Your search keyword '"Hasan, M. Zahid"' showing total 811 results

1. A Predictive First-Principles Framework of Chiral Charge Density Waves

Author

Shao, Sen, Chiu, Wei-Chi, Hossain, Md Shafayat, Hou, Tao, Wang, Naizhou, Belopolski, Ilya, Zhao, Yilin, Ni, Jinyang, Zhang, Qi, Li, Yongkai, Liu, Jinjin, Yahyavi, Mohammad, Jin, Yuanjun, Feng, Qiange, Cui, Peiyuan, Zhang, Cheng-Long, Yao, Yugui, Wang, Zhiwei, Yin, Jia-Xin, Xu, Su-Yang, Ma, Qiong, Gao, Wei-bo, Bansil, Arun, Hasan, M. Zahid, and Chang, Guoqing

Subjects

Condensed Matter - Materials Science

Abstract

Implementing and tuning chirality is fundamental in physics, chemistry, and material science. Chiral charge density waves (CDWs), where chirality arises from correlated charge orders, are attracting intense interest due to their exotic transport and optical properties. However, a general framework for predicting chiral CDW materials is lacking, primarily because the underlying mechanisms remain elusive. Here, we address this challenge by developing the first comprehensive predictive framework, systematically identifying chiral CDW materials via first-principles calculations. The key lies in the previously overlooked phase difference of the CDW Q-vectors between layers, which is linked to opposite collective atomic displacements across different layers. This phase difference induces a spiral arrangement of the Q-vectors, ultimately giving rise to a chiral structure in real space. We validate our framework by applying it to the kagome lattice AV$_{3}$Sb$_{5}$ (A = K, Rb, Cs), successfully predicting emergent structural chirality. To demonstrate the generality of our approach, we extend it to predict chiral CDWs in the triangular-lattice NbSe$_{2}$. Beyond material predictions, our theory uncovers a universal and unprecedented Hall effect in chiral CDW materials, occurring without external magnetic fields or intrinsic magnetization. Our experiments on CsV$_{3}$Sb$_{5}$ confirm this prediction, observing a unique signature where the Hall conductivity's sign reverses when the input current is reversed, a phenomenon distinct from known Hall effects. Our findings elucidate the mechanisms behind chiral CDWs and open new avenues for discovering materials with unconventional quantum properties, with potential applications in next-generation electronic and spintronic devices.

Published

2024

2. Pomeranchuk instability of a topological crystal

Author

Hossain, Md Shafayat, Muhammad, Zahir, Islam, Rajibul, Cheng, Zi-Jia, Jiang, Yu-Xiao, Litskevich, Maksim, Cochran, Tyler A., Yang, Xian P., Kim, Byunghoon, Xue, Fei, Perakis, Ilias E., Zhao, Weisheng, Kargarian, Mehdi, Balicas, Luis, Neupert, Titus, and Hasan, M. Zahid

Subjects

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

Abstract

Nematic quantum fluids appear in strongly interacting systems and break the rotational symmetry of the crystallographic lattice. In metals, this is connected to a well-known instability of the Fermi liquid-the Pomeranchuk instability. Using scanning tunneling microscopy, we identified this instability in a highly unusual setting: on the surface of an elemental topological metal, arsenic. By directly visualizing the Fermi surface of the surface state via scanning tunneling spectroscopy and photoemission spectroscopy, we find that the Fermi surface gets deformed and becomes elliptical at the energies where the nematic state is present. Known instances of nematic instability typically need van-Hove singularities or multi-orbital physics as drivers. In contrast, the surface states of arsenic are essentially indistinguishable from well-confined isotropic Rashba bands near the Fermi level, rendering our finding the first realization of Pomeranchuk instability of the topological surface state.

Published

2024

3. Perspective: imaging atomic step geometry to determine surface terminations of kagome materials and beyond

Author

Liu, Guowei, Yang, Tianyu, Jiang, Yu-Xiao, Hossain, Shafayat, Deng, Hanbin, Hasan, M. Zahid, and Yin, Jia-Xin

Subjects

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

Abstract

Here we review scanning tunneling microscopy research on the surface determination for various types of kagome materials, including 11-type (CoSn, FeSn, FeGe), 32-type (Fe3Sn2), 13-type (Mn3Sn), 135-type (AV3Sb5, A = K, Rb, Cs), 166-type (TbMn6Sn6, YMn6Sn6 and ScV6Sn6), and 322-type (Co3Sn2S2 and Ni3In2Se2). We first demonstrate that the measured step height between different surfaces typically deviates from the expected value of +-0.4~0.8A, which is owing to the tunneling convolution effect with electronic states and becomes a serious issue for Co3Sn2S2 where the expected Sn-S interlayer distance is 0.6A. Hence, we put forward a general methodology for surface determination as atomic step geometry imaging, which is fundamental but also experimentally challenging to locate the step and to image with atomic precision. We discuss how this method can be used to resolve the surface termination puzzle in Co3Sn2S2. This method provides a natural explanation for the existence of adatoms and vacancies, and beyond using unknown impurity states, we propose and use designer layer-selective substitutional chemical markers to confirm the validity of this method. Finally, we apply this method to determine the surface of a new kagome material Ni3In2Se2, as a cousin of Co3Sn2S2, and we image the underlying kagome geometry on the determined Se surface above the kagome layer, which directly visualizes the p-d hybridization physics. We emphasize that this general method does not rely on theory, but the determined surface identity can provide guidelines for first-principles calculations with adjustable parameters on the surface-dependent local density of states and quasi-particle interference patterns.

Published

2024

4. A topological Hund nodal line antiferromagnet

Author

Yang, Xian P., Yao, Yueh-Ting, Zheng, Pengyu, Guan, Shuyue, Zhou, Huibin, Cochran, Tyler A., Lin, Che-Min, Yin, Jia-Xin, Zhou, Xiaoting, Cheng, Zi-Jia, Li, Zhaohu, Shi, Tong, Hossain, Md Shafayat, Chi, Shengwei, Belopolski, Ilya, Jiang, Yu-Xiao, Litskevich, Maksim, Xu, Gang, Tian, Zhaoming, Bansil, Arun, Yin, Zhiping, Jia, Shuang, Chang, Tay-Rong, and Hasan, M. Zahid

Subjects

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

Abstract

The interplay of topology, magnetism, and correlations gives rise to intriguing phases of matter. In this study, through state-of-the-art angle-resolved photoemission spectroscopy, density functional theory and dynamical mean-field theory calculations, we visualize a fourfold degenerate Dirac nodal line at the boundary of the bulk Brillouin zone in the antiferromagnet YMn2Ge2. We further demonstrate that this gapless, antiferromagnetic Dirac nodal line is enforced by the combination of magnetism, space-time inversion symmetry and nonsymmorphic lattice symmetry. The corresponding drumhead surface states traverse the whole surface Brillouin zone. YMn2Ge2 thus serves as a platform to exhibit the interplay of multiple degenerate nodal physics and antiferromagnetism. Interestingly, the magnetic nodal line displays a d-orbital dependent renormalization along its trajectory in momentum space, thereby manifesting Hund coupling. Our findings offer insights into the effect of electronic correlations on magnetic Dirac nodal lines, leading to an antiferromagnetic Hund nodal line.

