Your search keyword '"An, Sung‐Kwan"' showing total 3,343 results

1. Dispersion kinks from electronic correlations in an unconventional iron-based superconductor

Author

Chang, Ming-Hua, Backes, Steffen, Lu, Donghui, Gauthier, Nicolas, Hashimoto, Makoto, Chen, Guan-Yu, Wen, Hai-Hu, Mo, Sung-Kwan, Valenti, Roser, and Pfau, Heike

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Superconductivity

Abstract

The attractive interaction in conventional BCS superconductors is provided by a bosonic mode. However, the pairing glue of most unconventional superconductors is unknown. The effect of electron-boson coupling is therefore extensively studied in these materials. A key signature are dispersion kinks that can be observed in the spectral function as abrupt changes in velocity and lifetime of quasiparticles. Here, we show the existence of two kinks in the unconventional iron-based superconductor RbFe$_2$As$_2$ using angle-resolved photoemission spectroscopy (ARPES) and dynamical mean field theory (DMFT). In addition, we observe the formation of a Hubbard band multiplet due to the combination of Coulomb interaction and Hund's rule coupling in this multiorbital systems. We demonstrate that the two dispersion kinks are a consequence of these strong many-body interactions. This interpretation is in line with a growing number of theoretical predictions for kinks in various general models of correlated materials. Our results provide a unifying link between iron-based superconductors and different classes of correlated, unconventional superconductors such as cuprates and heavy-fermion materials.

Published

2024

2. Novel Charge-Ordered States in 1T-IrTe2

Author

Hwang, Jinwoong and Mo, Sung-Kwan

Subjects

Physical Sciences, Condensed Matter Physics, Mathematical Sciences, General Physics, Mathematical sciences, Physical sciences

Abstract

1T-IrTe2 exhibits an intriguing series of charge-ordered states in both bulk and atomically thin layers. The charge orders in IrTe2 emerge with consecutive first-order structural transitions involving in-plane Ir–Ir dimerization and interlayer Te–Te depolymerization, resulting in stripe patterns with various periods. Upon chemical doping, 1T-IrTe2 can also be driven into a superconductor. Despite the intense research effort, a comprehensive understanding of the nature of the charge ordering and its relation to the superconductivity is yet to be reached. This review provides an overview of the novel charge orders and the emergence of superconductivity in IrTe2. We further introduce the recent studies on IrTe2 nanoflake, in which novel charge orders attainable only in two-dimensional limits lay the grounds for an exotic phase diagram.

Published

2024

3. Spin-orbit-splitting-driven nonlinear Hall effect in NbIrTe4

Author

Lee, Ji-Eun, Wang, Aifeng, Chen, Shuzhang, Kwon, Minseong, Hwang, Jinwoong, Cho, Minhyun, Son, Ki-Hoon, Han, Dong-Soo, Choi, Jun Woo, Kim, Young Duck, Mo, Sung-Kwan, Petrovic, Cedomir, Hwang, Choongyu, Park, Se Young, Jang, Chaun, and Ryu, Hyejin

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The Berry curvature dipole (BCD) serves as a one of the fundamental contributors to emergence of the nonlinear Hall effect (NLHE). Despite intense interest due to its potential for new technologies reaching beyond the quantum efficiency limit, the interplay between BCD and NLHE has been barely understood yet in the absence of a systematic study on the electronic band structure. Here, we report NLHE realized in NbIrTe4 that persists above room temperature coupled with a sign change in the Hall conductivity at 150 K. First-principles calculations combined with angle-resolved photoemission spectroscopy (ARPES) measurements show that BCD tuned by the partial occupancy of spin-orbit split bands via temperature is responsible for the temperature-dependent NLHE. Our findings highlight the correlation between BCD and the electronic band structure, providing a viable route to create and engineer the non-trivial Hall effect by tuning the geometric properties of quasiparticles in transition-metal chalcogen compounds.

Published

2024

4. Modified Dirac fermions in the crystalline xenon and graphene Moir\'{e} heterostructure

Author

Im, Hayoon, Im, Suji, Kim, Kyoo, Lee, Ji-Eun, Hwang, Jinwoong, Mo, Sung-Kwan, and Hwang, Choongyu

Subjects

Condensed Matter - Materials Science

Abstract

The interface between two-dimensional (2D) crystals often forms a Moire superstructure that imposes a new periodicity, which is a key element in realizing complex electronic phases as evidenced in twisted bilayer graphene. A combined angle resolved photoemission spectroscopy measurements and first-principles calculations reveal the formation of a Moire superstructure between a 2D Dirac semi-metallic crystal, graphene, and a 2D insulating crystal of noble gas, xenon. Incommensurate diffraction pattern and folded Dirac cones around the Brillouin zone center imply the formation of hexagonal crystalline array of xenon atoms. The velocity of Dirac fermions increases upon the formation of the 2D xenon crystal on top of graphene due to the enhanced dielectric screening by the xenon over-layer. These findings not only provide a novel method to produce a Moire superstructure from the adsorption of noble gas on 2D materials, but also to control the physical properties of graphene by the formation of a graphene-noble gas interface., Comment: 15 pages, 4 figures

Published

2024

5. Controlling structure and interfacial interaction of monolayer TaSe2 on bilayer graphene

Author

Lee, Hyobeom, Im, Hayoon, Choi, Byoung Ki, Park, Kyoungree, Chen, Yi, Ruan, Wei, Zhong, Yong, Lee, Ji-Eun, Ryu, Hyejin, Crommie, Michael F., Shen, Zhi-Xun, Hwang, Choongyu, Mo, Sung-Kwan, and Hwang, Jinwoong

Subjects

Condensed Matter - Materials Science

Abstract

Tunability of interfacial effects between two-dimensional (2D) crystals is crucial not only for understanding the intrinsic properties of each system, but also for designing electronic devices based on ultra-thin heterostructures. A prerequisite of such heterostructure engineering is the availability of 2D crystals with different degrees of interfacial interactions. In this work, we report a controlled epitaxial growth of monolayer TaSe2 with different structural phases, 1H and 1T, on a bilayer graphene (BLG) substrate using molecular beam epitaxy, and its impact on the electronic properties of the heterostructures using angle-resolved photoemission spectroscopy. 1H-TaSe2 exhibits significant charge transfer and band hybridization at the interface, whereas 1T-TaSe2 shows weak interactions with the substrate. The distinct interfacial interactions are attributed to the dual effects from the differences of the work functions as well as the relative interlayer distance between TaSe2 films and BLG substrate. The method demonstrated here provides a viable route towards interface engineering in a variety of transition-metal dichalcogenides that can be applied to future nano-devices with designed electronic properties., Comment: 23 pages, 4 figures

Published

2024

6. Electronically Amplified Electron-Phonon Interaction and Metal-Insulator Transition in Perovskite Nickelates

Author

Zhong, Yong, Lee, Kyuho, Bhatta, Regan, Lee, Yonghun, Gonzalez, Martin, Li, Jiarui, Wang, Ruohan, Hashimoto, Makoto, Lu, Donghui, Mo, Sung-Kwan, Jia, Chunjing, Hwang, Harold Y., and Shen, Zhi-Xun

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science

Abstract

The relative role of electron-electron and electron-lattice interactions in driving the metal-insulator transition in perovskite nickelates opens a rare window into the non-trivial interplay of the two important degrees of freedom in solids. The most promising solution is to extract the electronic and lattice contributions during the phase transition by performing high-resolution spectroscopy measurements. Here, we present a three-dimensional electronic structure study of Nd1-xSrxNiO3 (x = 0 and 0.175) thin films with unprecedented accuracy, in which the low energy fermiology has a quantitative agreement with model simulations and first-principles calculations. Two characteristic phonons, the octahedral rotational and breathing modes, are illustrated to be coupled with the electron dynamics in the metallic phase, showing a kink structure along the band dispersion, as well as a hump feature in the energy spectrum. Entering the insulating state, the electron-phonon interaction is amplified by strong electron correlations, transforming the mobile large polarons at high temperatures to localized small polarons in the ground state. Moreover, the analysis of quasiparticle residue enables us to establish a transport-spectroscopy correspondence in Nd1-xSrxNiO3 thin films. Our findings demonstrate the essential role of electron-lattice interaction enhanced by the electronic correlation to stabilize the insulating phase in the perovskite nickelates., Comment: 26 pages, 4 + 7 figures

Published

2024

7. Massive 1D Dirac Line, Solitons and Reversible Manipulation on the Surface of a Prototype Obstructed Atomic Insulator, Silicon

Author

Liu, Zhongkai, Deng, Peng, Xu, Yuanfeng, Yang, Haifeng, Pei, Ding, Chen, Cheng, He, Shanmei, Liu, Defa, Mo, Sung-Kwan, Kim, Timur, Cacho, Cephise, Yao, Hong, Song, Zhi-Da, Chen, Xi, Wang, Zhong, Yan, Binghai, Yang, Lexian, Bernevig, Bogdan A., and Chen, Yulin

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Superconductivity

Abstract

Topologically trivial insulators can be classified into atomic insulators (AIs) and obstructed atomic insulators (OAIs) depending on whether the Wannier charge centers are localized or not at spatial positions occupied by atoms. An OAI can possess unusual properties such as surface states along certain crystalline surfaces, which advantageously appear in materials with much larger bulk energy gap than topological insulators, making them more attractive for potential applications. In this work, we show that a well-known crystal, silicon (Si) is a model OAI, which naturally explains some of Si's unusual properties such as its famous (111) surface states. On this surface, using angle resolved photoemission spectroscopy (ARPES), we reveal sharp quasi-1D massive Dirac line dispersions; we also observe, using scanning tunneling microscopy/spectroscopy (STM/STS), topological solitons at the interface of the two atomic chains. Remarkably, we show that the different chain domains can be reversibly switched at the nanometer scale, suggesting the application potential in ultra-high density storage devices.

