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Your search keyword '"Seong, Maeng-Je"' showing total 202 results
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202 results on '"Seong, Maeng-Je"'

1. Interplay between magnetic and lattice excitations and emergent multiple phase transitions in MnPSe3-xSx

Author

Kumar, Deepu, Hoang, Nguyen The, Sim, Yumin, Choi, Youngsu, Raju, Kalaivanan, Ulaganathan, Rajesh Kumar, Sankar, Raman, Seong, Maeng-Je, and Choi, Kwang-Yong

Subjects
Condensed Matter - Materials Science
Abstract

The intricate interplay between spin and lattice degrees of freedom in two-dimensional magnetic materials plays a pivotal role in modifying their magnetic characteristics, engendering hybrid quasiparticles, and implementing functional devices. Herein, we present our comprehensive and in-depth investigations on magnetic and lattice excitations of MnPSe3-xSx (x = 0, 0.5, and 1.5) alloys, utilizing temperature- and polarization-dependent Raman scattering. Our experimental results reveal the occurrence of multiple phase transitions, evidenced by notable changes in phonon self-energy and the appearance or splitting of phonon modes. These emergent phases are tied to the development of long and short-range spin-spin correlations, as well as to spin reorientations or magnetic instabilities. Our analysis of two-magnon excitations as a function of temperature and composition showcases their hybridization with phonons whose degree weakens with increasing x. Moreover, the suppression of spin-dependent phonon intensity in chemically most-disordered MnPSe3-xSx (x = 1.5) suggests that chalcogen substitution offers a control knob of tuning spin and phonon dynamics by modulating concurrently superexchange pathways and a degree of trigonal distortions.

Published
2024

8. Optical Probe of Magnetic Ordering Structure and Spin‐Entangled Excitons in Mn‐Substituted NiPS3.

Author

Lee, Je‐Ho, Lee, Seungyeol, Choi, Youngsu, Gries, Lukas, Klingeler, Rüdiger, Raju, Kalaivanan, Ulaganathan, Rajesh Kumar, Sankar, Raman, Seong, Maeng‐Je, and Choi, Kwang‐Yong

Subjects
MAGNETIC structure, MAGNETIC measurements, MAGNETIC fields, MAGNETIC moments, QUANTUM entanglement
Abstract

In van der Waals magnets, the interplay between magneto‐excitonic coupling and optical phenomena opens avenues for directly probing magnetic ordering structures, manipulating excitonic properties through magnetic fields, and exploring quantum entanglement between electronic and magnetic states. Notably, NiPS3 stands out for its capacity to host spin‐entangled excitons, where the excitonic states are intricately tied with the material's spin configuration. Herein, it is experimentally showcased that the spin‐entangled excitons can be utilized for detecting the magnetic easy axis in Ni1‐xMnxPS3 (x = 0–0.1). The end members of this series exhibit distinct magnetic ordering patterns and easy axes: zigzag ordering with magnetic moments aligned along the a‐axis for NiPS3 versus Néel ordering with the out‐of‐plane easy axis for MnPS3. By combining angle‐resolved exciton photoluminescence with magnetic susceptibility measurements, it is observed that the magnetic easy axis rotates away from the local spin chain direction with increasing Mn content. Moreover, through a comprehensive thermal and substitution study, it is demonstrated that the energy and lifetime of spin‐entangled excitons are governed by two spin‐flip processes and are drastically influenced by disparate electronic states. These findings not only provide optical means to map out magnetic ordering structures but also offer insights into decoherence processes in spin‐exciton entangled states. [ABSTRACT FROM AUTHOR]

Published
2024
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9. An impermeable copper surface monolayer with high-temperature oxidation resistance

Author

Jeong, Se-Young, primary, Kim, Su Jae, additional, Lee, Yousil, additional, Kim, Young-Hoon, additional, Yang, Sang-Hyeok, additional, Kim, Seon, additional, Jung, Min-Hyoung, additional, Kim, Young-Min, additional, Lamichhane, Bipin, additional, Regmi, Binod, additional, Kim, Seong-Gon, additional, Jang, Jae Hyuck, additional, Jeong, Hu Young, additional, Seong, Maeng-Je, additional, and Choi, Hak Soo, additional

Published
2024
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19. Voltage control of magnetism in Fe3-xGeTe2/In2Se3 van der Waals ferromagnetic/ferroelectric heterostructures.