Published

2024

5. Insulator-to-Metal Transition and Isotropic Gigantic Magnetoresistance in Layered Magnetic Semiconductors

Author

Acharya, Gokul, Neupane, Bimal, Hsu, Chia-Hsiu, Yang, Xian P., Graf, David, Choi, Eun Sang, Pandey, Krishna, Nabi, Md Rafique Un, Chhetri, Santosh Karki, Basnet, Rabindra, Rahman, Sumaya, Wang, Jian, Hu, Zhengxin, Da, Bo, Churchill, Hugh, Chang, Guoqing, Hasan, M. Zahid, Wang, Yuanxi, and Hu, Jin

Subjects

Condensed Matter - Materials Science

Abstract

Magnetotransport, the response of electrical conduction to external magnetic field, acts as an important tool to reveal fundamental concepts behind exotic phenomena and plays a key role in enabling spintronic applications. Magnetotransport is generally sensitive to magnetic field orientations. In contrast, efficient and isotropic modulation of electronic transport, which is useful in technology applications such as omnidirectional sensing, is rarely seen, especially for pristine crystals. Here we propose a strategy to realize extremely strong modulation of electron conduction by magnetic field which is independent of field direction. GdPS, a layered antiferromagnetic semiconductor with resistivity anisotropies, supports a field-driven insulator-to-metal transition with a paradoxically isotropic gigantic negative magnetoresistance insensitive to magnetic field orientations. This isotropic magnetoresistance originates from the combined effects of a near-zero spin-orbit coupling of Gd3+-based half-filling f-electron system and the strong on-site f-d exchange coupling in Gd atoms. Our results not only provide a novel material system with extraordinary magnetotransport that offers a missing block for antiferromagnet-based ultrafast and efficient spintronic devices, but also demonstrate the key ingredients for designing magnetic materials with desired transport properties for advanced functionalities., Comment: 44 pages, 18 figures

Published

2024

6. Van-Hove annihilation and nematic instability on a Kagome lattice

Author

Jiang, Yu-Xiao, Shao, Sen, Xia, Wei, Denner, M. Michael, Ingham, Julian, Hossain, Md Shafayat, Qiu, Qingzheng, Zheng, Xiquan, Chen, Hongyu, Cheng, Zi-Jia, Yang, Xian P., Kim, Byunghoon, Yin, Jia-Xin, Zhang, Songbo, Litskevich, Maksim, Zhang, Qi, Cochran, Tyler A., Peng, Yingying, Chang, Guoqing, Guo, Yanfeng, Thomale, Ronny, Neupert, Titus, and Hasan, M. Zahid

Subjects

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

Abstract

Novel states of matter arise in quantum materials due to strong interactions among electrons. A nematic phase breaks the point group symmetry of the crystal lattice and is known to emerge in correlated materials. Here we report the observation of an intra-unit-cell nematic order and signatures of Pomeranchuk instability in the Kagome metal ScV6Sn6. Using scanning tunneling microscopy and spectroscopy, we reveal a stripe-like nematic order breaking the crystal rotational symmetry within the Kagome lattice itself. Moreover, we identify a set of van Hove singularities adhering to the Kagome layer electrons, which appear along one direction of the Brillouin zone while being annihilated along other high-symmetry directions, revealing a rotational symmetry breaking. Via detailed spectroscopic maps, we further observe an elliptical deformation of Fermi surface, which provides direct evidence for an electronically mediated nematic order. Our work not only bridges the gap between electronic nematicity and Kagome physics, but also sheds light on the potential mechanism for realizing symmetry-broken phases in correlated electron systems., Comment: 19 pages, 5 figures

Published

2024

7. A topological Hund nodal line antiferromagnet

Author

Yang, Xian P, Yao, Yueh-Ting, Zheng, Pengyu, Guan, Shuyue, Zhou, Huibin, Cochran, Tyler A, Lin, Che-Min, Yin, Jia-Xin, Zhou, Xiaoting, Cheng, Zi-Jia, Li, Zhaohu, Shi, Tong, Hossain, Md Shafayat, Chi, Shengwei, Belopolski, Ilya, Jiang, Yu-Xiao, Litskevich, Maksim, Xu, Gang, Tian, Zhaoming, Bansil, Arun, Yin, Zhiping, Jia, Shuang, Chang, Tay-Rong, and Hasan, M Zahid

Subjects

Physical Sciences, Condensed Matter Physics

Abstract

The interplay of topology, magnetism, and correlations gives rise to intriguing phases of matter. In this study, through state-of-the-art angle-resolved photoemission spectroscopy, density functional theory, and dynamical mean-field theory calculations, we visualize a fourfold degenerate Dirac nodal line at the boundary of the bulk Brillouin zone in the antiferromagnet YMn2Ge2. We further demonstrate that this gapless, antiferromagnetic Dirac nodal line is enforced by the combination of magnetism, space-time inversion symmetry, and nonsymmorphic lattice symmetry. The corresponding drumhead surface states traverse the whole surface Brillouin zone. YMn2Ge2 thus serves as a platform to exhibit the interplay of multiple degenerate nodal physics and antiferromagnetism. Interestingly, the magnetic nodal line displays a d-orbital dependent renormalization along its trajectory in momentum space, thereby manifesting Hund's coupling. Our findings offer insights into the effect of electronic correlations on magnetic Dirac nodal lines, leading to an antiferromagnetic Hund nodal line.

Published

2024

8. Untangle charge-order dependent bulk states from surface effects in a topological kagome metal ScV$_6$Sn$_6$

Author

Cheng, Zi-Jia, Shao, Sen, Kim, Byunghoon, Cochran, Tyler A., Yang, Xian P., Yi, Changjiang, Jiang, Yu-Xiao, Zhang, Junyi, Hossain, Md Shafayat, Roychowdhury, Subhajit, Yilmaz, Turgut, Vescovo, Elio, Fedorov, Alexei, Chandra, Shekhar, Felser, Claudia, Chang, Guoqing, and Hasan, M. Zahid

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Kagome metals with charge density wave (CDW) order exhibit a broad spectrum of intriguing quantum phenomena. The recent discovery of the novel kagome CDW compound ScV$_6$Sn$_6$ has spurred significant interest. However, understanding the interplay between CDW and the bulk electronic structure has been obscured by a profusion of surface states and terminations in this quantum material. Here, we employ photoemission spectroscopy and potassium dosing to elucidate the complete bulk band structure of ScV$_6$Sn$_6$, revealing multiple van Hove singularities near the Fermi level. We surprisingly discover a robust spin-polarized topological Dirac surface resonance state at the M point within the two-fold van Hove singularities. Assisted by the first-principle calculations, the temperature dependence of the $k_z$- resolved ARPES spectrum provides unequivocal evidence for the proposed $\sqrt{3}$$\times$$\sqrt{3}$$\times3$ charge order over other candidates. Our work not only enhances the understanding of the CDW-dependent bulk and surface states in ScV$_6$Sn$_6$ but also establishes an essential foundation for potential manipulation of the CDW order in kagome materials., Comment: To appear in PRB

Published

2024

9. Discovery of a Topological Charge Density Wave

Author

Litskevich, Maksim, Hossain, Md Shafayat, Zhang, Songbo, Cheng, Zi-Jia, Guin, Satya N., Kumar, Nitesh, Shekhar, Chandra, Wang, Zhiwei, Li, Yongkai, Chang, Guoqing, Yin, Jia-Xin, Zhang, Qi, Cheng, Guangming, Jiang, Yu-Xiao, Cochran, Tyler A., Shumiya, Nana, Yang, Xian P., Multer, Daniel, Liu, Xiaoxiong, Yao, Nan, Yao, Yugui, Felser, Claudia, Neupert, Titus, and Hasan, M. Zahid