Published

2024

8. Recent progress of MnBi 2 Te 4 epitaxial thin films as a platform for realising the quantum anomalous Hall effect

Author

Li, Qile, Mo, Sung-Kwan, and Edmonds, Mark T

Subjects

Quantum Physics, Physical Sciences, Condensed Matter Physics, Chemical Sciences, Technology, Nanoscience & Nanotechnology, Chemical sciences, Engineering, Physical sciences

Abstract

Since the first realisation of the quantum anomalous Hall effect (QAHE) in a dilute magnetic-doped topological insulator thin film in 2013, the quantisation temperature has been limited to less than 1 K due to magnetic disorder in dilute magnetic systems. With magnetic moments ordered into the crystal lattice, the intrinsic magnetic topological insulator MnBi2Te4 has the potential to eliminate or significantly reduce magnetic disorder and improve the quantisation temperature. Surprisingly, to date, the QAHE has yet to be observed in molecular beam epitaxy (MBE)-grown MnBi2Te4 thin films at zero magnetic field, and what leads to the difficulty in quantisation is still an active research area. Although bulk MnBi2Te4 and exfoliated flakes have been well studied, revealing both the QAHE and axion insulator phases, experimental progress on MBE thin films has been slower. Understanding how the breakdown of the QAHE occurs in MnBi2Te4 thin films and finding solutions that will enable mass-produced millimetre-size QAHE devices operating at elevated temperatures are required. In this mini-review, we will summarise recent studies on the electronic and magnetic properties of MBE MnBi2Te4 thin films and discuss mechanisms that could explain the failure of the QAHE from the aspects of defects, electronic structure, magnetic order, and consequences of their delicate interplay. Finally, we propose several strategies for realising the QAHE at elevated temperatures in MnBi2Te4 thin films.

Published

2024

9. Unconventional Spectral Gaps Induced by Charge Density Waves in the Weyl Semimetal (TaSe4)2I

Author

Lin, Meng-Kai, Hlevyack, Joseph Andrew, Zhao, Chengxi, Dudin, Pavel, Avila, José, Mo, Sung-Kwan, Cheng, Cheng-Maw, Abbamonte, Peter, Shoemaker, Daniel P, and Chiang, Tai-Chang

Subjects

Quantum Physics, Physical Sciences, Condensed Matter Physics, (TaSe4)(2)I, band structure, charge density wave, Weyl semimetal, spectral gap, (TaSe4)2I, Nanoscience & Nanotechnology

Abstract

Coupling Weyl quasiparticles and charge density waves (CDWs) can lead to fascinating band renormalization and many-body effects beyond band folding and Peierls gaps. For the quasi-one-dimensional chiral compound (TaSe4)2I with an incommensurate CDW transition at TC = 263 K, photoemission mappings thus far are intriguing due to suppressed emission near the Fermi level. Models for this unconventional behavior include axion insulator phases, correlation pseudogaps, polaron subbands, bipolaron bound states, etc. Our photoemission measurements show sharp quasiparticle bands crossing the Fermi level at T > TC, but for T < TC, these bands retain their dispersions with no Peierls or axion gaps at the Weyl points. Instead, occupied band edges recede from the Fermi level, opening a spectral gap. Our results confirm localization of quasiparticles (holes created by photoemission) is the key physics, which suppresses spectral weights over an energy window governed by incommensurate modulation and inherent phase defects of CDW.

Published

2024

10. Synthesis and Polymorph Manipulation of FeSe2 Monolayers

Author

He, Zehao, Poudel, Shiva Prasad, Stolz, Samuel, Wang, Tianye, Rossi, Antonio, Wang, Feng, Mo, Sung-Kwan, Weber-Bargioni, Alexander, Qiu, Zi Qiang, Barraza-Lopez, Salvador, Zhu, Tiancong, and Crommie, Michael F

Subjects

Physical Sciences, Condensed Matter Physics, polymorphism, magnetism, two-dimensional materials, scanning tunneling microscopy, phase transitions, density functional theory, Nanoscience & Nanotechnology

Abstract

Polymorph engineering involves the manipulation of material properties through controlled structural modification and is a candidate technique for creating unique two-dimensional transition metal dichalcogenide (TMDC) nanodevices. Despite its promise, polymorph engineering of magnetic TMDC monolayers has not yet been demonstrated. Here we grow FeSe2 monolayers via molecular beam epitaxy and find that they have great promise for magnetic polymorph engineering. Using scanning tunneling microscopy (STM) and spectroscopy (STS), we find that FeSe2 monolayers predominantly display a 1T' structural polymorph at 5 K. Application of voltage pulses from an STM tip causes a local, reversible transition from the 1T' phase to the 1T phase. Density functional theory calculations suggest that this single-layer structural phase transition is accompanied by a magnetic transition from an antiferromagnetic to a ferromagnetic configuration. These results open new possibilities for creating functional magnetic devices with TMDC monolayers via polymorph engineering.

Published

2024

11. Imaging the Breakdown and Restoration of Topological Protection in Magnetic Topological Insulator MnBi2Te4

Author

Li, Qile, Di Bernardo, Iolanda, Maniatis, Johnathon, McEwen, Daniel, Dominguez‐Celorrio, Amelia, Bhuiyan, Mohammad TH, Zhao, Mengting, Tadich, Anton, Watson, Liam, Lowe, Benjamin, Vu, Thi‐Hai‐Yen, Trang, Chi Xuan, Hwang, Jinwoong, Mo, Sung‐Kwan, Fuhrer, Michael S, and Edmonds, Mark T

Subjects

Quantum Physics, Physical Sciences, Condensed Matter Physics, magnetic topological insulators, quantum anomalous Hall effect, scanning tunneling microscopy and spectroscopy, topological materials, Chemical Sciences, Engineering, Nanoscience & Nanotechnology, Chemical sciences, Physical sciences

Abstract

Quantum anomalous Hall (QAH) insulators transport charge without resistance along topologically protected chiral 1D edge states. Yet, in magnetic topological insulators to date, topological protection is far from robust, with zero-magnetic field QAH effect only realized at temperatures an order of magnitude below the Néel temperature TN, though small magnetic fields can stabilize QAH effect. Understanding why topological protection breaks down is therefore essential to realizing QAH effect at higher temperatures. Here a scanning tunneling microscope is used to directly map the size of exchange gap (Eg,ex) and its spatial fluctuation in the QAH insulator 5-layer MnBi2Te4. Long-range fluctuations of Eg,ex are observed, with values ranging between 0 (gapless) and 70 meV, appearing to be uncorrelated to individual surface point defects. The breakdown of topological protection is directly imaged, showing that the gapless edge state, the hallmark signature of a QAH insulator, hybridizes with extended gapless regions in the bulk. Finally, it is unambiguously demonstrated that the gapless regions originate from magnetic disorder, by demonstrating that a small magnetic field restores Eg,ex in these regions, explaining the recovery of topological protection in magnetic fields. The results indicate that overcoming magnetic disorder is the key to exploiting the unique properties of QAH insulators.

Published

2024

12. Tailoring Physical Properties of Crystals through Synthetic Temperature Control: A Case Study for new Polymorphic NbFeTe2 phases

Author

Wu, Hanlin, Li, Sheng, Lyu, Yan, Guo, Yucheng, Liu, Wenhao, Oh, Ji Seop, Zhang, Yichen, Mo, Sung-Kwan, Cruz, Clarina dela, Birgeneau, Robert J., Taddei, Keith M., Yi, Ming, Yang, Li, and Lv, Bing

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science

Abstract

Growth parameters play a significant role in the crystal quality and physical properties of layered materials. Here we present a case study on a van der Waals magnetic NbFeTe2 material. Two different types of polymorphic NbFeTe2 phases, synthesized at different temperatures, display significantly different behaviors in crystal symmetry, electronic structure, electrical transport, and magnetism. While the phase synthesized at low temperature showing behavior consistent with previous reports, the new phase synthesized at high temperature, has completely different physical properties, such as metallic resistivity, long-range ferromagnetic order, anomalous Hall effect, negative magnetoresistance, and distinct electronic structures. Neutron diffraction reveals out-of-plane ferromagnetism below 70K, consistent with the electrical transport and magnetic susceptibility studies. Our work suggests that simply tuning synthetic parameters in a controlled manner could be an effective route to alter the physical properties of existing materials potentially unlocking new states of matter, or even discovering new materials., Comment: 22 Pages, 6 figures

Published

2024

13. Electronic structure of above-room-temperature van der Waals ferromagnet Fe$_3$GaTe$_2$

Author

Lee, Ji-Eun, Yan, Shaohua, Oh, Sehoon, Hwang, Jinwoong, Denlinger, Jonathan D., Hwang, Choongyu, Lei, Hechang, Mo, Sung-Kwan, Park, Se Young, and Ryu, Hyejin

Subjects

Condensed Matter - Materials Science

Abstract

Fe$_3$GaTe$_2$, a recently discovered van der Waals ferromagnet, demonstrates intrinsic ferromagnetism above room temperature, necessitating a comprehensive investigation of the microscopic origins of its high Curie temperature ($\textit{T}$$_C$). In this study, we reveal the electronic structure of Fe$_3$GaTe$_2$ in its ferromagnetic ground state using angle-resolved photoemission spectroscopy and density functional theory calculations. Our results establish a consistent correspondence between the measured band structure and theoretical calculations, underscoring the significant contributions of the Heisenberg exchange interaction ($\textit{J}$$_{ex}$) and magnetic anisotropy energy to the development of the high-$\textit{T}$$_C$ ferromagnetic ordering in Fe$_3$GaTe$_2$. Intriguingly, we observe substantial modifications to these crucial driving factors through doping, which we attribute to alterations in multiple spin-splitting bands near the Fermi level. These findings provide valuable insights into the underlying electronic structure and its correlation with the emergence of high-$\textit{T}$$_C$ ferromagnetic ordering in Fe$_3$GaTe$_2$., Comment: 25 pages, 4 figures

