inverse design approach is developed, combining machine learning prediction and density functional theory (DFT) calculations. Graph‐based neural networks are used to predict two crucial properties, i. e., the structural stability and voltage level. Results indicate that the use of TM‐substituted NVPF materials leads to about 150 % capacity enhancement with reduced time and resource requirements compared with the direct design approach. Furthermore, DFT calculations confirm improvements in cyclability, electronic conductivity, and chemical stability. The proposed approach is expected to accelerate the discovery of superior materials for battery electrodes. [ABSTRACT FROM AUTHOR]

Published
2024
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45. Structural and Magnetic Reconstruction of Thermodynamically Stable CaMnO$_{3}$ (001) Surfaces

Author

Saldana-Greco, Diomedes, Lee, Chan-Woo, Yuan, Doyle, and Rappe, Andrew M.

Subjects
Condensed Matter - Materials Science
Abstract

The relative thermodynamic stability of surface reconstructions including vacancies, adatoms and additional layers on both CaO and MnO$_{2}$ terminations is calculated to predict the surface phase diagram of ($\sqrt{2}\times\sqrt{2}$)$\it{R}$45$^{\circ}$ CaMnO$_{3}$ (001) using $\it{ab}$ $\it{initio}$ thermodynamics. Stoichiometric and nonstoichiometric reconstructions are considered. A set of boundary conditions driven by the binary and ternary sub-phases from CaMnO$_{3}$ defines its bulk stability region, enclosing the stable surface reconstructions that can be in equilibrium with the bulk. Most of the surfaces take the magnetic ordering of the bulk ground state, G-type antiferromagnetic (AFM); however, some of the MnO$_{2}$-terminated surfaces are more stable when the surface layer spins flip. At 573 K, the stoichiometric CaO- and MnO$_{2}$-terminated surfaces are predicted to be thermodynamically stable, as well as a CaO-terminated surface reconstruction where half the Ca are replaced by Mn. The MnO$_{2}$-terminated surface reconstructions dominate the phase diagrams at high temperatures, including phases with MnO and MnO$_{2}$ adatoms per surface unit cell., Comment: 21 pages, 4 figures

Published
2015

46. Customized Electronic Modulations of Transition Metal Chalcogenide Electrodes Via Heterointerfacing/High‐Valence Doping Toward High‐Performance Water Electrolysis with Ampere‐Level Current Density.

Author

Qin, Xinyu, Yan, Bingyi, Chen, Tianyu, Teng, Zhishun, Cho, Deok Ki, Haryanto, Andi, Lim, Hyun Woo, Lee, Chan Woo, Piao, Yuanzhe, Xu, Lin, and Kim, Jin Young

Subjects
TRANSITION metal chalcogenides, ELECTRONIC modulation, HYDROGEN evolution reactions, WATER electrolysis, HETEROJUNCTIONS
Abstract

Electrochemical water splitting offers an advancing approach to producing highly pure hydrogen and oxygen, motivated by the prevalence of a low‐carbon economy and the goal of a sustainable future. The customized modulation of electronic structures enables the electrocatalyst to directionally promote hydrogen evolution reaction (HER) and oxygen evolution reaction (OER), which is a promising shortcut to overall water splitting (OWS). Herein, 3D homologous WSeS/CoSeS heterojunction nanoarrays (WSeS/CoSeS NAs) and W‐doped CoSeS nanoarrays (W‐CoSeS NAs) are investigated. Abundant heterointerfaces within WSeS/CoSeS NAs facilitate HER kinetics, boosting mass diffusivity, and increasing carrier separation and transfer process. High‐valence W6+ doping into CoSeS prevents phase separation and stabilizes Co sites by charge offset effect, leading to enhanced OER. Consequently, the WSeS/CoSeS NAs and W‐CoSeS NAs reach 10 mA cm−2 at an overpotential of 43.8 and 233.3 mV in 1.0 m KOH electrolyte for HER and OER, respectively. Moreover, when asymmetrically engaged as an electrolyzer, this configuration exhibits extraordinary electrocatalytic performances (cell voltage of 1.51 V at 10 mA cm−2) with satisfying stability and mechanical robustness (over 1000 h at 1000 mA cm−2). The modulation and manufacture of reaction‐property‐oriented materials are experimentally and theoretically validated potential, illuminating the light of inspiration for multiple applications. [ABSTRACT FROM AUTHOR]

Published
2024
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