Subjects

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

Abstract

Charge density waves (CDWs) appear in numerous condensed matter platforms, ranging from high-Tc superconductors to quantum Hall systems. Despite such ubiquity, there has been a lack of direct experimental study on boundary states that can uniquely stem from the charge order. Here, using scanning tunneling microscopy, we directly visualize the bulk and boundary phenomenology of CDW in a topological material, Ta2Se8I. Below the transition temperature (TCDW = 260 K), tunneling spectra on an atomically resolved lattice reveal a large insulating gap in the bulk and on the surface, exceeding 500 meV, surpassing predictions from standard weakly-coupled mean-field theory. Spectroscopic imaging confirms the presence of CDW, with LDOS maxima at the conduction band corresponding to the LDOS minima at the valence band, thus revealing a {\pi} phase difference in the respective CDW order. Concomitantly, at a monolayer step edge, we detect an in-gap boundary mode with modulations along the edge that match the CDW wavevector along the edge. Intriguingly, the phase of the edge state modulation shifts by {\pi} within the charge order gap, connecting the fully gapped bulk (and surface) conduction and valence bands via a smooth energy-phase relation. This bears similarity to the topological spectral flow of edge modes, where the boundary modes bridge the gapped bulk modes in energy and momentum magnitude but in Ta2Se8I, the connectivity distinctly occurs in energy and momentum phase. Notably, our temperature-dependent measurements indicate a vanishing of the insulating gap and the in-gap edge state above TCDW, suggesting their direct relation to CDW. The theoretical analysis also indicates that the observed boundary mode is topological and linked to CDW., Comment: Nature Physics (2024); in press

Published

2024

10. Tunable Topological Phase Transitions in a Piezoelectric Janus Monolayer

Author

Tanisha, Tanshia Tahreen, Hossain, Md. Shafayat, Hiramony, Nishat Tasnim, Rasul, Ashiqur, Hasan, M. Zahid, and Khosru, Quazi D. M.

Subjects

Condensed Matter - Materials Science

Abstract

Quantum Spin Hall (QSH) insulators represent a quintessential example of a topological phase of matter, characterized by a conducting edge mode within a bulk energy gap. The pursuit of a tunable QSH state stands as a pivotal objective in the development of QSH-based topological devices. In this study, we employ first-principles calculations to identify three strain-tunable QSH insulators based on monolayer MAlGaTe4 (where M represents Mg, Ca, or Sr). These monolayers exhibit dynamic stability, with no imaginary modes detected in their phonon dispersion. Additionally, they possess piezoelectric properties, rendering them amenable to strain-induced tuning. While MgAlGaTe4 is a normal insulator under zero strain, it transitions into the QSH phase when subjected to external strain. Conversely, CaAlGaTe4 and SrAlGaTe4 already exhibit the QSH phase at zero strain. Intriguingly, upon the application of biaxial strain, these two compounds undergo phase transitions, encompassing metallic (M), normal/trivial insulator (NI), and topological insulator (TI) phases, thereby illustrating their strain-tunable electronic and topological properties. (Ca, Sr)AlGaTe4, in particular, undergo M-TI/TI-M transitions under applied strain, while MgAlGaTe4 additionally experiences an M-NI/NI-M transition, signifying it as a material featuring a metal-insulator transition (MIT). Remarkably, the observation of metal-trivial insulator-topological insulator transitions in MgAlGaTe4 introduces it as a unique material platform in which both MIT and topological phase transitions can be controlled through the same physical parameter. Our study thus introduces a novel material platform distinguished by highly strain-tunable electronic and topological properties, offering promising prospects for the development of next-generation, low-power topological devices., Comment: 37 pages, 13 figures

Published

2024

11. Discovery of a hybrid topological quantum state in an elemental solid

Author

Hossain, Md Shafayat, Schindler, Frank, Islam, Rajibul, Muhammad, Zahir, Jiang, Yu-Xiao, Cheng, Zi-Jia, Zhang, Qi, Hou, Tao, Chen, Hongyu, Litskevich, Maksim, Casas, Brian, Yin, Jia-Xin, Cochran, Tyler A., Yahyavi, Mohammad, Yang, Xian P., Balicas, Luis, Chang, Guoqing, Zhao, Weisheng, Neupert, Titus, and Hasan, M. Zahid

Subjects

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

Abstract

Topology and interactions are foundational concepts in the modern understanding of quantum matter. Their nexus yields three significant research directions: competition between distinct interactions, as in the multiple intertwined phases, interplay between interactions and topology that drives the phenomena in twisted layered materials and topological magnets, and the coalescence of multiple topological orders to generate distinct novel phases. The first two examples have grown into major areas of research, while the last example remains mostly untouched, mainly because of the lack of a material platform for experimental studies. Here, using tunneling microscopy, photoemission spectroscopy, and theoretical analysis, we unveil a "hybrid" and yet novel topological phase of matter in the simple elemental solid arsenic. Through a unique bulk-surface-edge correspondence, we uncover that arsenic features a conjoined strong and higher-order topology, stabilizing a hybrid topological phase. While momentum-space spectroscopy measurements show signs of topological surface states, real-space microscopy measurements unravel a unique geometry of topology-induced step edge conduction channels revealed on various forms of natural nanostructures on the surface. Using theoretical models, we show that the existence of gapless step edge states in arsenic relies on the simultaneous presence of both a nontrivial strong Z2 invariant and a nontrivial higher-order topological invariant, providing experimental evidence for hybrid topology and its realization in a single crystal. Our discovery highlights pathways to explore the interplay of different kinds of band topology and harness the associated topological conduction channels in future engineered quantum or nano-devices., Comment: Nature (2024); in press

Published

2024

12. Discovery of a topological exciton insulator with tunable momentum order

Author

Hossain, Md Shafayat, Cochran, Tyler A., Jiang, Yu-Xiao, Zhang, Songbo, Wu, Huangyu, Liu, Xiaoxiong, Zheng, Xiquan, Kim, Byunghoon, Cheng, Guangming, Zhang, Qi, Litskevich, Maksim, Zhang, Junyi, Cheng, Zi-Jia, Liu, Jinjin, Yin, Jia-Xin, Yang, Xian P., Denlinger, Jonathan, Tallarida, Massimo, Dai, Ji, Vescovo, Elio, Rajapitamahuni, Anil, Miao, Hu, Yao, Nan, Peng, Yingying, Yao, Yugui, Wang, Zhiwei, Balicas, Luis, Neupert, Titus, and Hasan, M. Zahid

Subjects

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

Abstract

Topology and correlations are fundamental concepts in modern physics, but their simultaneous occurrence within a single quantum phase is exceptionally rare. In this study, we present the discovery of such a phase of matter in Ta2Pd3Te5, a semimetal where the Coulomb interaction between electrons and holes leads to the spontaneous formation of excitonic bound states below T=100 K. Our spectroscopy unveils the development of an insulating gap stemming from the condensation of these excitons, thus giving rise to a highly sought-after correlated quantum phase known as the excitonic insulator. Remarkably, our scanning tunneling microscopy measurements reveal the presence of gapless boundary modes in the excitonic insulator state. Their magnetic field response and our theoretical calculations suggest a topological origin of these modes, rendering Ta2Pd3Te5 as the first experimentally identified topological excitonic insulator in a three-dimensional material not masked by any structural phase transition. Furthermore, our study uncovers a secondary excitonic instability below T=5 K, which differs from the primary one in having finite momentum. We observe unprecedented tunability of its wavevector by an external magnetic field. These findings unlock a frontier in the study of novel correlated topological phases of matter and their tunability.

