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1. Incommensurate antiferromagnetic order in weakly frustrated two-dimensional van der Waals insulator CrPSe$_3$

Author

Mallesh, Baithi, Dang, Ngoc Toan, Tran, Tuan Anh, Luong, Dinh Hoa, Dhakal, Krishna P., Yoon, Duhee, Rutkauskas, Anton V., Kichanov, Sergei E., Zel, Ivan Y., Kim, Jeongyoung, Kozlenko, Denis P., Lee, Young Hee, and Duong, Dinh Loc

Subjects
Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons
Abstract

Although the magnetic order is suppressed by a strong magnetic frustration, it is maintained but appears in complex order forms such as a cycloid or spin density wave in weakly frustrated systems. Herein, we report a weakly magnetic-frustrated two-dimensional van der Waals material CrPSe$_3$. Polycrystalline CrPSe$_3$ was synthesized at an optimized temperature of 700$^\circ$C to avoid the formation of any secondary phases (e.g., Cr$_2$Se$_3$). The antiferromagnetic transition appeared at $T_N\sim 126$ K with a large Curie-Weiss temperature $T_{\rm CW} \sim -371$ via magnetic susceptibility measurements, indicating weak frustration in CrPSe$_3$ with a frustration factor $f (|T_{\rm CW}|/T_N) \sim 3$. Evidently, the formation of long-range incommensurate spin-density wave antiferromagnetic order with the propagation vector $k = (0, 0.04, 0)$ was revealed by neutron diffraction measurements at low temperatures (below 120K). The monoclinic crystal structure of C2/m symmetry is preserved over the studied temperature range down to 20K, as confirmed by Raman spectroscopy measurements. Our findings on the spin density wave antiferromagnetic order in two-dimensional (2D) magnetic materials, not previously observed in the MPX$_3$ family, are expected to enrich the physics of magnetism at the 2D limit, thereby opening opportunities for their practical applications in spintronics and quantum devices., Comment: 23 pages, 4 figures, 2 tables

Published
2022

2. Observation of strange metal in hole-doped valley-spin insulator

Author

Nguyen, Tuan Dung, Mallesh, Baithi, Kim, Seon Je, Bouzid, Houcine, Cho, Byeongwook, Le, Xuan Phu, Ngo, Tien Dat, Yoo, Won Jong, Kim, Young-Min, Duong, Dinh Loc, and Lee, Young Hee

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

Temperature-linear resistance at low temperatures in strange metals is an exotic characteristic of strong correlation systems, as observed in high-TC superconducting cuprates, heavy fermions, Fe-based superconductors, ruthenates, and twisted bilayer graphene. Here, we introduce a hole-doped valley-spin insulator, V-doped WSe2, with hole pockets in the valence band. The strange metal characteristic was observed in VxW1-xSe2 at a critical carrier concentration of 9.5 x 10^20 cm-3 from 150 K to 1.8 K. The unsaturated magnetoresistance is almost linearly proportional to the magnetic field. Using the ansatz R(H,T) - R(0,0) ~ [(alpha.k.T)^2+(gamma.mu.B)^2]^1/2, the gamma/alpha ratio is estimated approximately to 4, distinct from that for the quasiparticles of LSCO, BaFe2(As1-xPx)2 (gamma/alpha=1) and bosons of YBCO (gamma/alpha=2). Our observation opens up the possible routes that induce strong correlation and superconductivity in two-dimensional materials with strong spin-orbit coupling., Comment: 8 pages, 4 figures + Supplemental Material

Published
2022

4. Predicting spin orbit coupling effect in the electronic and magnetic properties of cobalt (Co) doped WSe2 monolayer

Author

Thapa, Dinesh, Duong, Dinh Loc, Yun, Seok Joon, KC, Santosh, Lee, Young Hee, and Kim, Seong-Gon

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

The electronic and magnetic properties of cobalt (Co) doped monolayer (ML) tungsten diselenide (WSe2) are investigated using the density functional theory with the on-site Hubbard potential correction (DFT+U) for the localized d orbitals of Co atom taking into account the spin orbit coupling (SOC) interaction. The results show that the substitution of Co at the W sites of ML WSe2 is energetically favorable under Se rich environment. We noticed that the Hund's exchange splitting (\Delta H_{ex}) is dominant over the crystal field splitting (\Delta_{cf}). The induced magnetic moment due to the Co-doped defect is ~3.00 \mu_B per Co atom. The magnetic interaction between two Co atoms at the nearest neighbor separation depends mainly on the concentration of the impurity atoms. The calculated value of curie temperature (TC) is increasing with increasing impurity concentration satisfying the Zener model. Based on the results, it can be proposed that the Co-doped WSe2 monolayer is potential candidate to apply in spintronics, optoelectronics, and magnetic storage devices.