Published

2024

14. Electronic structure of the alternating monolayer-trilayer phase of La3Ni2O7

Author

Abadi, Sebastien N., Xu, Ke-Jun, Lomeli, Eder G., Puphal, Pascal, Isobe, Masahiko, Zhong, Yong, Fedorov, Alexei V., Mo, Sung-Kwan, Hashimoto, Makoto, Lu, Dong-Hui, Moritz, Brian, Keimer, Bernhard, Devereaux, Thomas P., Hepting, Matthias, and Shen, Zhi-Xun

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Strongly Correlated Electrons

Abstract

Recent studies of La$_3$Ni$_2$O$_7$ have identified a bilayer (2222) structure and an unexpected alternating monolayer-trilayer (1313) structure, both of which feature signatures of superconductivity near 80 K under high pressures. Using angle-resolved photoemission spectroscopy, we measure the electronic structure of 1313 samples. In contrast to the previously studied 2222 structure, we find that the 1313 structure hosts a flat band with a markedly different binding energy, as well as an additional electron pocket and band splittings. By comparison to local-density approximation calculations, we find renormalizations of the Ni-$d_{z^2}$ and Ni-$d_{x^2-y^2}$ derived bands to be about 5 to 7 and about 4 respectively, suggesting strong correlation effects. These results reveal important differences in the electronic structure brought about by the distinct structural motifs with the same stoichiometry. Such differences may be relevant to the putative high temperature superconductivity., Comment: Version 2: Improved data quality of the small electron pocket at the zone center ($\epsilon$ band). Also, observations of multilayer splitting effects in the flat band ($\gamma$ and $\delta$ bands) and in the large cuprate-like pockets ($\beta$ bands). Band structure calculations now use LDA instead of LDA+U. Main text: 7 pages, 3 figures. SM: 9 pages, 6 figures

Published

2024

15. Emergence of two distinct phase transitions in monolayer CoSe2 on graphene

Author

Rhee, Tae Gyu, Lam, Nguyen Huu, Kim, Yeong Gwang, Gu, Minseon, Hwang, Jinwoong, Bostwick, Aaron, Mo, Sung-Kwan, Chun, Seung-Hyun, Kim, Jungdae, Chang, Young Jun, and Choi, Byoung Ki

Subjects

Engineering, Nanotechnology, Angle-resolved photoemission spectroscopy, Charge-density wave, Electron-boson coupling, Molecular beam epitaxy, Scanning tunneling microscopy, Transition metal chalcogenides

Abstract

Dimensional modifications play a crucial role in various applications, especially in the context of device miniaturization, giving rise to novel quantum phenomena. The many-body dynamics induced by dimensional modifications, including electron-electron, electron-phonon, electron-magnon and electron-plasmon coupling, are known to significantly affect the atomic and electronic properties of the materials. By reducing the dimensionality of orthorhombic CoSe2 and forming heterostructure with bilayer graphene using molecular beam epitaxy, we unveil the emergence of two types of phase transitions through angle-resolved photoemission spectroscopy and scanning tunneling microscopy measurements. We disclose that the 2 × 1 superstructure is associated with charge density wave induced by Fermi surface nesting, characterized by a transition temperature of 340 K. Additionally, another phase transition at temperature of 160 K based on temperature dependent gap evolution are observed with renormalized electronic structure induced by electron-boson coupling. These discoveries of the electronic and atomic modifications, influenced by electron-electron and electron-boson interactions, underscore that many-body physics play significant roles in understanding low-dimensional properties of non-van der Waals Co-chalcogenides and related heterostructures.

Published

2024

16. Charge density waves in two-dimensional transition metal dichalcogenides

Author

Hwang, Jinwoong, Ruan, Wei, Chen, Yi, Tang, Shujie, Crommie, Michael F, Shen, Zhi-Xun, and Mo, Sung-Kwan

Subjects

Quantum Physics, Physical Sciences, Condensed Matter Physics, charge density wave, transition metal dichalcogenides, ARPES, STM, MBE, Mathematical Sciences, General Physics, Mathematical sciences, Physical sciences

Abstract

Charge density wave (CDW is one of the most ubiquitous electronic orders in quantum materials. While the essential ingredients of CDW order have been extensively studied, a comprehensive microscopic understanding is yet to be reached. Recent research efforts on the CDW phenomena in two-dimensional (2D) materials provide a new pathway toward a deeper understanding of its complexity. This review provides an overview of the CDW orders in 2D with atomically thin transition metal dichalcogenides (TMDCs) as the materials platform. We mainly focus on the electronic structure investigations on the epitaxially grown TMDC samples with angle-resolved photoemission spectroscopy and scanning tunneling microscopy/spectroscopy as complementary experimental tools. We discuss the possible origins of the 2D CDW, novel quantum states coexisting with them, and exotic types of charge orders that can only be realized in the 2D limit.

Published

2024

17. Two-Step Electronic Response to Magnetic Ordering in a van der Waals Ferromagnet

Author

Wu, Han, Zhu, Jian-Xin, Chen, Lebing, Butcher, Matthew W, Yue, Ziqin, Yuan, Dongsheng, He, Yu, Oh, Ji Seop, Huang, Jianwei, Wu, Shan, Gong, Cheng, Guo, Yucheng, Mo, Sung-Kwan, Denlinger, Jonathan D., Lu, Donghui, Hashimoto, Makoto, Stone, Matthew B., Kolesnikov, Alexander I., Chi, Songxue, Kono, Junichiro, Nevidomskyy, Andriy H., Birgeneau, Robert J., Dai, Pengcheng, and Yi, Ming

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science

Abstract

The two-dimensional (2D) material Cr$_2$Ge$_2$Te$_6$ is a member of the class of insulating van der Waals magnets. Here, using high resolution angle-resolved photoemission spectroscopy in a detailed temperature dependence study, we identify a clear response of the electronic structure to a dimensional crossover in the form of two distinct temperature scales marking onsets of modifications in the electronic structure. Specifically, we observe Te $p$-orbital-dominated bands to undergo changes at the Curie transition temperature T$_C$ while the Cr $d$-orbital-dominated bands begin evolving at a higher temperature scale. Combined with neutron scattering, density functional theory calculations, and Monte Carlo simulations, we find that the electronic system can be consistently understood to respond sequentially to the distinct temperatures at which in-plane and out-of-plane spin correlations exceed a characteristic length scale. Our findings reveal the sensitivity of the orbital-selective electronic structure for probing the dynamical evolution of local moment correlations in vdW insulating magnets., Comment: PRB, in press

Published

2023

18. From Stoner to Local Moment Magnetism in Atomically Thin Cr2Te3

Author

Zhong, Yong, Peng, Cheng, Huang, Haili, Guan, Dandan, Hwang, Jinwoong, Hsu, Kuan H., Hu, Yi, Jia, Chunjing, Moritz, Brian, Lu, Donghui, Lee, Jun-Sik, Jia, Jin-Feng, Devereaux, Thomas P., Mo, Sung-Kwan, and Shen, Zhi-Xun

Subjects

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

Abstract

The field of two-dimensional (2D) ferromagnetism has been proliferating over the past few years, with ongoing interests in basic science and potential applications in spintronic technology. However, a high-resolution spectroscopic study of the 2D ferromagnet is still lacking due to the small size and air sensitivity of the exfoliated nanoflakes. Here, we report a thickness-dependent ferromagnetism in epitaxially grown Cr2Te3 thin films and investigate the evolution of the underlying electronic structure by synergistic angle-resolved photoemission spectroscopy, scanning tunneling microscopy, x-ray absorption spectroscopy, and first-principle calculations. A conspicuous ferromagnetic transition from Stoner to Heisenberg-type is directly observed in the atomically thin limit, indicating that dimensionality is a powerful tuning knob to manipulate the novel properties of 2D magnetism. Monolayer Cr2Te3 retains robust ferromagnetism, but with a suppressed Curie temperature, due to the drastic drop in the density of states near the Fermi level. Our results establish atomically thin Cr2Te3 as an excellent platform to explore the dual nature of localized and itinerant ferromagnetism in 2D magnets., Comment: 32 pages, 4 + 10 figures

Published

2023

19. Dimensionality-driven metal to Mott insulator transition in two-dimensional 1T-TaSe2

Author

Tian, Ning, Huang, Zhe, Jang, Bo Gyu, Guo, Shuaifei, Yan, Ya-Jun, Gao, Jingjing, Yu, Yijun, Hwang, Jinwoong, Tang, Cenyao, Wang, Meixiao, Luo, Xuan, Sun, Yu Ping, Liu, Zhongkai, Feng, Dong-Lai, Chen, Xianhui, Mo, Sung-Kwan, Kim, Minjae, Son, Young-Woo, Shen, Dawei, Ruan, Wei, and Zhang, Yuanbo

Subjects

Quantum Physics, Physical Sciences, Condensed Matter Physics, Crop and Pasture Production

Abstract

Two-dimensional materials represent a major frontier for research into exotic many-body quantum phenomena. In the extreme two-dimensional limit, electron-electron interaction often dominates over other electronic energy scales, leading to strongly correlated effects such as quantum spin liquid and unconventional superconductivity. The dominance is conventionally attributed to the lack of electron screening in the third dimension. Here, we discover an intriguing metal to Mott insulator transition in 1T-TaSe2 that defies conventional wisdom. Specifically, we find that dimensionality crossover, instead of reduced screening, drives the transition in atomically thin 1T-TaSe2. A dispersive band crossing the Fermi level is found to be responsible for the bulk metallicity in the material. Reducing the dimensionality, however, effectively quenches the kinetic energy of these initially itinerant electrons, and drives the material into a Mott insulating state. The dimensionality-driven metal to Mott insulator transition resolves the long-standing dichotomy between metallic bulk and insulating surface of 1T-TaSe2. Our work further reveals a new pathway for modulating two-dimensional materials that enables exploring strongly correlated systems across uncharted parameter space.