Published

2023

13. Transport response of topological hinge modes in $\alpha$-Bi$_4$Br$_4$

Author

Hossain, Md Shafayat, Zhang, Qi, Wang, Zhiwei, Dhale, Nikhil, Liu, Wenhao, Litskevich, Maksim, Casas, Brian, Shumiya, Nana, Yin, Jia-Xin, Cochran, Tyler A., Li, Yongkai, Jiang, Yu-Xiao, Yang, Ying, Cheng, Guangming, Cheng, Zi-Jia, Yang, Xian P., Yao, Nan, Neupert, Titus, Balicas, Luis, Yao, Yugui, Lv, Bing, and Hasan, M. Zahid

Subjects

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

Abstract

Electronic topological phases are renowned for their unique properties, where conducting surface states exist on the boundary of an insulating three-dimensional bulk. While the transport response of the surface states has been extensively studied, the response of the topological hinge modes remains elusive. Here, we investigate a layered topological insulator $\alpha$-Bi$_4$Br$_4$, and provide the first evidence for quantum transport in gapless topological hinge states existing within the insulating bulk and surface energy gaps. Our magnetoresistance measurements reveal pronounced h/e periodic (where h denotes Planck's constant and e represents the electron charge) Aharonov-Bohm oscillation. The observed periodicity, which directly reflects the enclosed area of phase-coherent electron propagation, matches the area enclosed by the sample hinges, providing compelling evidence for the quantum interference of electrons circumnavigating around the hinges. Notably, the h/e oscillations evolve as a function of magnetic field orientation, following the interference paths along the hinge modes that are allowed by topology and symmetry, and in agreement with the locations of the hinge modes according to our scanning tunneling microscopy images. Remarkably, this demonstration of quantum transport in a topological insulator can be achieved using a flake geometry and we show that it remains robust even at elevated temperatures. Our findings collectively reveal the quantum transport response of topological hinge modes with both topological nature and quantum coherence, which can be directly applied to the development of efficient quantum electronic devices., Comment: Nature Physics, in press (2023)

Published

2023

14. Boundary modes of a charge density wave state in a topological material

Author

Litskevich, Maksim, Hossain, Md Shafayat, Zhang, Song-Bo, Cheng, Zi-Jia, Guin, Satya N., Kumar, Nitesh, Shekhar, Chandra, Wang, Zhiwei, Li, Yongkai, Chang, Guoqing, Yin, Jia-Xin, Zhang, Qi, Cheng, Guangming, Cochran, Tyler A., Shumiya, Nana, Jiang, Yu-Xiao, Yang, Xian P., Multer, Daniel, Liu, Xiaoxiong, Yao, Nan, Yao, Yugui, Felser, Claudia, Neupert, Titus, and Hasan, M. Zahid

Published

2024

15. Topological, or Non-topological? A Deep Learning Based Prediction

Author

Rasul, Ashiqur, Hossain, Md Shafayat, Dastider, Ankan Ghosh, Roy, Himaddri, Hasan, M. Zahid, and Khosru, Quazi D. M.

Subjects

Condensed Matter - Materials Science, Computer Science - Machine Learning

Abstract

Prediction and discovery of new materials with desired properties are at the forefront of quantum science and technology research. A major bottleneck in this field is the computational resources and time complexity related to finding new materials from ab initio calculations. In this work, an effective and robust deep learning-based model is proposed by incorporating persistent homology and graph neural network which offers an accuracy of 91.4% and an F1 score of 88.5% in classifying topological vs. non-topological materials, outperforming the other state-of-the-art classifier models. The incorporation of the graph neural network encodes the underlying relation between the atoms into the model based on their own crystalline structures and thus proved to be an effective method to represent and process non-euclidean data like molecules with a relatively shallow network. The persistent homology pipeline in the suggested neural network is capable of integrating the atom-specific topological information into the deep learning model, increasing robustness, and gain in performance. It is believed that the presented work will be an efficacious tool for predicting the topological class and therefore enable the high-throughput search for novel materials in this field., Comment: 13 pages, 8 figures

Published

2023

16. Observation of flat bands and Dirac cones in a pyrochlore lattice superconductor

Author

Huang, Jianwei, Setty, Chandan, Deng, Liangzi, You, Jing-Yang, Liu, Hongxiong, Shao, Sen, Oh, Ji Seop, Guo, Yucheng, Zhang, Yichen, Yue, Ziqin, Yin, Jia-Xin, Hashimoto, Makoto, Lu, Donghui, Gorovikov, Sergey, Dai, Pengcheng, Denlinger, Jonathan D, Allen, JW, Hasan, M Zahid, Feng, Yuan-Ping, Birgeneau, Robert J, Shi, Youguo, Chu, Ching-Wu, Chang, Guoqing, Si, Qimiao, and Yi, Ming

Subjects

Physical Sciences, Condensed Matter Physics, Engineering, Physical sciences

Abstract

Emergent phases often appear when the electronic kinetic energy is comparable to the Coulomb interactions. One approach to seek material systems as hosts of such emergent phases is to realize localization of electronic wavefunctions due to the geometric frustration inherent in the crystal structure, resulting in flat electronic bands. Recently, such efforts have found a wide range of exotic phases in the two-dimensional kagome lattice, including magnetic order, time-reversal symmetry breaking charge order, nematicity, and superconductivity. However, the interlayer coupling of the kagome layers disrupts the destructive interference needed to completely quench the kinetic energy. Here we demonstrate that an interwoven kagome network—a pyrochlore lattice—can host a three dimensional (3D) localization of electron wavefunctions. Meanwhile, the nonsymmorphic symmetry of the pyrochlore lattice guarantees all band crossings at the Brillouin zone X point to be 3D gapless Dirac points, which was predicted theoretically but never yet observed experimentally. Through a combination of angle-resolved photoemission spectroscopy, fundamental lattice model and density functional theory calculations, we investigate the novel electronic structure of a Laves phase superconductor with a pyrochlore sublattice, CeRu2. We observe evidence of flat bands originating from the Ce 4f orbitals as well as flat bands from the 3D destructive interference of the Ru 4d orbitals. We further observe the nonsymmorphic symmetry-protected 3D gapless Dirac cone at the X point. Our work establishes the pyrochlore structure as a promising lattice platform to realize and tune novel emergent phases intertwining topology and many-body interactions.