Published
2021

5. Spin-orbit torque: Moving towards two-dimensional van der Waals heterostructures

Author

Sahoo, R. C., Duong, Dinh Loc, Yoon, Jungbum, Hai, Pham Nam, and Lee, Young Hee

Subjects
Physics - Applied Physics
Abstract

The manipulation of magnetic properties using either electrical currents or gate bias is the key of future high-impact nanospintronics applications such as spin-valve read heads, non-volatile logic, and random-access memories. The current technology for magnetic switching with spin-transfer torque requires high current densities, whereas gate-tunable magnetic materials such as ferromagnetic semiconductors and multiferroic materials are still far from practical applications. Recently, magnetic switching induced by pure spin currents using the spin Hall and Rashba effects in heavy metals, called spin-orbit torque (SOT), has emerged as a candidate for designing next-generation magnetic memory with low current densities. The recent discovery of topological materials and two-dimensional (2D) van der Waals (vdW) materials provides opportunities to explore versatile 3D-2D and 2D-2D heterostructures with interesting characteristics. In this review, we introduce the emerging approaches to realizing SOT nanodevices including techniques to evaluate the SOT efficiency as well as the opportunities and challenges of using 2D topological materials and vdW materials in such applications.

Published
2021

7. Light-controlled room temperature ferromagnetism in vanadium-doped tungsten diselenide semiconducting monolayers

Author

Jimenez, Valery Ortiz, Pham, Yen Thi Hai, Liu, Mingzu, Zhang, Fu, Kalappattil, Vijaysankar, Muchharla, Baleeswaraiah, Eggers, Tatiana, Duong, Dinh Loc, Terrones, Mauricio, and Phan, Manh-Huong

Subjects
Condensed Matter - Materials Science
Abstract

Atomically thin transition metal dichalcogenide (TMD) semiconductors hold enormous potential for modern optoelectronic devices and quantum computing applications. By inducing long-range ferromagnetism (FM) in these semiconductors through the introduction of small amounts of a magnetic dopant, it is possible to extend their potential in emerging spintronic applications. Here, we demonstrate light-mediated, room temperature (RT) FM, in V-doped WS2 (V-WS2) monolayers. We probe this effect using the principle of magnetic LC resonance, which employs a soft ferromagnetic Co-based microwire coil driven near its resonance in the radio frequency (RF) regime. The combination of LC resonance with an extraordinary giant magneto-impedance effect, renders the coil highly sensitive to changes in the magnetic flux through its core. We then place the V-WS2 monolayer at the core of the coil where it is excited with a laser while its change in magnetic permeability is measured. Notably, the magnetic permeability of the monolayer is found to depend on the laser intensity, thus confirming light control of RT magnetism in this two-dimensional (2D) material. Guided by density functional calculations, we attribute this phenomenon to the presence of excess holes in the conduction and valence bands, as well as carriers trapped in the magnetic doping states, which in turn mediates the magnetization of the V-WS2 monolayer. These findings provide a unique route to exploit light-controlled ferromagnetism in low powered 2D spintronic devices capable of operating at RT.

Published
2020

8. Evidence of itinerant holes for long-range magnetic order in tungsten diselenide semiconductor with vanadium dopants

Author

Song, Bumsub, Yun, Seok Joon, Jiang, Jinbao, Beach, Kory, Choi, Wooseon, Kim, Young-Min, Terrones, Humberto, Song, Young Jae, Duong, Dinh Loc, and Lee, Young Hee