Published

2024

20. Reversible non-volatile electronic switching in a near-room-temperature van der Waals ferromagnet

Author

Wu, Han, Chen, Lei, Malinowski, Paul, Jang, Bo Gyu, Deng, Qinwen, Scott, Kirsty, Huang, Jianwei, Ruff, Jacob PC, He, Yu, Chen, Xiang, Hu, Chaowei, Yue, Ziqin, Oh, Ji Seop, Teng, Xiaokun, Guo, Yucheng, Klemm, Mason, Shi, Chuqiao, Shi, Yue, Setty, Chandan, Werner, Tyler, Hashimoto, Makoto, Lu, Donghui, Yilmaz, Turgut, Vescovo, Elio, Mo, Sung-Kwan, Fedorov, Alexei, Denlinger, Jonathan D, Xie, Yaofeng, Gao, Bin, Kono, Junichiro, Dai, Pengcheng, Han, Yimo, Xu, Xiaodong, Birgeneau, Robert J, Zhu, Jian-Xin, da Silva Neto, Eduardo H, Wu, Liang, Chu, Jiun-Haw, Si, Qimiao, and Yi, Ming

Subjects

Physical Sciences, Condensed Matter Physics

Abstract

Non-volatile phase-change memory devices utilize local heating to toggle between crystalline and amorphous states with distinct electrical properties. Expanding on this kind of switching to two topologically distinct phases requires controlled non-volatile switching between two crystalline phases with distinct symmetries. Here, we report the observation of reversible and non-volatile switching between two stable and closely related crystal structures, with remarkably distinct electronic structures, in the near-room-temperature van der Waals ferromagnet Fe5-δGeTe2. We show that the switching is enabled by the ordering and disordering of Fe site vacancies that results in distinct crystalline symmetries of the two phases, which can be controlled by a thermal annealing and quenching method. The two phases are distinguished by the presence of topological nodal lines due to the preserved global inversion symmetry in the site-disordered phase, flat bands resulting from quantum destructive interference on a bipartite lattice, and broken inversion symmetry in the site-ordered phase.

Published

2024

21. Two-step electronic response to magnetic ordering in a van der Waals ferromagnet

Author

Wu, Han, Zhu, Jian-Xin, Chen, Lebing, Butcher, Matthew W, Yue, Ziqin, Yuan, Dongsheng, He, Yu, Oh, Ji Seop, Gao, Bin, Huang, Jianwei, Wu, Shan, Gong, Cheng, Guo, Yucheng, Mo, Sung-Kwan, Denlinger, Jonathan, Lu, Donghui, Hashimoto, Makoto, Stone, Matthew B, Kolesnikov, Alexander I, Chi, Songxue, Kono, Junichiro, Nevidomskyy, Andriy H, Birgeneau, Robert J, Dai, Pengcheng, and Yi, Ming

Subjects

Physical Sciences, Condensed Matter Physics, Chemical sciences, Engineering, Physical sciences

Abstract

The two-dimensional material Cr2Ge2Te6 is a member of the class of insulating van der Waals (vdW) magnets. Here, using high resolution angle-resolved photoemission spectroscopy in a detailed temperature dependence study, we identify a clear response of the electronic structure to a dimensional crossover in the form of two distinct temperature scales marking onsets of modifications in the electronic structure. Specifically, we observe Te p-orbital-dominated bands to undergo changes at the Curie transition temperature TC while the Cr d-orbital-dominated bands begin evolving at a higher temperature scale. Combined with neutron scattering, density functional theory calculations, and Monte Carlo simulations, we find that the electronic system can be consistently understood to respond sequentially to the distinct temperatures at which in-plane and out-of-plane spin correlations exceed a characteristic length scale. Our findings reveal the sensitivity of the orbital-selective electronic structure for probing the dynamical evolution of local moment correlations in vdW insulating magnets.

Published

2024

22. Electronic Structure of Above-Room-Temperature van der Waals Ferromagnet Fe3GaTe2

Author

Lee, Ji-Eun, Yan, Shaohua, Oh, Sehoon, Hwang, Jinwoong, Denlinger, Jonathan D, Hwang, Choongyu, Lei, Hechang, Mo, Sung-Kwan, Park, Young, and Ryu, Hyejin

Subjects

Quantum Physics, Physical Sciences, Condensed Matter Physics, Fe3GaTe2, room-temperature vander Waals ferromagnet, high-T (C) ferromagnet, electronic structures, Heisenbergexchange interaction, magnetic anisotropy energy, Heisenberg exchange interaction, high-TC ferromagnet, room-temperature van der Waals ferromagnet, Nanoscience & Nanotechnology

Abstract

Fe3GaTe2, a recently discovered van der Waals ferromagnet, demonstrates intrinsic ferromagnetism above room temperature, necessitating a comprehensive investigation of the microscopic origins of its high Curie temperature (TC). In this study, we reveal the electronic structure of Fe3GaTe2 in its ferromagnetic ground state using angle-resolved photoemission spectroscopy and density functional theory calculations. Our results establish a consistent correspondence between the measured band structure and theoretical calculations, underscoring the significant contributions of the Heisenberg exchange interaction (Jex) and magnetic anisotropy energy to the development of the high-TC ferromagnetic ordering in Fe3GaTe2. Intriguingly, we observe substantial modifications to these crucial driving factors through doping, which we attribute to alterations in multiple spin-splitting bands near the Fermi level. These findings provide valuable insights into the underlying electronic structure and its correlation with the emergence of high-TC ferromagnetic ordering in Fe3GaTe2.

Published

2023

23. Antiferromagnetic topological insulating state in Tb$_{0.02}$Bi$_{1.08}$Sb$_{0.9}$Te$_2$S single crystals

Author

Guo, Lei, Zhao, Weiyao, Li, Qile, Xu, Meng, Chen, Lei, Bake, Abdulhakim, Vu, Thi-Hai-Yen, He, Yahua, Fang, Yong, Cortie, David, Mo, Sung-Kwan, Edmonds, Mark, Wang, Xiaolin, Dong, Shuai, Karel, Julie, and Zheng, Ren-Kui

Subjects

Condensed Matter - Materials Science

Abstract

Topological insulators are emerging materials with insulating bulk and symmetry protected nontrivial surface states. One of the most fascinating transport behaviors in a topological insulator is the quantized anomalous Hall insulator, which has been observed inmagnetic-topological-insulator-based devices. In this work, we report a successful doping of rare earth element Tb into Bi$_{1.08}$Sb$_{0.9}$Te$_2$S topological insulator single crystals, in which the Tb moments are antiferromagnetically ordered below ~10 K. Benefiting from the in-bulk-gap Fermi level, transport behavior dominant by the topological surface states is observed below ~ 150 K. At low temperatures, strong Shubnikov-de Haas oscillations are observed, which exhibit 2D-like behavior. The topological insulator with long range magnetic ordering in rare earth doped Bi$_{1.08}$Sb$_{0.9}$Te$_2$S single crystal provides an ideal platform for quantum transport studies and potential applications., Comment: 15 pages, 3 figures

Published

2023

24. Reversible Non-Volatile Electronic Switching in a Near Room Temperature van der Waals Ferromagnet

Author

Wu, Han, Chen, Lei, Malinowski, Paul, Huang, Jianwei, Deng, Qinwen, Scott, Kirsty, Jang, Bo Gyu, Ruff, Jacob P. C., He, Yu, Chen, Xiang, Hu, Chaowei, Yue, Ziqin, Oh, Ji Seop, Teng, Xiaokun, Guo, Yucheng, Klemm, Mason, Shi, Chuqiao, Shi, Yue, Setty, Chandan, Werner, Tyler, Hashimoto, Makoto, Lu, Donghui, Yilmaz, T., Vescovo, Elio, Mo, Sung-Kwan, Fedorov, Alexei, Denlinger, Jonathan, Xie, Yaofeng, Gao, Bin, Kono, Junichiro, Dai, Pengcheng, Han, Yimo, Xu, Xiaodong, Birgeneau, Robert J., Zhu, Jian-Xin, Neto, Eduardo H. da Silva, Wu, Liang, Chu, Jiun-Haw, Si, Qimiao, and Yi, Ming

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science

Abstract

The ability to reversibly toggle between two distinct states in a non-volatile method is important for information storage applications. Such devices have been realized for phase-change materials, which utilizes local heating methods to toggle between a crystalline and an amorphous state with distinct electrical properties. To expand such kind of switching between two topologically distinct phases requires non-volatile switching between two crystalline phases with distinct symmetries. Here we report the observation of reversible and non-volatile switching between two stable and closely-related crystal structures with remarkably distinct electronic structures in the near room temperature van der Waals ferromagnet Fe$_{5-\delta}$GeTe$_2$. From a combination of characterization techniques we show that the switching is enabled by the ordering and disordering of an Fe site vacancy that results in distinct crystalline symmetries of the two phases that can be controlled by a thermal annealing and quenching method. Furthermore, from symmetry analysis as well as first principle calculations, we provide understanding of the key distinction in the observed electronic structures of the two phases: topological nodal lines compatible with the preserved global inversion symmetry in the site-disordered phase, and flat bands resulting from quantum destructive interference on a bipartite crystaline lattice formed by the presence of the site order as well as the lifting of the topological degeneracy due to the broken inversion symmetry in the site-ordered phase. Our work not only reveals a rich variety of quantum phases emergent in the metallic van der Waals ferromagnets due to the presence of site ordering, but also demonstrates the potential of these highly tunable two-dimensional magnets for memory and spintronics applications.