Published

2024

17. Publisher Correction: Phonon promoted charge density wave in topological kagome metal ScV6Sn6

Author

Hu, Yong, Ma, Junzhang, Li, Yinxiang, Jiang, Yuxiao, Gawryluk, Dariusz Jakub, Hu, Tianchen, Teyssier, Jérémie, Multian, Volodymyr, Yin, Zhouyi, Xu, Shuxiang, Shin, Soohyeon, Plokhikh, Igor, Han, Xinloong, Plumb, Nicholas C., Liu, Yang, Yin, Jia-Xin, Guguchia, Zurab, Zhao, Yue, Schnyder, Andreas P., Wu, Xianxin, Pomjakushina, Ekaterina, Hasan, M. Zahid, Wang, Nanlin, and Shi, Ming

Published

2024

18. Phonon promoted charge density wave in topological kagome metal ScV6Sn6

Author

Hu, Yong, Ma, Junzhang, Li, Yinxiang, Jiang, Yuxiao, Gawryluk, Dariusz Jakub, Hu, Tianchen, Teyssier, Jérémie, Multian, Volodymyr, Yin, Zhouyi, Xu, Shuxiang, Shin, Soohyeon, Plokhikh, Igor, Han, Xinloong, Plumb, Nicholas C., Liu, Yang, Yin, Jia-Xin, Guguchia, Zurab, Zhao, Yue, Schnyder, Andreas P., Wu, Xianxin, Pomjakushina, Ekaterina, Hasan, M. Zahid, Wang, Nanlin, and Shi, Ming

Published

2024

19. Quantum transport response of topological hinge modes

Author

Hossain, Md Shafayat, Zhang, Qi, Wang, Zhiwei, Dhale, Nikhil, Liu, Wenhao, Litskevich, Maksim, Casas, Brian, Shumiya, Nana, Yin, Jia-Xin, Cochran, Tyler A., Li, Yongkai, Jiang, Yu-Xiao, Zhang, Yuqi, Cheng, Guangming, Cheng, Zi-Jia, Yang, Xian P., Yao, Nan, Neupert, Titus, Balicas, Luis, Yao, Yugui, Lv, Bing, and Hasan, M. Zahid

Published

2024

20. A hybrid topological quantum state in an elemental solid

Author

Hossain, Md Shafayat, Schindler, Frank, Islam, Rajibul, Muhammad, Zahir, Jiang, Yu-Xiao, Cheng, Zi-Jia, Zhang, Qi, Hou, Tao, Chen, Hongyu, Litskevich, Maksim, Casas, Brian, Yin, Jia-Xin, Cochran, Tyler A., Yahyavi, Mohammad, Yang, Xian P., Balicas, Luis, Chang, Guoqing, Zhao, Weisheng, Neupert, Titus, and Hasan, M. Zahid

Published

2024

21. Observation of Flat Bands and Dirac Cones in a Pyrochlore Lattice Superconductor

Author

Huang, Jianwei, Setty, Chandan, Deng, Liangzi, You, Jing-Yang, Liu, Hongxiong, Shao, Sen, Oh, Ji Seop, Guo, Yucheng, Zhang, Yichen, Yue, Ziqin, Yin, Jia-Xin, Hashimoto, Makoto, Lu, Donghui, Gorovikov, Sergey, Dai, Pengcheng, Denlinger, Jonathan D., Hasan, M. Zahid, Feng, Yuan-Ping, Birgeneau, Robert J., Shi, Youguo, Chu, Ching-Wu, Chang, Guoqing, Si, Qimiao, and Yi, Ming

Subjects

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

Abstract

Emergent phases often appear when the electronic kinetic energy is comparable to the Coulomb interactions. One approach to seek material systems as hosts of such emergent phases is to realize localization of electronic wavefunctions due to the geometric frustration inherent in the crystal structure, resulting in flat electronic bands. Recently, such efforts have found a wide range of exotic phases in the two-dimensional kagome lattice, including magnetic order, time-reversal symmetry breaking charge order, nematicity, and superconductivity. However, the interlayer coupling of the kagome layers disrupts the destructive interference needed to completely quench the kinetic energy. Here we demonstrate that an interwoven kagome network-a pyrochlore lattice-can host a three dimensional (3D) localization of electron wavefunctions. Meanwhile, the nonsymmorphic symmetry of the pyrochlore lattice guarantees all band crossings at the Brillouin zone X point to be 3D gapless Dirac points, which was predicted theoretically but never yet observed experimentally. Through a combination of angle-resolved photoemission spectroscopy, fundamental lattice model and density functional theory calculations, we investigate the novel electronic structure of a Laves phase superconductor with a pyrochlore sublattice, CeRu$_2$. We observe flat bands originating from both the Ce 4$f$ orbitals as well as from the 3D destructive interference of the Ru 4$d$ orbitals. We further observe the nonsymmorphic symmetry-protected 3D gapless Dirac cones at the X point. Our work establishes the pyrochlore structure as a promising lattice platform to realize and tune novel emergent phases intertwining topology and many-body interactions., Comment: 27 pages, 4 figures

Published

2023

22. Phonon promoted charge density wave in topological kagome metal ScV$_{6}$Sn$_{6}$

Author

Hu, Yong, Ma, Junzhang, Li, Yinxiang, Gawryluk, Dariusz Jakub, Hu, Tianchen, Teyssier, Jérémie, Multian, Volodymyr, Yin, Zhouyi, Jiang, Yuxiao, Xu, Shuxiang, Shin, Soohyeon, Plokhikh, Igor, Han, Xinloong, Plumb, Nicholas Clark, Liu, Yang, Yin, Jiaxin, Guguchia, Zurab, Zhao, Yue, Schnyder, Andreas P., Wu, Xianxin, Pomjakushina, Ekaterina, Hasan, M. Zahid, Wang, Nanlin, and Shi, Ming

Subjects

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

Abstract

Charge density wave (CDW) orders in vanadium-based kagome metals have recently received tremendous attention due to their unique properties and intricate interplay with exotic correlated phenomena, topological and symmetry-breaking states. However, the origin of the CDW order remains a topic of debate. The discovery of ScV$_{6}$Sn$_{6}$, a vanadium-based bilayer kagome metal exhibiting an in-plane $\sqrt{3}$ x $\sqrt{3} $ $\textit{R}$30${\deg}$ CDW order with time-reversal symmetry breaking, provides a novel platform to explore the underlying mechanism behind the unconventional CDW. Here, we combine high-resolution angle-resolved photoemission spectroscopy, Raman scattering measurements and density functional theory to investigate the electronic structures and phonon modes of ScV$_{6}$Sn$_{6}$ and their evolution with temperature. We identify topologically nontrivial Dirac surface states and multiple van Hove singularities (VHSs) in the vicinity of the Fermi level, with one VHS near the K point exhibiting nesting wave vectors in proximity to the $\sqrt{3}$ x $\sqrt{3}$ $\textit{R}$30${\deg}$ CDW wave vector. Additionally, Raman measurements indicate a strong intrinsic electron-phonon coupling in ScV$_{6}$Sn$_{6}$, as evidenced by the presence of a two-phonon mode and a large frequency amplitude mode. Our findings highlight the fundamental role of lattice degrees of freedom in promoting the CDW in ScV$_{6}$Sn$_{6}$ and provide important insights into the fascinating correlation phenomena observed in kagome metals.

Published

2023

23. Theory for charge density wave and orbital-flux state in antiferromagnetic kagome metal FeGe

Author

Ma, Hai-Yang, Yin, Jia-Xin, Hasan, M. Zahid, and Liu, Jianpeng

Subjects

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

Abstract

In this work, we theoretically study the charge order and orbital magnetic properties of a new type of antiferromagnetic kagome metal FeGe. Based on first principles density functional theory (DFT) calculations, we have studied the electronic structures, Fermi-surface quantum fluctuations, as well as phonon properties of the antiferromagnetic kagome metal FeGe. We find that charge density wave emerges in such a system due to a subtle cooperation between electron-electron ($e$-$e$) interactions and electron-phonon couplings, which gives rise to an unusual scenario of interaction-triggered phonon instabilities, and eventually yields a charge density wave (CDW) state. We further show that, in the CDW phase, the ground-state current density distribution exhibits an intriguing star-of-David pattern, leading to flux density modulation. The orbital fluxes (or current loops) in this system emerges as a result of the subtle interplay between magnetism, lattice geometries, charge order, and spin-orbit coupling (SOC), which can be described by a simple, yet universal, tight-binding theory including a Kane-Mele type SOC term and a magnetic exchange interaction. We further study the origin of the peculiar step-edge states in FeGe, which shed light on the topological properties and correlation effects in this new type of kagome antiferromagnetic material.