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

One primary concern in diluted magnetic semiconductors (DMSs) is how to establish a long-range magnetic order with a low magnetic doping concentration to maintain the gate tunability of the host semiconductor, as well as to increase Curie temperature. Two-dimensional van der Waals semiconductors have been recently investigated to demonstrate the magnetic order in DMSs; however, a comprehensive understanding of the mechanism responsible for the gate-tunable long-range magnetic order in DMSs has not been achieved yet. Here, we introduce a monolayer tungsten diselenide (WSe2) semiconductor with V dopants to demonstrate the long-range magnetic order through itinerant spin-polarized holes. The V atoms are sparsely located in the host lattice by substituting W atoms, which is confirmed by scanning tunneling microscopy and high-resolution transmission electron microscopy. The V impurity states and the valence band edge states are overlapped, which is congruent with density functional theory calculations. The field-effect transistor characteristics reveal the itinerant holes within the hybridized band; this clearly resembles the Zener model. Our study gives an insight into the mechanism of the long-range magnetic order in V-doped WSe2, which can also be used for other magnetically doped semiconducting transition metal dichalcogenides., Comment: 19 pages, 4 figures

Published
2020
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9. Gate modulation of the long-range magnetic order in a vanadium-doped WSe2 semiconductor

Author

Duong, Dinh Loc, Kim, Seong-Gon, and Lee, Young Hee

Subjects
Condensed Matter - Materials Science
Abstract

We demonstrate the gate-tunability of the long-range magnetic order in a p-type V-doped WSe2 monolayer using ab initio calculations. We found that at a low V-doping concentration limit, the long-range ferromagnetic order is enhanced by increasing the hole density. In contrast, the short-range antiferromagnetic order is manifested at a high electron density by full compensation of the p-type V doping concentration. The hole-mediated long-range magnetic exchange is ~70 meV, thus strongly suggesting the ferromagnetism in V-doped WSe2 at room temperature. Our findings on strong coupling between charge and spin order in V-doped WSe2 provide plenty of room for multifunctional gate-tunable spintronics., Comment: 13 pages, 4 figures, 1 table

Published
2020
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12. Room-temperature ferromagnetism in monolayer WSe2 semiconductor via vanadium dopant

Author

Yun, Seok Joon, Duong, Dinh Loc, Doan, Manh-Ha, Singh, Kirandeep, Phan, Thanh Luan, Choi, Wooseon, Kim, Young-Min, and Lee, Young Hee

Subjects
Condensed Matter - Materials Science
Abstract

Diluted magnetic semiconductors including Mn-doped GaAs are attractive for gate-controlled spintronics but Curie transition at room temperature with long-range ferromagnetic order is still debatable to date. Here, we report the room-temperature ferromagnetic domains with long-range order in semiconducting V-doped WSe2 monolayer synthesized by chemical vapor deposition. Ferromagnetic order is manifested using magnetic force microscopy up to 360K, while retaining high on/off current ratio of ~105 at 0.1% V-doping concentration. The V-substitution to W sites keep a V-V separation distance of 5 nm without V-V aggregation, scrutinized by high-resolution scanning transmission-electron microscopy, which implies the possibility of the Ruderman-Kittel-Kasuya-Yoshida interaction (or Zener model) by establishing the long-range ferromagnetic order in V-doped WSe2 monolayer through free hole carriers. More importantly, the ferromagnetic order is clearly modulated by applying a back gate. Our findings open new opportunities for using two-dimensional transition metal dichalcogenides for future spintronics., Comment: 16 pages, 4 figures

Published
2018
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14. Ab initio computation of the transition temperature of the charge density wave transition in TiSe2

Author

Duong, Dinh Loc, Burghard, Marko, and Schoen, J. Christian

Subjects
Condensed Matter - Materials Science
Abstract

We present a density functional perturbation theory approach to estimate the transition temperature of the charge density wave transition of TiSe2. The softening of the phonon mode at the L-point where in TiSe2 a giant Kohn anomaly occurs, and the energy difference between the normal and distorted phase are analyzed. Both features are studied as function of the electronic temperature, which corresponds to the Fermi-Dirac distribution smearing value in the calculation. The transition temperature is found to be 500 K and 600 K by phonon and energy analysis, respectively, in reasonable agreement with the experimental value of 200 K., Comment: 18 pages, 9 figures, 1 table

Published
2015

15. Charge Transport in Polycrystalline Graphene: Challenges and Opportunities

Author

Cummings, Aron W., Duong, Dinh Loc, Nguyen, Van Luan, Van Tuan, Dinh, Kotakoski, Jani, Varga, Jose Eduardo Barrios, Lee, Young Hee, and Roche, Stephan