Published

2023

25. Charge order induced Dirac pockets in the nonsymmorphic crystal TaTe4

Author

Zhang, Yichen, Zhou, Ruixiang, Wu, Hanlin, Oh, Ji Seop, Li, Sheng, Huang, Jianwei, Denlinger, Jonathan D, Hashimoto, Makoto, Lu, Donghui, Mo, Sung-Kwan, Kelly, Kevin F, McCandless, Gregory T, Chan, Julia Y, Birgeneau, Robert J, Lv, Bing, Li, Gang, and Yi, Ming

Subjects

Physical Sciences, Condensed Matter Physics, Chemical sciences, Engineering, Physical sciences

Abstract

The interplay between charge order (CO) and nontrivial band topology has spurred tremendous interest in understanding topological excitations beyond the single-particle description. In a quasi-one-dimensional nonsymmorphic crystal TaTe4, the (2a×2b×3c) charge ordered ground state drives the system into a space group where the symmetry indicators feature the emergence of Dirac fermions and unconventional double Dirac fermions. Using angle-resolved photoemission spectroscopy and first-principles calculations, we provide evidence of the CO induced Dirac fermion-related bands near the Fermi level. Furthermore, the band folding at the Fermi level is compatible with the new periodicity dictated by the CO, indicating that the electrons near the Fermi level follow the crystalline symmetries needed to host double Dirac fermions in this system.

Published

2023

26. Correction: Emergence of two distinct phase transitions in monolayer CoSe2 on graphene

Author

Rhee, Tae Gyu, Lam, Nguyen Huu, Kim, Yeong Gwang, Gu, Minseon, Hwang, Jinwoong, Bostwick, Aaron, Mo, Sung-Kwan, Chun, Seung-Hyun, Kim, Jungdae, Chang, Young Jun, and Choi, Byoung Ki

Published

2024

27. Differentiated roles of Lifshitz transition on thermodynamics and superconductivity in La2-xSrxCuO4

Author

Zhong, Yong, Chen, Zhuoyu, Chen, Su-Di, Xu, Ke-Jun, Hashimoto, Makoto, He, Yu, Uchida, Shin-ichi, Lu, Donghui, Mo, Sung-Kwan, and Shen, Zhi-Xun

Subjects

Condensed Matter - Superconductivity

Abstract

The effect of Lifshitz transition on thermodynamics and superconductivity in hole-doped cuprates has been heavily debated but remains an open question. In particular, an observed peak of electronic specific heat is proposed to originate from fluctuations of a putative quantum critical point p* (e.g. the termination of pseudogap at zero temperature), which is close to, but distinguishable from the Lifshitz transition in La-based cuprates. Here, we report an in situ angle-resolved photoemission spectroscopy study of three-dimensional Fermi surfaces in La2-xSrxCuO4 thin films(x = 0.06 - 0.35). With accurate kz dispersion quantification, the Lifshitz transition is determined to happen within a finite range around x = 0.21. Normal state electronic specific heat, calculated from spectroscopy-derived band parameters, agrees with previous thermodynamic microcalorimetry measurements. The account of the specific heat maximum by underlying band structures excludes the need for additionally dominant contribution from the quantum fluctuations at p*. A d-wave superconducting gap smoothly across the Lifshitz transition demonstrates the insensitivity of superconductivity to the dramatic density of states enhancement.

Published

2023

28. Spectral evidence for unidirectional charge density wave in detwinned BaNi2As2

Author

Guo, Yucheng, Klemm, Mason, Oh, Ji Seop, Xie, Yaofeng, Lei, Bing-Hua, Moreschini, Luca, Chen, Cheng, Yue, Ziqin, Gorovikov, Sergey, Pedersen, Tor, Michiardi, Matteo, Zhdanovich, Sergey, Damascelli, Andrea, Denlinger, Jonathan, Hashimoto, Makoto, Lu, Donghui, Jozwiak, Chris, Bostwick, Aaron, Rotenberg, Eli, Mo, Sung-Kwan, Moore, Rob G, Kono, Junichiro, Birgeneau, Robert J, Singh, David J, Dai, Pengcheng, and Yi, Ming

Subjects

Physical Sciences, Condensed Matter Physics, Chemical sciences, Engineering, Physical sciences

Abstract

In the iron-based superconductors, unconventional superconductivity emerges in proximity to intertwined electronic orders consisting of an electronic nematic order and a spin density wave (SDW). Recently, BaNi2As2, like its well-known iron-based analog BaFe2As2, has been discovered to host a symmetry-breaking structural transition but coupled to a unidirectional charge density wave (CDW) instead of SDW, providing a novel platform to study intertwined orders. Here, through a systematic angle-resolved photoemission spectroscopy study combined with a detwinning B1g uniaxial strain, we identify distinct spectral evidence of band evolution due to the structural transition as well as CDW-induced band folding. In contrast to the nematicity and spin density wave in BaFe2As2, the structural and CDW order parameters in BaNi2As2 are observed to be strongly coupled and do not separate in the presence of uniaxial strain. Furthermore, no nematic band splitting is resolved above the structural transition. Our measurements point to a likely lattice origin of the CDW order in BaNi2As2.

Published

2023

29. Modified Dirac Fermions in the Crystalline Xenon and Graphene Moiré Heterostructure

Author

Im, Suji, Im, Hayoon, Kim, Kyoo, Lee, Ji‐Eun, Hwang, Jinwoong, Mo, Sung‐Kwan, and Hwang, Choongyu

Subjects

Physical Sciences, Condensed Matter Physics, ARPES, graphene, moir & eacute, structures, xenon

Abstract

Abstract: The interface between two‐dimensional (2D) crystals often forms a Moiré superstructure that imposes a new periodicity, which is a key element in realizing complex electronic phases as evidenced in twisted bilayer graphene. Acombined angle‐resolved photoemission spectroscopy measurements and first‐principles calculations reveal the formation of a Moiré superstructure between a 2D Dirac semi‐metallic crystal, graphene, and a 2D insulating crystal of noble gas, xenon. Incommensurate diffraction pattern and folded Dirac cones around the Brillouin zone center imply the formation of hexagonal crystalline array of xenon atoms. The velocity of Dirac fermions increases upon the formation of the 2D xenon crystal on top of graphene due to the enhanced dielectric screening by the xenon over‐layer. These findings not only provide a novel method to produce a Moiré superstructure from the adsorption of noble gas on 2D materials, but also to control the physical properties of graphene by the formation of a graphene‐noble gas interface.

Published

2023

30. Imaging the breakdown and restoration of topological protection in magnetic topological insulator MnBi$_2$Te$_4$

Author

Li, Qile, Di Bernardo, Iolanda, Maniatis, Johnathon, McEwen, Daniel, Watson, Liam, Lowe, Benjamin, Vu, Thi-Hai-Yen, Trang, Chi Xuan, Hwang, Jinwoong, Mo, Sung-Kwan, Fuhrer, Michael S., and Edmonds, Mark T.

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Quantum anomalous Hall (QAH) insulators transport charge without resistance along topologically protected chiral one-dimensional edge states. Yet, in magnetic topological insulators (MTI) to date, topological protection is far from robust, with the zero-magnetic field QAH effect only realised at temperatures an order of magnitude below the N\'eel temperature TN, though small magnetic fields can stabilize QAH effect. Understanding why topological protection breaks down is therefore essential to realising QAH effect at higher temperatures. Here we use a scanning tunnelling microscope to directly map the size of the exchange gap (Eg,ex) and its spatial fluctuation in the QAH insulator 5-layer MnBi$_2$Te$_4$. We observe long-range fluctuations of Eg,ex with values ranging between 0 (gapless) and 70 meV, uncorrelated to individual point defects. We directly image the breakdown of topological protection, showing that the chiral edge state, the hallmark signature of a QAH insulator, hybridizes with extended gapless metallic regions in the bulk. Finally, we unambiguously demonstrate that the gapless regions originate in magnetic disorder, by demonstrating that a small magnetic field restores Eg,ex in these regions, explaining the recovery of topological protection in magnetic fields. Our results indicate that overcoming magnetic disorder is key to exploiting the unique properties of QAH insulators.

Published

2023

31. Electronic origin of half-metal to semiconductor transition and colossal magnetoresistance in spinel HgCr2Se4

Author

Liang, Aiji, Li, Zhilin, Zhang, Shihao, Sun, Shucui, Liu, Shuai, Chen, Cheng, Yang, Haifeng, Cui, Shengtao, Mo, Sung-Kwan, Yang, Shuai, Li, Yongqing, Wang, Meixiao, Yang, Lexian, Liu, Jianpeng, Liu, Zhongkai, and Chen, Yulin

Subjects

Physical Sciences, Condensed Matter Physics, Chemical sciences, Engineering, Physical sciences

Abstract

Half metals are ferromagnets hosting spin-polarized conducting carriers and are crucial for spintronics applications. The chromium spinel HgCr2Se4 represents a unique type of half-metal, which features a half-metal to semiconductor transition (HMST) and exhibits colossal magnetoresistance (CMR) across the ferromagnetic-paramagnetic (FM-PM) transition. Using angle-resolved photoemission spectroscopy, we find that the Fermi surface of n-type HgCr2Se4 (n-HgCr2Se4) consists of a single electron pocket which moves above the Fermi level (EF) upon the FM-PM transition, leading to the HMST. Such a Lifshitz transition manifests a giant band splitting which originates from the exchange interaction unveiled with a specific chemical nonstoichiometry. The exchange band splitting and the chemical nonstoichiometry are two key ingredients to the HMST and CMR, consistent with our ab initio calculation. Our findings provide spectroscopic evidence of the electronic origin of the anomalous properties of HgCr2Se4, which address the unique phase transition in half-metals.