Author

Eom, Jaeun, Lee, In Hak, Kee, Jung Yun, Cho, Minhyun, Seo, Jeongdae, Suh, Hoyoung, Choi, Hyung-Jin, Sim, Yumin, Chen, Shuzhang, Chang, Hye Jung, Baek, Seung-Hyub, Petrovic, Cedomir, Ryu, Hyejin, Jang, Chaun, Kim, Young Duck, Yang, Chan-Ho, Seong, Maeng-Je, Lee, Jin Hong, Park, Se Young, and Choi, Jun Woo

Subjects
VOLTAGE control, MAGNETISM, MAGNETOELECTRIC effect, HETEROSTRUCTURES, FERROELECTRIC devices, PHOTOVOLTAIC effect
Abstract

We investigate the voltage control of magnetism in a van der Waals (vdW) heterostructure device consisting of two distinct vdW materials, the ferromagnetic Fe3-xGeTe2 and the ferroelectric In2Se3. It is observed that gate voltages applied to the Fe3-xGeTe2/In2Se3 heterostructure device modulate the magnetic properties of Fe3-xGeTe2 with significant decrease in coercive field for both positive and negative voltages. Raman spectroscopy on the heterostructure device shows voltage-dependent increase in the in-plane In2Se3 and Fe3-xGeTe2 lattice constants for both voltage polarities. Thus, the voltage-dependent decrease in the Fe3-xGeTe2 coercive field, regardless of the gate voltage polarity, can be attributed to the presence of in-plane tensile strain. This is supported by density functional theory calculations showing tensile-strain-induced reduction of the magnetocrystalline anisotropy, which in turn decreases the coercive field. Our results demonstrate an effective method to realize low-power voltage-controlled vdW spintronic devices utilizing the magnetoelectric effect in vdW ferromagnetic/ferroelectric heterostructures. The control of magnetism by electric field is an important goal for future development of low-power spintronics. Here, the authors demonstrate voltage control of magnetism in van der Waals ferromagnetic/ferroelectric heterostructure devices via the strain-mediated magnetoelectric effect. [ABSTRACT FROM AUTHOR]

Published
2023
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35. Selective Growth and Robust Valley Polarization of Bilayer 3R-MoS2

Author

Ullah, Farman, primary, Lee, Je-Ho, additional, Tahir, Zeeshan, additional, Samad, Abdus, additional, Le, Chinh Tam, additional, Kim, Jungcheol, additional, Kim, Donggyu, additional, Rashid, Mamoon Ur, additional, Lee, Sol, additional, Kim, Kwanpyo, additional, Cheong, Hyeonsik, additional, Jang, Joon I., additional, Seong, Maeng-Je, additional, and Kim, Yong Soo, additional

Published
2021
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36. Extrinsic Surface Magnetic Anisotropy Contribution in Pt/Y3Fe5O12Interface in Longitudinal Spin Seebeck Effect by Graphene Interlayer

Author

Lee, Won-Yong, primary, Park, No-Won, additional, Kang, Min-Sung, additional, Kim, Gil-Sung, additional, Yoon, Young-Gui, additional, Lee, Suheon, additional, Choi, Kwang-Yong, additional, Kim, Keun Soo, additional, Kim, Jin-Hyuk, additional, Seong, Maeng-Je, additional, Kikkawa, Takashi, additional, Saitoh, Eiji, additional, and Lee, Sang-Kwon, additional

Published
2021
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41. Highly Efficient Solar Steam Generation by Glassy Carbon Foam Coated with Two-Dimensional Metal Chalcogenides