Subjects
Condensed Matter - Materials Science
Abstract

Graphene has attracted significant interest both for exploring fundamental science and for a wide range of technological applications. Chemical vapor deposition (CVD) is currently the only working approach to grow graphene at wafer scale, which is required for industrial applications. Unfortunately, CVD graphene is intrinsically polycrystalline, with pristine graphene grains stitched together by disordered grain boundaries, which can be either a blessing or a curse. On the one hand, grain boundaries are expected to degrade the electrical and mechanical properties of polycrystalline graphene, rendering the material undesirable for many applications. On the other hand, they exhibit an increased chemical reactivity, suggesting their potential application to sensing or as templates for synthesis of one-dimensional materials. Therefore, it is important to gain a deeper understanding of the structure and properties of graphene grain boundaries. Here, we review experimental progress on identification and electrical and chemical characterization of graphene grain boundaries. We use numerical simulations and transport measurements to demonstrate that electrical properties and chemical modification of graphene grain boundaries are strongly correlated. This not only provides guidelines for the improvement of graphene devices, but also opens a new research area of engineering graphene grain boundaries for highly sensitive electrobiochemical devices.

Published
2015
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17. Transition Metal Dichalcogenides: Making Atomic‐Level Magnetism Tunable with Light at Room Temperature

Author

Ortiz Jimenez, Valery, primary, Pham, Yen Thi Hai, additional, Zhou, Da, additional, Liu, Mingzu, additional, Nugera, Florence Ann, additional, Kalappattil, Vijaysankar, additional, Eggers, Tatiana, additional, Hoang, Khang, additional, Duong, Dinh Loc, additional, Terrones, Mauricio, additional, Rodriguez Gutiérrez, Humberto, additional, and Phan, Manh‐Huong, additional

Published
2023
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21. Transition Metal Dichalcogenides: Making Atomic‐Level Magnetism Tunable with Light at Room Temperature.

Author

Ortiz Jimenez, Valery, Pham, Yen Thi Hai, Zhou, Da, Liu, Mingzu, Nugera, Florence Ann, Kalappattil, Vijaysankar, Eggers, Tatiana, Hoang, Khang, Duong, Dinh Loc, Terrones, Mauricio, Rodriguez Gutiérrez, Humberto, and Phan, Manh‐Huong

Subjects
TRANSITION metals, MAGNETISM, MAGNETIC semiconductors, MAGNETIC traps, DENSITY functional theory, CHROMIUM isotopes, CHARGE transfer, GALLIUM antimonide
Abstract

The capacity to manipulate magnetization in 2D dilute magnetic semiconductors (2D‐DMSs) using light, specifically in magnetically doped transition metal dichalcogenide (TMD) monolayers (M‐doped TX2, where M = V, Fe, and Cr; T = W, Mo; X = S, Se, and Te), may lead to innovative applications in spintronics, spin‐caloritronics, valleytronics, and quantum computation. This Perspective paper explores the mediation of magnetization by light under ambient conditions in 2D‐TMD DMSs and heterostructures. By combining magneto‐LC resonance (MLCR) experiments with density functional theory (DFT) calculations, we show that the magnetization can be enhanced using light in V‐doped TMD monolayers (e.g., V‐WS2, V‐WSe2). This phenomenon is attributed to excess holes in the conduction and valence bands, and carriers trapped in magnetic doping states, mediating the magnetization of the semiconducting layer. In 2D‐TMD heterostructures (VSe2/WS2, VSe2/MoS2), the significance of proximity, charge‐transfer, and confinement effects in amplifying light‐mediated magnetism is demonstrated. We attributed this to photon absorption at the TMD layer that generates electron–hole pairs mediating the magnetization of the heterostructure. These findings will encourage further research in the field of 2D magnetism and establish a novel design of 2D‐TMDs and heterostructures with optically tunable magnetic functionalities, paving the way for next‐generation magneto‐optic nanodevices. [ABSTRACT FROM AUTHOR]

Published
2024
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22. Anomalous Temperature and Polarization Dependences of Photoluminescence of Metal‐Organic Chemical Vapor Deposition‐Grown GeSe2