Published

2023

32. Electronic Origin of Half-metal to Semiconductor Transition and Colossal Magnetoresistance in Spinel HgCr2Se4

Author

Liang, Aiji, Li, Zhilin, Zhang, Shihao, Sun, Shucui, Liu, Shuai, Chen, Cheng, Yang, Haifeng, Cui, Shengtao, Mo, Sung-Kwan, Yang, Shuai, Li, Yongqing, Wang, Meixiao, Yang, Lexian, Liu, Jianpeng, Liu, Zhongkai, and Chen, Yulin

Subjects

Condensed Matter - Materials Science

Abstract

Half-metals are ferromagnets hosting spin-polarized conducting carriers and crucial for spintronics applications. The chromium spinel HgCr2Se4 represents a unique type of half-metal, which features a half-metal to semiconductor transition (HMST) and exhibits colossal magnetoresistance (CMR) across the ferromagnetic-paramagnetic (FM-PM) transition. Using angle-resolved photoemission spectroscopy (ARPES), we find that the Fermi surface of n-type HgCr2Se4 (n-HgCr2Se4) consists of a single electron pocket which moves above the Fermi level (EF) upon the FM-PM transition, leading to the HMST. Such a Lifshitz transition manifests a giant band splitting which originates from the exchange interaction unveiled with a specific chemical nonstoichiometry. The exchange band splitting and the chemical nonstoichiometry are two key ingredients to the HMST and CMR, consistent with our ab-initio calculation. Our findings provide spectroscopic evidences of the electronic origin of the anomalous properties of HgCr2Se4, which address the unique phase transition in half-metals.

Published

2022

33. Metal to Mott Insulator Transition in Two-dimensional 1T-TaSe$_2$

Author

Tian, Ning, Huang, Zhe, Jang, Bo Gyu, Guo, Shuaifei, Yan, Ya-Jun, Gao, Jingjing, Yu, Yijun, Hwang, Jinwoong, Wang, Meixiao, Luo, Xuan, Sun, Yu Ping, Liu, Zhongkai, Feng, Dong-Lai, Chen, Xianhui, Mo, Sung-Kwan, Kim, Minjae, Son, Young-Woo, Shen, Dawei, Ruan, Wei, and Zhang, Yuanbo

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science

Abstract

When electron-electron interaction dominates over other electronic energy scales, exotic, collective phenomena often emerge out of seemingly ordinary matter. The strongly correlated phenomena, such as quantum spin liquid and unconventional superconductivity, represent a major research frontier and a constant source of inspiration. Central to strongly correlated physics is the concept of Mott insulator, from which various other correlated phases derive. The advent of two-dimensional (2D) materials brings unprecedented opportunities to the study of strongly correlated physics in the 2D limit. In particular, the enhanced correlation and extreme tunability of 2D materials enables exploring strongly correlated systems across uncharted parameter space. Here, we discover an intriguing metal to Mott insulator transition in 1T-TaSe$_2$ as the material is thinned down to atomic thicknesses. Specifically, we discover, for the first time, that the bulk metallicity of 1T-TaSe$_2$ arises from a band crossing Fermi level. Reducing the dimensionality effectively quenches the kinetic energy of the initially itinerant electrons and drives the material into a Mott insulating state. The dimensionality-driven Metal to Mott insulator transition resolves the long-standing dichotomy between metallic bulk and insulating surface of 1T-TaSe$_2$. Our results additionally establish 1T-TaSe$_2$ as an ideal variable system for exploring various strongly correlated phenomena.

Published

2022

34. A novel $\sqrt{19}\times\sqrt{19}$ superstructure in epitaxially grown 1T-TaTe$_2$

Author

Hwang, Jinwoong, Jin, Yeongrok, Zhang, Canxun, Zhu, Tiancong, Kim, Kyoo, Zhong, Yong, Lee, Ji-Eun, Shen, Zongqi, Chen, Yi, Ruan, Wei, Ryu, Hyejin, Hwang, Choongyu, Lee, Jaekwang, Crommie, Michael F., Mo, Sung-Kwan, and Shen, Zhi-Xun

Subjects

Condensed Matter - Materials Science

Abstract

The spontaneous formation of electronic orders is a crucial element for understanding complex quantum states and engineering heterostructures in two-dimensional materials. We report a novel $\sqrt{19}\times\sqrt{19}$ charge order in few-layer thick 1T-TaTe$_2$ transition metal dichalcogenide films grown by molecular beam epitaxy, which has not been realized. Our photoemission and scanning probe measurements demonstrate that monolayer 1T-TaTe$_2$ exhibits a variety of metastable charge density wave orders, including the $\sqrt{19}\times\sqrt{19}$ superstructure, which can be selectively stabilized by controlling the post-growth annealing temperature. Moreover, we find that only the $\sqrt{19}\times\sqrt{19}$ order persists in 1T-TaTe$_2$ films thicker than a monolayer, up to 8 layers. Our findings identify the previously unrealized novel electronic order in a much-studied transition metal dichalcogenide and provide a viable route to control it within the epitaxial growth process.

Published

2022

35. Emergence of two distinct phase transitions in monolayer CoSe2 on graphene

Author

Tae Gyu Rhee, Nguyen Huu Lam, Yeong Gwang Kim, Minseon Gu, Jinwoong Hwang, Aaron Bostwick, Sung-Kwan Mo, Seung-Hyun Chun, Jungdae Kim, Young Jun Chang, and Byoung Ki Choi

Subjects

Transition metal chalcogenides, Charge-density wave, Electron-boson coupling, Molecular beam epitaxy, Angle-resolved photoemission spectroscopy, Scanning tunneling microscopy, Technology, Chemical technology, TP1-1185, Biotechnology, TP248.13-248.65, Science, Physics, QC1-999

Abstract

Abstract Dimensional modifications play a crucial role in various applications, especially in the context of device miniaturization, giving rise to novel quantum phenomena. The many-body dynamics induced by dimensional modifications, including electron-electron, electron-phonon, electron-magnon and electron-plasmon coupling, are known to significantly affect the atomic and electronic properties of the materials. By reducing the dimensionality of orthorhombic CoSe2 and forming heterostructure with bilayer graphene using molecular beam epitaxy, we unveil the emergence of two types of phase transitions through angle-resolved photoemission spectroscopy and scanning tunneling microscopy measurements. We disclose that the 2 × 1 superstructure is associated with charge density wave induced by Fermi surface nesting, characterized by a transition temperature of 340 K. Additionally, another phase transition at temperature of 160 K based on temperature dependent gap evolution are observed with renormalized electronic structure induced by electron-boson coupling. These discoveries of the electronic and atomic modifications, influenced by electron-electron and electron-boson interactions, underscore that many-body physics play significant roles in understanding low-dimensional properties of non-van der Waals Co-chalcogenides and related heterostructures. Graphical Abstract

Published

2024

36. Spin-orbit-splitting-driven nonlinear Hall effect in NbIrTe4

Author

Ji-Eun Lee, Aifeng Wang, Shuzhang Chen, Minseong Kwon, Jinwoong Hwang, Minhyun Cho, Ki-Hoon Son, Dong-Soo Han, Jun Woo Choi, Young Duck Kim, Sung-Kwan Mo, Cedomir Petrovic, Choongyu Hwang, Se Young Park, Chaun Jang, and Hyejin Ryu

Subjects

Science

Abstract

Abstract The Berry curvature dipole (BCD) serves as a one of the fundamental contributors to emergence of the nonlinear Hall effect (NLHE). Despite intense interest due to its potential for new technologies reaching beyond the quantum efficiency limit, the interplay between BCD and NLHE has been barely understood yet in the absence of a systematic study on the electronic band structure. Here, we report NLHE realized in NbIrTe4 that persists above room temperature coupled with a sign change in the Hall conductivity at 150 K. First-principles calculations combined with angle-resolved photoemission spectroscopy (ARPES) measurements show that BCD tuned by the partial occupancy of spin-orbit split bands via temperature is responsible for the temperature-dependent NLHE. Our findings highlight the correlation between BCD and the electronic band structure, providing a viable route to create and engineer the non-trivial Hall effect by tuning the geometric properties of quasiparticles in transition-metal chalcogen compounds.

Published

2024

37. Controlling structure and interfacial interaction of monolayer TaSe2 on bilayer graphene

Author

Hyobeom Lee, Hayoon Im, Byoung Ki Choi, Kyoungree Park, Yi Chen, Wei Ruan, Yong Zhong, Ji-Eun Lee, Hyejin Ryu, Michael F. Crommie, Zhi-Xun Shen, Choongyu Hwang, Sung-Kwan Mo, and Jinwoong Hwang

Subjects

Transition metal dichalcogenides, TaSe2, Graphene, Interface, Heterostructure, Molecular beam epitaxy, Technology, Chemical technology, TP1-1185, Biotechnology, TP248.13-248.65, Science, Physics, QC1-999

Abstract

Abstract Tunability of interfacial effects between two-dimensional (2D) crystals is crucial not only for understanding the intrinsic properties of each system, but also for designing electronic devices based on ultra-thin heterostructures. A prerequisite of such heterostructure engineering is the availability of 2D crystals with different degrees of interfacial interactions. In this work, we report a controlled epitaxial growth of monolayer TaSe2 with different structural phases, 1H and 1 T, on a bilayer graphene (BLG) substrate using molecular beam epitaxy, and its impact on the electronic properties of the heterostructures using angle-resolved photoemission spectroscopy. 1H-TaSe2 exhibits significant charge transfer and band hybridization at the interface, whereas 1 T-TaSe2 shows weak interactions with the substrate. The distinct interfacial interactions are attributed to the dual effects from the differences of the work functions as well as the relative interlayer distance between TaSe2 films and BLG substrate. The method demonstrated here provides a viable route towards interface engineering in a variety of transition-metal dichalcogenides that can be applied to future nano-devices with designed electronic properties.