Published

2023

24. Observation of Kondo lattice and Kondo-enhanced anomalous Hall effect in an itinerant ferromagnet

Author

Cheng, Zi-Jia, Huang, Yuqing, Zheng, Pengyu, Chen, Lei, Cochran, Tyler A., Hu, Haoyu, Yin, Jia-Xin, Yang, Xian P., Hossain, Md Shafayat, Zhang, Qi, Belopolski, Ilya, Liu, Rui, Cheng, Guangming, Hashimoto, Makoto, Lu, Donghui, Xu, Xitong, Zhou, Huibin, Ma, Wenlong, Chang, Guoqing, Yao, Nan, Yin, Zhiping, Hasan, M. Zahid, and Jia, Shuang

Subjects

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

Abstract

The interplay between Kondo screening and magnetic interactions is central to comprehending the intricate phases in heavy-fermion compounds. However, the role of the itinerant magnetic order, which is driven by the conducting (c) electrons, has been largely uncharted in the context of heavy-fermion systems due to the scarcity of material candidates. Here we demonstrate the coexistence of the coherent Kondo screening and d-orbital ferromagnetism in material system La$_{1-x}$Ce$_x$Co$_2$As$_2$, through comprehensive thermodynamic and electrical transport measurements. Additionally, using angle-resolved photoemission spectroscopy (ARPES), we further observe the f-orbit-dominated bands near the Fermi level ($E_f$) and signatures of the f-c hybridization below the magnetic transition temperature, providing strong evidence of Kondo lattice state in the presence of ferromagnetic order. Remarkably, by changing the ratio of Ce/La, we observe a substantial enhancement of the anomalous Hall effect (AHE) in the Kondo lattice regime. The value of the Hall conductivity quantitatively matches with the first-principle calculation that optimized with our ARPES results and can be attributed to the large Berry curvature (BC) density engendered by the topological nodal rings composed of the Ce-4f and Co-3d orbitals at $E_f$. Our findings point to the realization of a new platform for exploring correlation-driven topological responses in a novel Kondo lattice environment., Comment: 4 Figs and 22 pages. This is the submitted version and the work will be presented in March meeting (section T19). All comments are welcome!

Published

2023

25. Optical bulk-boundary dichotomy in a quantum spin Hall insulator

Author

Han, Junfeng, Mao, Pengcheng, Chen, Hailong, Yin, Jia-Xin, Wang, Maoyuan, Chen, Dongyun, Li, Yongkai, Zheng, Jingchuan, Zhang, Xu, Ma, Dashuai, Ma, Qiong, Yu, Zhi-Ming, Zhou, Jinjian, Liu, Cheng-Cheng, Wang, Yeliang, Jia, Shuang, Weng, Yuxiang, Hasan, M. Zahid, Xiao, Wende, and Yao, Yugui

Subjects

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

Abstract

The bulk-boundary correspondence is a key concept in topological quantum materials. For instance, a quantum spin Hall insulator features a bulk insulating gap with gapless helical boundary states protected by the underlying Z2 topology. However, the bulk-boundary dichotomy and distinction are rarely explored in optical experiments, which can provide unique information about topological charge carriers beyond transport and electronic spectroscopy techniques. Here, we utilize mid-infrared absorption micro-spectroscopy and pump-probe micro-spectroscopy to elucidate the bulk-boundary optical responses of Bi4Br4, a recently discovered room-temperature quantum spin Hall insulator. Benefiting from the low energy of infrared photons and the high spatial resolution, we unambiguously resolve a strong absorption from the boundary states while the bulk absorption is suppressed by its insulating gap. Moreover, the boundary absorption exhibits a strong polarization anisotropy, consistent with the one-dimensional nature of the topological boundary states. Our infrared pump-probe microscopy further measures a substantially increased carrier lifetime for the boundary states, which reaches one nanosecond scale. The nanosecond lifetime is about one to two orders longer than that of most topological materials and can be attributed to the linear dispersion nature of the helical boundary states. Our findings demonstrate the optical bulk-boundary dichotomy in a topological material and provide a proof-of-principal methodology for studying topological optoelectronics., Comment: 26 pages, 4 figures

Published

2023

26. Anomalously high supercurrent density in a two-dimensional topological material

Author

Zhang, Qi, Hossain, Md Shafayat, Casas, Brian, Zheng, Wenkai, Cheng, Zi-Jia, Lai, Zhuangchai, Tu, Yi-Hsin, Chang, Guoqing, Yao, Yao, Li, Siyuan, Jiang, Yu-Xiao, Mardanya, Sougata, Chang, Tay-Rong, You, Jing-Yang, Feng, Yuan-Ping, Cheng, Guangming, Yin, Jia-Xin, Shumiya, Nana, Cochran, Tyler A., Yang, Xian P., Litskevich, Maksim, Yao, Nan, Watanabe, Kenji, Taniguchi, Takashi, Zhang, Hua, Balicas, Luis, and Hasan, M. Zahid

Subjects

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

Abstract

Ongoing advances in superconductors continue to revolutionize technology thanks to the increasingly versatile and robust availability of lossless supercurrent. In particular high supercurrent density can lead to more efficient and compact power transmission lines, high-field magnets, as well as high-performance nanoscale radiation detectors and superconducting spintronics. Here, we report the discovery of an unprecedentedly high superconducting critical current density (17 MA/cm2 at 0 T and 7 MA/cm2 at 8 T) in 1T'-WS2, exceeding those of all reported two-dimensional superconductors to date. 1T'-WS2 features a strongly anisotropic (both in- and out-of-plane) superconducting state that violates the Pauli paramagnetic limit signaling the presence of unconventional superconductivity. Spectroscopic imaging of the vortices further substantiates the anisotropic nature of the superconducting state. More intriguingly, the normal state of 1T'-WS2 carries topological properties. The band structure obtained via angle-resolved photoemission spectroscopy and first-principles calculations points to a Z2 topological invariant. The concomitance of topology and superconductivity in 1T'-WS2 establishes it as a topological superconductor candidate, which is promising for the development of quantum computing technology.

Published

2023

27. Coexistence of bulk-nodal and surface-nodeless Cooper pairings in a superconducting Dirac semimetal

Author

Yang, Xian P., Zhong, Yigui, Mardanya, Sougata, Cochran, Tyler A., Chapai, Ramakanta, Mine, Akifumi, Zhang, Junyi, Sánchez-Barriga, Jaime, Cheng, Zi-Jia, Clark, Oliver J., Yin, Jia- Xin, Blawat, Joanna, Cheng, Guangming, Belopolski, Ilya, Nagashima, Tsubaki, Sahand, Najafzadeh, Gao, Shiyuan, Yao, Nan, Bansil, Arun, Jin, Rongying, Chang, Tay-Rong, Shin, Shik, Okazaki, Kozo, and Hasan, M. Zahid

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Strongly Correlated Electrons