Author

Lee, Eunji, primary, Dhakal, Krishna Prasad, additional, Song, Hwayoung, additional, Choi, Heenang, additional, Chung, Taek‐Mo, additional, Oh, Saeyoung, additional, Jeong, Hu Young, additional, Marmolejo‐Tejada, Juan M., additional, Mosquera, Martín A., additional, Duong, Dinh Loc, additional, Kang, Kibum, additional, and Kim, Jeongyong, additional

Published
2023
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23. Incommensurate Antiferromagnetic Order in Weakly Frustrated Two-Dimensional van der Waals Insulator CrPSe3

Author

Baithi, Mallesh, primary, Dang, Ngoc Toan, additional, Tran, Tuan Anh, additional, Fix, J. Pierce, additional, Luong, Dinh Hoa, additional, Dhakal, Krishna P., additional, Yoon, Duhee, additional, Rutkauskas, Anton V., additional, Kichanov, Sergei E., additional, Zel, Ivan Y., additional, Kim, Jeongyong, additional, Borys, Nicholas J., additional, Kozlenko, Denis P., additional, Lee, Young Hee, additional, and Duong, Dinh Loc, additional

Published
2023
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24. Anomalous Temperature and Polarization Dependences of Photoluminescence of Metal‐Organic Chemical Vapor Deposition‐Grown GeSe2.

Author

Lee, Eunji, Dhakal, Krishna Prasad, Song, Hwayoung, Choi, Heenang, Chung, Taek‐Mo, Oh, Saeyoung, Jeong, Hu Young, Marmolejo‐Tejada, Juan M., Mosquera, Martín A., Duong, Dinh Loc, Kang, Kibum, and Kim, Jeongyong

Subjects
PHOTOLUMINESCENCE, CHEMICAL vapor deposition, DENSITY functional theory, VAPORS, OPTICAL properties
Abstract

Germanium diselenide (GeSe2) is a 2D semiconductor with air stability, a wide bandgap, and anisotropic optical properties. The absorption and photoluminescence (PL) of single‐crystalline 2D GeSe2 grown by metal‐organic chemical vapor deposition and their dependence on temperature and polarization are studied. The PL spectra exhibit peaks at 2.5 eV (peak A) and 1.8 eV (peak B); peak A displays a strongly polarized emission along the short axis of the crystal, and peak B displays a weak polarization perpendicular to that of peak A. With increasing temperature, peak B shows anomalous behaviors, i.e., an increasing PL energy and intensity. The excitation energy‐dependent PL, time‐resolved PL, and density functional theory calculations suggest that peak A corresponds to the band‐edge transition, whereas peak B originates from the inter‐band mid‐gap states caused by selenium vacancies passivated by oxygen atoms. The comprehensive study on the PL of single‐crystalline GeSe2 sheds light on the origins of light emission in terms of the band structure of anisotropic GeSe2, making it beneficial for the corresponding optoelectronic applications. [ABSTRACT FROM AUTHOR]

Published
2024
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26. High Pressure‐Driven Magnetic Disorder and Structural Transformation in Fe3GeTe2: Emergence of a Magnetic Quantum Critical Point

Author

Dang, Ngoc‐Toan, primary, Kozlenko, Denis P., additional, Lis, Olga N., additional, Kichanov, Sergey E., additional, Lukin, Yevgenii V., additional, Golosova, Natalia O., additional, Savenko, Boris N., additional, Duong, Dinh‐Loc, additional, Phan, The‐Long, additional, Tran, Tuan‐Anh, additional, and Phan, Manh‐Huong, additional

Published
2023
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29. High Pressure‐Driven Magnetic Disorder and Structural Transformation in Fe3GeTe2: Emergence of a Magnetic Quantum Critical Point.