Published

2024

38. Reversible non-volatile electronic switching in a near-room-temperature van der Waals ferromagnet

Author

Han Wu, Lei Chen, Paul Malinowski, Bo Gyu Jang, Qinwen Deng, Kirsty Scott, Jianwei Huang, Jacob P. C. Ruff, Yu He, Xiang Chen, Chaowei Hu, Ziqin Yue, Ji Seop Oh, Xiaokun Teng, Yucheng Guo, Mason Klemm, Chuqiao Shi, Yue Shi, Chandan Setty, Tyler Werner, Makoto Hashimoto, Donghui Lu, Turgut Yilmaz, Elio Vescovo, Sung-Kwan Mo, Alexei Fedorov, Jonathan D. Denlinger, Yaofeng Xie, Bin Gao, Junichiro Kono, Pengcheng Dai, Yimo Han, Xiaodong Xu, Robert J. Birgeneau, Jian-Xin Zhu, Eduardo H. da Silva Neto, Liang Wu, Jiun-Haw Chu, Qimiao Si, and Ming Yi

Subjects

Science

Abstract

Abstract Non-volatile phase-change memory devices utilize local heating to toggle between crystalline and amorphous states with distinct electrical properties. Expanding on this kind of switching to two topologically distinct phases requires controlled non-volatile switching between two crystalline phases with distinct symmetries. Here, we report the observation of reversible and non-volatile switching between two stable and closely related crystal structures, with remarkably distinct electronic structures, in the near-room-temperature van der Waals ferromagnet Fe5−δ GeTe2. We show that the switching is enabled by the ordering and disordering of Fe site vacancies that results in distinct crystalline symmetries of the two phases, which can be controlled by a thermal annealing and quenching method. The two phases are distinguished by the presence of topological nodal lines due to the preserved global inversion symmetry in the site-disordered phase, flat bands resulting from quantum destructive interference on a bipartite lattice, and broken inversion symmetry in the site-ordered phase.

Published

2024

39. An imported case of Afebrile 'Plasmodium falciparum' malaria infection from Tanzania in a returning traveler to the Republic of Korea following an earlier COVID-19 infection

Author

Lee, Chaeryoung, Hong, Sung Kwan, and Kim, Jong Hun

Published

2022

40. Persistent exchange splitting in a chiral helimagnet Cr1/3NbS2

Author

Qin, Na, Chen, Cheng, Du, Shiqiao, Du, Xian, Zhang, Xin, Yin, Zhongxu, Zhou, Jingsong, Xu, Runzhe, Gu, Xu, Zhang, Qinqin, Zhao, Wenxuan, Li, Yidian, Mo, Sung-Kwan, Liu, Zhongkai, Zhang, Shilei, Guo, Yanfeng, Tang, P. Z., Chen, Yulin, and Yang, Lexian

Subjects

Condensed Matter - Materials Science

Abstract

Using high-resolution angle-resolved photoemission spectroscopy (ARPES) and ab-initio calculation, we systematically investigate the electronic structure of the chiral helimagnet Cr1/3NbS2 and its temperature evolution. The comparison with NbS2 suggests that the electronic structure of Cr1/3NbS2 is strongly modified by the intercalation of Cr atoms. Our ab-initio calculation, consistent with experimental result, suggests strong hybridization between Nb- and Cr-derived states near the Fermi level. In the chiral helimagnetic state (below the Curie temperature Tc), we observe exchange splitting of the energy bands crossing EF, which follows the temperature evolution of the magnetic moment, suggesting an important role of the conduction electrons in the long-range magnetic ordering. Interestingly, the exchange splitting persists far above Tc with negligible temperature dependence, in drastic contrast to the itinerant ferromagnetism described by the Stoner model, indicating the existence of short-range magnetic order. Our results provide important insights into the microscopic mechanism of the chiral helimagnetic ordering in Cr1/3NbS2.

Published

2022

41. Dirac Nodal Line in Hourglass Semimetal Nb3SiTe6

Author

Liu, Ro-Ya, Huang, Angus, Sankar, Raman, Hlevyack, Joseph Andrew, Su, Chih-Chuan, Weng, Shih-Chang, Lin, Meng-Kai, Chen, Peng, Cheng, Cheng-Maw, Denlinger, Jonathan D, Mo, Sung-Kwan, Fedorov, Alexei V, Chang, Chia-Seng, Jeng, Horng-Tay, Chuang, Tien-Ming, and Chiang, Tai-Chang

Subjects

Physical Sciences, Condensed Matter Physics, hourglass fermions, Dirac nodal loop, nonsymmorphic crystals, glide-mirror symmetry, photoemission, first-principles band structures, Nanoscience & Nanotechnology

Abstract

Glide-mirror symmetry in nonsymmorphic crystals can foster the emergence of novel hourglass nodal loop states. Here, we present spectroscopic signatures from angle-resolved photoemission of a predicted topological hourglass semimetal phase in Nb3SiTe6. Linear band crossings are observed at the zone boundary of Nb3SiTe6, which could be the origin of the nontrivial Berry phase and are consistent with a predicted glide quantum spin Hall effect; such linear band crossings connect to form a nodal loop. Furthermore, the saddle-like Fermi surface of Nb3SiTe6 observed in our results helps unveil linear band crossings that could be missed. In situ alkali-metal doping of Nb3SiTe6 also facilitated the observation of other band crossings and parabolic bands at the zone center correlated with accidental nodal loop states. Overall, our results complete the system's band structure, help explain prior Hall measurements, and suggest the existence of a nodal loop at the zone center of Nb3SiTe6.

Published

2023

42. Enhanced thermoelectric performance of SnSe by controlled vacancy population

Author

Lee, Ji-Eun, Kim, Kyoo, Nguyen, Van Quang, Hwang, Jinwoong, Denlinger, Jonathan D, Min, Byung Il, Cho, Sunglae, Ryu, Hyejin, Hwang, Choongyu, and Mo, Sung-Kwan

Subjects

Engineering, Nanotechnology, Affordable and Clean Energy, Thermoelectric, Defect engineering, Electron band structure, Vacancy, SnSe

Abstract

The thermoelectric performance of SnSe strongly depends on its low-energy electron band structure that provides high density of states in a narrow energy window due to the multi-valley valence band maximum (VBM). Angle-resolved photoemission spectroscopy measurements, in conjunction with first-principles calculations, reveal that the binding energy of the VBM of SnSe is tuned by the population of Sn vacancy, which is determined by the cooling rate during the sample growth. The VBM shift follows precisely the behavior of the thermoelectric power factor, while the effective mass is barely modified upon changing the population of Sn vacancies. These findings indicate that the low-energy electron band structure is closely correlated with the high thermoelectric performance of hole-doped SnSe, providing a viable route toward engineering the intrinsic defect-induced thermoelectric performance via the sample growth condition without an additional ex-situ process.

Published

2023

43. Signatures of the exciton gas phase and its condensation in monolayer 1T-ZrTe2

Author

Song, Yekai, Jia, Chunjing, Xiong, Hongyu, Wang, Binbin, Jiang, Zhicheng, Huang, Kui, Hwang, Jinwoong, Li, Zhuojun, Hwang, Choongyu, Liu, Zhongkai, Shen, Dawei, Sobota, Jonathan A, Kirchmann, Patrick, Xue, Jiamin, Devereaux, Thomas P, Mo, Sung-Kwan, Shen, Zhi-Xun, and Tang, Shujie

Subjects

Quantum Physics, Physical Sciences, Condensed Matter Physics

Abstract

The excitonic insulator (EI) is a Bose-Einstein condensation (BEC) of excitons bound by electron-hole interaction in a solid, which could support high-temperature BEC transition. The material realization of EI has been challenged by the difficulty of distinguishing it from a conventional charge density wave (CDW) state. In the BEC limit, the preformed exciton gas phase is a hallmark to distinguish EI from conventional CDW, yet direct experimental evidence has been lacking. Here we report a distinct correlated phase beyond the 2×2 CDW ground state emerging in monolayer 1T-ZrTe2 and its investigation by angle-resolved photoemission spectroscopy (ARPES) and scanning tunneling microscopy (STM). The results show novel band- and energy-dependent folding behavior in a two-step process, which is the signatures of an exciton gas phase prior to its condensation into the final CDW state. Our findings provide a versatile two-dimensional platform that allows tuning of the excitonic effect.

Published

2023

44. Spectral Evidence for Unidirectional Charge Density Wave in Detwinned BaNi$_2$As$_2$

Author

Guo, Yucheng, Klemm, Mason, Oh, Ji Seop, Xie, Yaofeng, Lei, Bing-Hua, Gorovikov, Sergey, Pedersen, Tor, Michiardi, Matteo, Zhdanovich, Sergey, Damascelli, Andrea, Denlinger, Jonathan, Hashimoto, Makoto, Lu, Donghui, Mo, Sung-Kwan, Moore, Rob G., Birgeneau, Robert J., Singh, David J., Dai, Pengcheng, and Yi, Ming

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

The emergence of unconventional superconductivity in proximity to intertwined electronic orders is especially relevant in the case of iron-based superconductors. Such order consists of an electronic nematic order and a spin density wave in these systems. BaNi$_2$As$_2$, like its well-known iron-based analog BaFe$_2$As$_2$, also hosts a symmetry-breaking structural transition that is coupled to a unidirectional charge density wave (CDW), providing a novel platform to study intertwined orders. Here, through a systematic angle-resolved photoemission spectroscopy study combined with a detwinning $B_1g$ uniaxial strain, we identify distinct spectral evidence of band evolution due to the structural transition as well as CDW-induced band folding. In contrast to the nematicity and spin density wave in BaFe$_2$As$_2$, the structural and CDW order parameters in BaNi$_2$As$_2$ are observed to be strongly coupled and do not separate in the presence of uniaxial strain. Our measurements point to a likely lattice origin of the CDW in BaNi$_2$As$_2$., Comment: 6 pages, 4 figures

Published

2022

45. Observation of Dimension-Crossover of a Tunable 1D Dirac Fermion in Topological Semimetal NbSi$_x$Te$_2$

Author

Zhang, Jing, Lv, Yangyang, Feng, Xiaolong, Liang, Aiji, Xia, Wei, Mo, Sung-Kwan, Chen, Cheng, Xue, Jiamin, Yang, Shengyuan A., Yang, Lexian, Guo, Yanfeng, Chen, Yanbin, Chen, Yulin, and Liu, Zhongkai