Abstract

The interplay of nontrivial topology and superconductivity in condensed matter physics gives rise to exotic phenomena. However, materials are extremely rare where it is possible to explore the full details of the superconducting pairing. Here, we investigate the momentum dependence of the superconducting gap distribution in a novel Dirac material PdTe. Using high resolution, low temperature photoemission spectroscopy, we establish it as a spin-orbit coupled Dirac semimetal with the topological Fermi arc crossing the Fermi level on the (010) surface. This spin-textured surface state exhibits a fully gapped superconducting Cooper pairing structure below Tc~4.5K. Moreover, we find a node in the bulk near the Brillouin zone boundary, away from the topological Fermi arc.These observations not only demonstrate the band resolved electronic correlation between topological Fermi arc states and the way it induces Cooper pairing in PdTe, but also provide a rare case where surface and bulk states host a coexistence of nodeless and nodal gap structures enforced by spin-orbit coupling., Comment: accepted by PRL

Published

2023

28. Transverse circular photogalvanic effect associated with Lorentz-violating Weyl fermions

Author

Yahyavi, Mohammad, Jin, Yuanjun, Zhao, Yilin, Cheng, Zi-Jia, Cochran, Tyler A., Hung, Yi-Chun, Chang, Tay-Rong, Ma, Qiong, Xu, Su-Yang, Bansil, Arun, Hasan, M. Zahid, and Chang, Guoqing

Subjects

Condensed Matter - Materials Science, Physics - Optics

Abstract

Nonlinear optical responses of quantum materials have recently undergone dramatic developments to unveil nontrivial geometry and topology. A remarkable example is the quantized longitudinal circular photogalvanic effect (CPGE) associated with the Chern number of Weyl fermions, while the physics of transverse CPGE in Weyl semimetals remains exclusive. Here, we show that the transverse CPGE of Lorentz invariant Weyl fermions is forced to be zero. We find that the transverse photocurrents of Weyl fermions are associated not only with the Chern numbers but also with the degree of Lorentz-symmetry breaking in condensed matter systems. Based on the generic two-band model analysis, we provide a new powerful equation to calculate the transverse CPGE based on the tilting and warping terms of Weyl fermions. Our results are more capable in designing large transverse CPGE of Weyl semimetals in experiments and are applied to more than tens of Weyl materials to estimate their photocurrents. Our method paves the way to study the CPGE of massless or massive quasiparticles to design next-generation quantum optoelectronics.

Published

2023

29. Imaging real-space flat band localization in kagome magnet FeSn

Author

Multer, Daniel, Yin, Jia-Xin, Hossain, Md. Shafayat, Yang, Xian, Sales, Brian C, Miao, Hu, Meier, William R, Jiang, Yu-Xiao, Xie, Yaofeng, Dai, Pengcheng, Liu, Jianpeng, Deng, Hanbin, Lei, Hechang, Lian, Biao, and Hasan, M. Zahid

Subjects

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

Abstract

Kagome lattices host flat bands due to their frustrated lattice geometry, which leads to destructive quantum interference of electron wave functions. Here, we report imaging of the kagome flat band localization in real-space using scanning tunneling microscopy. We identify both the Fe3Sn kagome lattice layer and the Sn2 honeycomb layer with atomic resolution in kagome antiferromagnet FeSn. On the Fe3Sn lattice, at the flat band energy determined by the angle resolved photoemission spectroscopy, tunneling spectroscopy detects an unusual state localized uniquely at the Fe kagome lattice network. We further show that the vectorial in-plane magnetic field manipulates the spatial anisotropy of the localization state within each kagome unit cell. Our results are consistent with the real-space flat band localization in the magnetic kagome lattice. We further discuss the magnetic tuning of flat band localization under the spin-orbit coupled magnetic kagome lattice model., Comment: To appear in Communications Materials

Published

2022

30. Topological kagome magnets and superconductors

Author

Yin, Jia-Xin, Lian, Biao, and Hasan, M Zahid

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Superconductivity

Abstract

A kagome lattice naturally features Dirac fermions, flat bands and van Hove singularities in its electronic structure. The Dirac fermions encode topology, flat bands favour correlated phenomena such as magnetism, and van Hove singularities can lead to instabilities towards long-range many-body orders, altogether allowing for the realization and discovery of a series of topological kagome magnets and superconductors with exotic properties. Recent progress in exploring kagome materials has revealed rich emergent phenomena resulting from the quantum interactions between geometry, topology, spin and correlation. Here we review these key developments in this field, starting from the fundamental concepts of a kagome lattice, to the realizations of Chern and Weyl topological magnetism, to various flat-band many-body correlations, and then to the puzzles of unconventional charge-density waves and superconductivity. We highlight the connection between theoretical ideas and experimental observations, and the bond between quantum interactions within kagome magnets and kagome superconductors, as well as their relation to the concepts in topological insulators, topological superconductors, Weyl semimetals and high-temperature superconductors. These developments broadly bridge topological quantum physics and correlated many-body physics in a wide range of bulk materials and substantially advance the frontier of topological quantum matter.

Published

2022

31. Evidence for electronic signature of magnetic transition in topological magnet HoSbTe

Author

Shumiya, Nana, Yin, Jia-Xin, Chang, Guoqing, Yang, Meng, Mardanya, Sougata, Chang, Tay-Rong, Lin, Hsin, Hossain, Md Shafayat, Jiang, Yu-Xiao, Cochran, Tyler A., Zhang, Qi, Yang, Xian P., Shi, Youguo, and Hasan, M. Zahid

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Topological insulators with intrinsic magnetic order are emerging as an exciting platform to realize fundamentally new excitations from topological quantum states of matter. To study these systems and their physics, people have proposed a variety of magnetic topological insulator systems, including HoSbTe, an antiferromagnetic weak topological insulator candidate. In this work, we use scanning tunneling microscopy to probe the electronic structure of HoSbTe with antiferromagnetic and ferromagnetic orders that are tuned by applying an external magnetic field. Although around the Fermi energy, we find minor differences between the quasi-particle interferences under the ferromagnetic and antiferromagnetic orders, deep inside the valance region, a new quasi-particle interference signal emerges with ferromagnetism. This observation is consistent with our first-principles calculations indicating the magnetism-driven transition of the electronic states in this spin-orbit coupled topological magnet., Comment: 13 pages, 7 figures

Published

2022

32. Intertwining of magnetism and charge ordering in kagome FeGe

Author

Shao, Sen, Yin, Jia-Xin, Belopolski, Ilya, You, Jing-Yang, Hou, Tao, Chen, Hongyu, Jiang, Yuxiao, Hossain, Md Shafayat, Yahyavi, Mohammad, Hsu, Chia-Hsiu, Feng, Yuan Ping, Bansil, Arun, Hasan, M. Zahid, and Chang, Guoqing

Subjects

Condensed Matter - Materials Science

Abstract

Recent experiments report a charge density wave (CDW) in the antiferromagnet FeGe, but the nature of the charge ordering and the associated structural distortion remains elusive. We discuss the structural and electronic properties of FeGe. Our proposed ground state phase accurately captures atomic topographies acquired by scanning tunneling microscopy. We show that the 2$\times$2$\times$1 CDW likely results from the Fermi surface nesting of hexagonal-prism-shaped kagome states. FeGe is found to exhibit distortions in the positions of the Ge atoms instead of the Fe atoms in the kagome layers. Using in-depth first-principles calculations and analytical modeling, we demonstrate that this unconventional distortion is driven by the intertwining of magnetic exchange coupling and CDW interactions in this kagome material. Movement of Ge atoms from their pristine positions also enhances the magnetic moment of the Fe kagome layers. Our study indicates that magnetic kagome lattices provide a material candidate for exploring the effects of strong electronic correlations on the ground state and their implications for transport, magnetic, and optical responses in materials.