Author

Tahir, Zeeshan, primary, Kim, Sungdo, additional, Ullah, Farman, additional, Lee, Sunghan, additional, Lee, Je-ho, additional, Park, No-Won, additional, Seong, Maeng-Je, additional, Lee, Sang-Kwon, additional, Ju, Tae-Seong, additional, Park, Sungkyun, additional, Bae, Jong-Seong, additional, Jang, Joon Ik, additional, and Kim, Yong Soo, additional

Published
2019
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43. Tuning of Thermoelectric Properties of MoSe2 Thin Films Under Helium Ion Irradiation.

Author

Kim, Hyuk Jin, Van Quang, Nguyen, Nguyen, Thi Huong, Kim, Sera, Lee, Yangjin, Lee, In Hak, Cho, Sunglae, Seong, Maeng-Je, Kim, Kwanpyo, and Chang, Young Jun

Subjects
THERMOELECTRIC materials, THIN films, HELIUM ions, SEEBECK coefficient, ELECTRIC conductivity, THERMAL conductivity
Abstract

Transition metal dichalcogenides have attracted renewed interest for use as thermoelectric materials owing to their tunable bandgap, moderate Seebeck coefficient, and low thermal conductivity. However, their thermoelectric parameters such as Seebeck coefficient, electrical conductivity, and thermal conductivity are interdependent, which is a drawback. Therefore, it is necessary to find a way to adjust one of these parameters without affecting the other parameters. In this study, we investigated the effect of helium ion irradiation on MoSe2 thin films with the objective of controlling the Seebeck coefficient and electrical conductivity. At the optimal irradiation dose of 1015 cm−2, we observed multiple enhancements of the power factor resulting from an increase in the electrical conductivity, with slight suppression of the Seebeck coefficient. Raman spectroscopy, X-ray diffraction, and transmission electron microscopy analyses revealed that irradiation-induced selenium vacancies played an important role in changing the thermoelectric properties of MoSe2 thin films. These results suggest that helium ion irradiation is a promising method to significantly improve the thermoelectric properties of two-dimensional transition metal dichalcogenides. Effect of He+ irradiation on thermoelectric properties of MoSe2 thin films. [ABSTRACT FROM AUTHOR]

Published
2022
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50. Interface-Induced Seebeck Effect in PtSe2/PtSe2van der Waals Homostructures

Author

Lee, Won-Yong, Kang, Min-Sung, Kim, Gil-Sung, Choi, Jae Won, Park, No-Won, Sim, Yumin, Kim, Yun-Ho, Seong, Maeng-Je, Yoon, Young-Gui, Saitoh, Eiji, and Lee, Sang-Kwon

Abstract

The Seebeck effect refers to the production of an electric voltage when different temperatures are applied on a conductor, and the corresponding voltage-production efficiency is represented by the Seebeck coefficient. We report a Seebeck effect: thermal generation of driving voltage from the heat flowing in a thin PtSe2/PtSe2van der Waals homostructure at the interface. We refer to the effect as the interface-induced Seebeck effect. By exploiting this effect by directly attaching multilayered PtSe2over high-resistance PtSe2thin films as a hybridized single structure, we obtained the highly challenging in-plane Seebeck coefficient of the PtSe2films that exhibit extremely high resistances. This direct attachment further enhanced the in-plane thermal Seebeck coefficients of the PtSe2/PtSe2van der Waals homostructure on sapphire substrates. Consequently, we successfully enhanced the in-plane Seebeck coefficients for the PtSe2(10 nm)/PtSe2(2 nm) homostructure approximately 42% compared to that of a pure PtSe2(10 nm) layer at 300 K. These findings represent a significant achievement in understanding the interface-induced Seebeck effect and provide an effective strategy for promising large-area thermoelectric energy harvesting devices using two-dimensional transition metal dichalcogenide materials, which are ideal thermoelectric platforms with high figures of merit.

Published
2022
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