Subjects

Condensed Matter - Materials Science

Abstract

Condensed matter systems in low dimensions exhibit emergent physics that does not exist in three dimensions. When electrons are confined to one dimension (1D), some significant electronic states appear, such as charge density wave, spin-charge separations and Su-Schrieffer-Heeger (SSH) topological state. However, a clear understanding of how the 1D electronic properties connects with topology is currently lacking. Here we systematically investigated the characteristic 1D Dirac fermion electronic structure originated from the metallic NbTe$_2$ chains on the surface of the composition-tunable layered compound NbSi$_x$Te$_2$ ($x$ = 0.40 and 0.43) using angle-resolved photoemission spectroscopy. We found the Dirac fermion forms a Dirac nodal line structure protected by the combined $\widetilde{\mathcal{M}}{\rm_y}$ and time-reversal symmetry T and proves the NbSi$_x$Te$_2$ system as a topological semimetal, in consistent with the ab-initio calculations. As $x$ decreases, the interaction between adjacent NbTe2 chains increases and Dirac fermion goes through a dimension-crossover from 1D to 2D, as evidenced by the variation of its Fermi surface and Fermi velocity across the Brillouin zone in consistence with a Dirac SSH model. Our findings demonstrate a tunable 1D Dirac electron system, which offers a versatile platform for the exploration of intriguing 1D physics and device applications., Comment: 24 pages, 4 figures, to be published in npj Quantum Materials

Published

2022

46. Direct Visualization and Manipulation of Tunable Quantum Well State in Semiconducting Nb2SiTe4

Author

Zhang, Jing, Yang, Zhilong, Liu, Shuai, Xia, Wei, Zhu, Tongshuai, Chen, Cheng, Wang, Chengwei, Wang, Meixiao, Mo, Sung-Kwan, Yang, Lexian, Kou, Xufeng, Guo, Yanfeng, Zhang, Haijun, Liu, Zhongkai, and Chen, Yulin

Subjects

Condensed Matter - Materials Science

Abstract

Quantum well states (QWSs) can form at the surface or interfaces of materials with confinement potential. They have broad applications in electronic and optical devices such as high mobility electron transistor, photodetector and quantum well laser. The properties of the QWSs are usually the key factors for the performance of the devices. However, direct visualization and manipulation of such states are in general challenging. In this work, by using angle-resolved photoemission spectroscopy (ARPES) and scanning tunneling microscopy/spectroscopy (STM/STS), we directly probe the QWSs generated on the vacuum interface of a narrow band gap semiconductor Nb2SiTe4. Interestingly, the position and splitting of QWSs could be easily manipulated via potassium (K) dosage onto the sample surface. Our results suggest Nb2SiTe4 to be an intriguing semiconductor system to study and engineer the QWSs, which has great potential in device applications., Comment: 28 pages, 5 figures

Published

2022

47. Nematic fluctuations in the non-superconducting iron pnictide BaFe$_{1.9-x}$Ni$_{0.1}$Cr$_{x}$As$_{2}$

Author

Gong, Dongliang, Yi, Ming, Wang, Meng, Xie, Tao, Zhang, Wenliang, Danilkin, Sergey, Deng, Guochu, Liu, Xinzhi, Park, Jitae T., Ikeuchi, Kazuhiko, Kamazawa, Kazuya, Mo, Sung-Kwan, Hashimoto, Makoto, Lu, Donghui, Zhang, Rui, Dai, Pengcheng, Birgeneau, Robert J., Li, Shiliang, and Luo, Huiqian

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Materials Science, Condensed Matter - Strongly Correlated Electrons

Abstract

The main driven force of the electronic nematic phase in iron-based superconductors is still under debate. Here, we report a comprehensive study on the nematic fluctuations in a non-superconducting iron pnictide system BaFe$_{1.9-x}$Ni$_{0.1}$Cr$_{x}$As$_{2}$ by electronic transport, angle-resolved photoemission spectroscopy (ARPES) and inelastic neutron scattering (INS) measurements. Previous neutron diffraction and transport measurements suggested that the collinear antiferromagnetism persists to $x=0.8$, with similar N\'{e}el temperature $T_N$ and structural transition temperature $T_s$ around 32 K, but the charge carriers change from electron type to hole type around $x=$ 0.5. In this study, we have found that the in-plane resistivity anisotropy also highly depends on the Cr dopings and the type of charge carriers. While ARPES measurements suggest possibly weak orbital anisotropy onset near $T_s$ for both $x=0.05$ and $x=0.5$ compounds, INS experiments reveal clearly different onset temperatures of low-energy spin excitation anisotropy, which is likely related to the energy scale of spin nematicity. These results suggest that the interplay between the local spins on Fe atoms and the itinerant electrons on Fermi surfaces is crucial to the nematic fluctuations of iron pnictides, where the orbital degree of freedom may behave differently from the spin degree of freedom, and the transport properties are intimately related to the spin dynamics., Comment: 12 pages, 8 figures. Frontiers in Physics: Topic "Nematicity in Iron-Based Superconductors"

Published

2022

48. Large-gap insulating dimer ground state in monolayer IrTe2

Author

Hwang, Jinwoong, Kim, Kyoo, Zhang, Canxun, Zhu, Tiancong, Herbig, Charlotte, Kim, Sooran, Kim, Bongjae, Zhong, Yong, Salah, Mohamed, El-Desoky, Mohamed M., Hwang, Choongyu, Shen, Zhi-Xun, Crommie, Michael F., and Mo, Sung-Kwan

Subjects

Condensed Matter - Materials Science

Abstract

Monolayers of two-dimensional van der Waals materials exhibit novel electronic phases distinct from their bulk due to the symmetry breaking and reduced screening in the absence of the interlayer coupling. In this work, we combine angle-resolved photoemission spectroscopy and scanning tunneling microscopy/spectroscopy to demonstrate the emergence of a unique insulating 2 x 1 dimer ground state in monolayer 1T-IrTe2 that has a large band gap in contrast to the metallic bilayer-to-bulk forms of this material. First-principles calculations reveal that phonon and charge instabilities as well as local bond formation collectively enhance and stabilize a charge-ordered ground state. Our findings provide important insights into the subtle balance of interactions having similar energy scales that occurs in the absence of strong interlayer coupling, which offers new opportunities to engineer the properties of 2D monolayers.

Published

2022

49. Evidence for a spinon Kondo effect in cobalt atoms on single-layer 1T-TaSe2

Author

Chen, Yi, He, Wen-Yu, Ruan, Wei, Hwang, Jinwoong, Tang, Shujie, Lee, Ryan L, Wu, Meng, Zhu, Tiancong, Zhang, Canxun, Ryu, Hyejin, Wang, Feng, Louie, Steven G, Shen, Zhi-Xun, Mo, Sung-Kwan, Lee, Patrick A, and Crommie, Michael F

Subjects

Quantum Physics, Physical Sciences, Condensed Matter Physics, MSD-General, Mathematical Sciences, Fluids & Plasmas, Mathematical sciences, Physical sciences

Abstract

Quantum spin liquids are highly entangled, disordered magnetic states that are expected to arise in frustrated Mott insulators and to exhibit exotic fractional excitations such as spinons and chargons. Despite being electrical insulators, some quantum spin liquids are predicted to exhibit gapless itinerant spinons that yield metallic behaviour in the charge-neutral spin channel. We deposited isolated magnetic atoms onto single-layer 1T-TaSe2, a candidate gapless spin liquid, to probe how itinerant spinons couple to impurity spin centres. Using scanning tunnelling spectroscopy, we observe the emergence of new, impurity-induced resonance peaks at the 1T-TaSe2 Hubbard band edges when cobalt adatoms are positioned to have maximal spatial overlap with the local charge distribution. These resonance peaks disappear when the spatial overlap is reduced or when the magnetic impurities are replaced with nonmagnetic impurities. Theoretical simulations of a modified Anderson impurity model show that the observed peaks are consistent with a Kondo resonance induced by spinons combined with spin-charge binding effects that arise due to fluctuations of an emergent gauge field.

Published

2022

50. A Novel 19$\sqrt {19} $ × 19$\sqrt {19} $ Superstructure in Epitaxially Grown 1T‐TaTe2

Author

Hwang, Jinwoong, Jin, Yeongrok, Zhang, Canxun, Zhu, Tiancong, Kim, Kyoo, Zhong, Yong, Lee, Ji‐Eun, Shen, Zongqi, Chen, Yi, Ruan, Wei, Ryu, Hyejin, Hwang, Choongyu, Lee, Jaekwang, Crommie, Michael F, Mo, Sung‐Kwan, and Shen, Zhi‐Xun

Subjects

Physical Sciences, Condensed Matter Physics, angle-resolved photoemission, charge density waves, molecular beam epitaxy, tantalum ditellurides, transition metal dichalcogenides, Chemical Sciences, Engineering, Nanoscience & Nanotechnology, Chemical sciences, Physical sciences

Abstract

The spontaneous formation of electronic orders is a crucial element for understanding complex quantum states and engineering heterostructures in 2D materials. A novel 19 $\sqrt {19} $ × 19 $\sqrt {19} $ charge order in few-layer-thick 1T-TaTe2 transition metal dichalcogenide films grown by molecular beam epitaxy, which has not been realized, is report. The photoemission and scanning probe measurements demonstrate that monolayer 1T-TaTe2 exhibits a variety of metastable charge density wave orders, including the 19 $\sqrt {19} $ × 19 $\sqrt {19} $ superstructure, which can be selectively stabilized by controlling the post-growth annealing temperature. Moreover, it is found that only the 19 $\sqrt {19} $ × 19 $\sqrt {19} $ order persists in 1T-TaTe2 films thicker than a monolayer, up to 8 layers. The findings identify the previously unrealized novel electronic order in a much-studied transition metal dichalcogenide and provide a viable route to control it within the epitaxial growth process.

Published

2022