Author

Dang, Ngoc‐Toan, Kozlenko, Denis P., Lis, Olga N., Kichanov, Sergey E., Lukin, Yevgenii V., Golosova, Natalia O., Savenko, Boris N., Duong, Dinh‐Loc, Phan, The‐Long, Tran, Tuan‐Anh, and Phan, Manh‐Huong

Subjects
MAGNETIC properties, MAGNETISM, PHASE transitions, CURIE temperature, DENSITY functional theory, X-ray powder diffraction
Abstract

Among the recently discovered 2D intrinsic van der Waals (vdW) magnets, Fe3GeTe2 (FGT) has emerged as a strong candidate for spintronics applications, due to its high Curie temperature (130 – 220 K) and magnetic tunability in response to external stimuli (electrical field, light, strain). Theory predicts that the magnetism of FGT can be significantly modulated by an external strain. However, experimental evidence is needed to validate this prediction and understand the underlying mechanism of strain‐mediated vdW magnetism in this system. Here, the effects of pressure (0 – 20 GPa) are elucidated on the magnetic and structural properties of Fe3GeTe2 by means of synchrotron Mössbauer source spectroscopy, X‐ray powder diffraction and Raman spectroscopy over a wide temperature range of 10 – 290 K. A strong suppression of ferromagnetic ordering is observed with increasing pressure, and a paramagnetic ground state emerges when pressure exceeds a critical value, PPM ≈ 15 GPa. The anomalous pressure dependence of structural parameters and vibrational modes is observed at PC ≈ 7 GPa and attributed to an isostructural phase transformation. Density functional theory calculations complement these experimental findings. This study highlights pressure as a driving force for magnetic quantum criticality in layered vdW magnetic systems. [ABSTRACT FROM AUTHOR]

Published
2023
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31. Escalating Ferromagnetic Order via Se‐Vacancies Near Vanadium in WSe 2 Monolayers

Author

Yun, Seok Joon, primary, Cho, Byeong Wook, additional, Dinesh, Thapa, additional, Yang, Dae Hee, additional, Kim, Yong In, additional, Jin, Jeong Won, additional, Yang, Sang‐Hyeok, additional, Nguyen, Tuan Dung, additional, Kim, Young‐Min, additional, Kim, Ki Kang, additional, Duong, Dinh Loc, additional, Kim, Seong‐Gon, additional, and Lee, Young Hee, additional

Published
2022
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33. Spin-Selective Hole–Exciton Coupling in a V-Doped WSe2 Ferromagnetic Semiconductor at Room Temperature

Author

Nguyen, Lan-Anh T., primary, Dhakal, Krishna P., additional, Lee, Yuhan, additional, Choi, Wooseon, additional, Nguyen, Tuan Dung, additional, Hong, Chengyun, additional, Luong, Dinh Hoa, additional, Kim, Young-Min, additional, Kim, Jeongyong, additional, Lee, Myeongwon, additional, Choi, Taeyoung, additional, Heinrich, Andreas J., additional, Kim, Ji-Hee, additional, Lee, Donghun, additional, Duong, Dinh Loc, additional, and Lee, Young Hee, additional

Published
2021
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35. CNT-molecule-CNT (1D-0D-1D) van der Waals integration ferroelectric memory with 1-nm2 junction area.

Author

Phan, Thanh Luan, Seo, Sohyeon, Cho, Yunhee, An Vu, Quoc, Lee, Young Hee, Duong, Dinh Loc, Lee, Hyoyoung, and Yu, Woo Jong

Subjects
FERROELECTRIC polymers, MOLECULAR electronics, CARBON nanotubes, MEMORY, DIPOLE moments
Abstract

The device's integration of molecular electronics is limited regarding the large-scale fabrication of gap electrodes on a molecular scale. The van der Waals integration (vdWI) of a vertically aligned molecular layer (0D) with 2D or 3D electrodes indicates the possibility of device's integration; however, the active junction area of 0D-2D and 0D-3D vdWIs remains at a microscale size. Here, we introduce the robust fabrication of a vertical 1D-0D-1D vdWI device with the ultra-small junction area of 1 nm2 achieved by cross-stacking top carbon nanotubes (CNTs) on molecularly assembled bottom CNTs. 1D-0D-1D vdWI memories are demonstrated through ferroelectric switching of azobenzene molecules owing to the cis-trans transformation combined with the permanent dipole moment of the end-tail -CF3 group. In this work, our 1D-0D-1D vdWI memory exhibits a retention performance above 2000 s, over 300 cycles with an on/off ratio of approximately 105 and record current density (3.4 × 108 A/cm2), which is 100 times higher than previous study through the smallest junction area achieved in a vdWI. The simple stacking of aligned CNTs (4 × 4) allows integration of memory arrays (16 junctions) with high device operational yield (100%), offering integration guidelines for future molecular electronics. The van der Waals integration of molecular layer (0D) with 2D or 3D electrodes is limited at microscale junction. Here, the authors introduce 1D-0D-1D vdWI memory with 1 nm2 junction achieved by cross-stacking t-CNT on molecularly assembled b-CNT. [ABSTRACT FROM AUTHOR]

Published
2022
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37. Light‐Controlled Room Temperature Ferromagnetism in Vanadium‐Doped Tungsten Disulfide Semiconducting Monolayers

Author

Ortiz Jimenez, Valery, primary, Pham, Yen Thi Hai, additional, Liu, Mingzu, additional, Zhang, Fu, additional, Yu, Zhuohang, additional, Kalappattil, Vijaysankar, additional, Muchharla, Baleeswaraiah, additional, Eggers, Tatiana, additional, Duong, Dinh Loc, additional, Terrones, Mauricio, additional, and Phan, Manh‐Huong, additional

Published
2021
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38. Probing graphene grain boundaries with optical microscopy

Author

Duong, Dinh Loc, Han, Gang Hee, Lee, Seung Mi, Gunes, Fethullah, Kim, Eun Sung, Kim, Sung Tae, Kim, Heetae, Ta, Quang Huy, So, Kang Pyo, Yoon, Seok Jun, Chae, Seung Jin, Jo, Young Woo, Park, Min Ho, Chae, Sang Hoon, Lim, Seong Chu, Choi, Jae Young, and Lee, Young Hee

Subjects
Microspectroscopy -- Research, Grain boundaries -- Research, Graphene -- Research, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

Grain boundaries in graphene are formed by the joining of islands during the initial growth stage, and these boundaries govern transport properties and related device performance (1,2). Although information on [...]

Published
2012
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39. Evidence of itinerant holes for long-range magnetic order in the tungsten diselenide semiconductor with vanadium dopants

Author

Song, Bumsub, primary, Yun, Seok Joon, additional, Jiang, Jinbao, additional, Avila, José, additional, Beach, Kory, additional, Choi, Wooseon, additional, Kim, Young-Min, additional, Yoon, Duhee, additional, Terrones, Humberto, additional, Song, Young Jae, additional, Asensio, Maria C., additional, Duong, Dinh Loc, additional, and Lee, Young Hee, additional

Published
2021
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42. Light-emitting Ti2N (MXene) quantum dots: synthesis, characterization and theoretical calculations.

Author

Sharbirin, Anir S., Roy, Shrawan, Tran, Trang Thu, Akhtar, Sophia, Singh, Jaspal, Duong, Dinh Loc, and Kim, Jeongyong

Abstract

MXene-based quantum dots (MQDs), which are obtained by fragmenting MXenes into a nanometer scale, can display photoluminescence (PL), suggesting light-emitting applications for bandgap-less MXenes. However, despite the diverse possible formations of MXene components, only carbide MXene-based MQDs have been reported to emit light. In this study, we synthesized water-soluble MQDs with an average diameter of 3.14 nm using the titanium nitride (Ti2N) MXene. Ti2N MQDs exhibited efficient PL, with a maximum quantum yield of 7.5%, upon light absorption over the deep UV wavelength range of 400–230 nm. The density functional theory calculations and PL excitation measurements identified a bandgap of 3.8 eV and the existence of an unfulfilled band (E1) between the occupied low-energy (E0) and unoccupied high-energy (E2) bands, which induces strong absorption in deep UV energy originating from the E0–E2 transition. Light-emitting nitride MQDs expand and facilitate the UV optoelectronic applications of MQDs. [ABSTRACT FROM AUTHOR]

Published
2022
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44. Carrier transport mechanisms of reactively direct current magnetron sputtered tungsten oxide/n-type crystalline silicon heterojunction

Author

Dao, Vinh-Ai, primary, Trinh, Thanh Thuy, additional, Kim, Sangho, additional, Van Ngoc, Le, additional, Viet, Truong Doan, additional, Thanh Giang, Ngo Thi, additional, Duong, Dinh Loc, additional, Thanh Nguyen, Huong Thi, additional, Nam, Nguyen Dang, additional, Yi, Junsin, additional, and Kim, Joondong, additional

Published
2020
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