Published

2022

33. Coexistence of Bulk-Nodal and Surface-Nodeless Cooper Pairings in a Superconducting Dirac Semimetal

Author

Yang, Xian P, Zhong, Yigui, Mardanya, Sougata, Cochran, Tyler A, Chapai, Ramakanta, Mine, Akifumi, Zhang, Junyi, Sánchez-Barriga, Jaime, Cheng, Zi-Jia, Clark, Oliver J, Yin, Jia-Xin, Blawat, Joanna, Cheng, Guangming, Belopolski, Ilya, Nagashima, Tsubaki, Najafzadeh, Sahand, Gao, Shiyuan, Yao, Nan, Bansil, Arun, Jin, Rongying, Chang, Tay-Rong, Shin, Shik, Okazaki, Kozo, and Hasan, M Zahid

Subjects

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

Abstract

The interplay of nontrivial topology and superconductivity in condensed matter physics gives rise to exotic phenomena. However, materials are extremely rare where it is possible to explore the full details of the superconducting pairing. Here, we investigate the momentum dependence of the superconducting gap distribution in a novel Dirac material PdTe. Using high resolution, low temperature photoemission spectroscopy, we establish it as a spin-orbit coupled Dirac semimetal with the topological Fermi arc crossing the Fermi level on the (010) surface. This spin-textured surface state exhibits a fully gapped superconducting Cooper pairing structure below T_{c}∼4.5  K. Moreover, we find a node in the bulk near the Brillouin zone boundary, away from the topological Fermi arc. These observations not only demonstrate the band resolved electronic correlation between topological Fermi arc states and the way it induces Cooper pairing in PdTe, but also provide a rare case where surface and bulk states host a coexistence of nodeless and nodal gap structures enforced by spin-orbit coupling.

Published

2023

34. Emergent Edge Modes in Shifted Quasi-One-Dimensional Charge Density Waves

Author

Zhang, Song-Bo, Liu, Xiaoxiong, Hossain, Md Shafayat, Yin, Jia-Xin, Hasan, M. Zahid, and Neupert, Titus

Subjects

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

Abstract

We propose and study a two-dimensional (2D) phase of shifted charge density waves (CDW), which is constructed from an array of weakly coupled 1D CDW wires whose phases shift from one wire to the next. We show that the fully gapped bulk CDW has topological properties, characterized by a nonzero Chern number, that imply edge modes within the bulk gap. Remarkably, these edge modes exhibit spectral pseudo-flow as a function of \emph{position} along the edge, and are thus dual to the chiral edge modes of Chern insulators with their spectral flow in \emph{momentum} space. Furthermore, we show that the CDW edge modes are stable against inter-wire coupling. Our predictions can be tested experimentally in quasi-1D CDW compounds such as Ta$_2$Se$_8$I., Comment: 5+4 pages, 4+6 figures

Published

2022

35. Discovery of charge density wave in a correlated kagome lattice antiferromagnet

Author

Teng, Xiaokun, Chen, Lebing, Ye, Feng, Rosenberg, Elliott, Liu, Zhaoyu, Yin, Jia-Xin, Jiang, Yu-Xiao, Oh, Ji Seop, Hasan, M. Zahid, Neubauer, Kelly J., Gao, Bin, Xie, Yaofeng, Hashimoto, Makoto, Lu, Donghui, Jozwiak, Chris, Bostwick, Aaron, Rotenberg, Eli, Birgeneau, Robert J., Chu, Jiun-Haw, Yi, Ming, and Dai, Pengcheng

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

A hallmark of strongly correlated quantum materials is the rich phase diagram resulting from competing and intertwined phases with nearly degenerate ground state energies. A well-known example is the copper oxides, where a charge density wave (CDW) is ordered well above and strongly coupled to the magnetic order to form spin-charge separated stripes that compete with superconductivity. Recently, such rich phase diagrams have also been revealed in correlated topological materials. In two-dimensional kagome lattice metals consisting of corner-sharing triangles, the geometry of the lattice can produce flat bands with localized electrons, non-trivial topology, chiral magnetic order, superconductivity and CDW order. While CDW has been found in weakly electron correlated nonmagnetic AV3Sb5 (A = K, Rb, Cs), it has not yet been observed in correlated magnetic ordered kagome lattice metals. Here we report the discovery of CDW within the antiferromagnetic (AFM) ordered phase of kagome lattice FeGe. The CDW in FeGe occurs at wavevectors identical to that of AV3Sb5, enhances the AFM ordered moment, and induces an emergent anomalous Hall effect. Our findings suggest that CDW in FeGe arises from the combination of electron correlations-driven AFM order and van Hove singularities-driven instability possibly associated with a chiral flux phase, in stark contrast to strongly correlated copper oxides and nickelates, where the CDW precedes or accompanies the magnetic order., Comment: 36 pages, 4 figures in main text

Published

2022

36. Magnetization-direction-tunable kagome Weyl line

Author

Cheng, Zi-Jia, Belopolski, Ilya, Cochran, Tyler A., Tien, Hung-Ju, Yang, Xian P., Ma, Wenlong, Yin, Jia-Xin, Zhang, Junyi, Jozwiak, Chris, Bostwick, Aaron, Rotenberg, Eli, Cheng, Guangming, Hossain, Md. Shafayat, Zhang, Qi, Shumiya, Nana, Multer, Daniel, Litskevich, Maksim, Jiang, Yuxiao, Yao, Nan, Lian, Biao, Chang, Guoqing, Jia, Shuang, Chang, Tay-Rong, and Hasan, M. Zahid

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Kagome magnets provide a fascinating platform for a plethora of topological quantum phenomena. Here, utilizing angle-resolved photoemission spectroscopy, we demonstrate Weyl lines with strong out-of-plane dispersion in an A-A stacked kagome magnet TbxGd1-xMn6Sn6. On the Gd rich side, the Weyl line remains nearly spin-orbit-gapless due to a remarkable cooperative interplay between Kane-Mele spin-orbit-coupling, low site symmetry and in-plane magnetic order. Under Tb substitution, the kagome Weyl line gaps due to a magnetic reorientation to out-of-plane order. Our results illustrate the magnetic moment direction as an efficient tuning knob for realizing distinct three-dimensional topological phases., Comment: 12 pages, 4 figures. Comments are welcome!

Published

2022

37. Discovery of charge order and corresponding edge state in kagome magnet FeGe

Author

Yin, Jia-Xin, Jiang, Yu-Xiao, Teng, Xiaokun, Hossain, Md. Shafayat, Mardanya, Sougata, Chang, Tay-Rong, Ye, Zijin, Xu, Gang, Denner, M. Michael, Neupert, Titus, Lienhard, Benjamin, Deng, Han-Bin, Setty, Chandan, Si, Qimiao, Chang, Guoqing, Guguchia, Zurab, Gao, Bin, Shumiya, Nana, Zhang, Qi, Cochran, Tyler A., Multer, Daniel, Yi, Ming, Dai, Pengcheng, and Hasan, M. Zahid

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Kagome materials often host exotic quantum phases, including spin liquids, Chern gap, charge order, and superconductivity. Existing scanning microscopy studies of the kagome charge order have been limited to non-kagome surface layers. Here we tunnel into the kagome lattice of FeGe to uncover features of the charge order. Our spectroscopic imaging identifes a 2x2 charge order in the magnetic kagome lattice, resembling that discovered in kagome superconductors. Spin-mapping across steps of unit-cell-height demonstrates that this charge order emerges from spin-polarized electrons with an antiferromagnetic stacking order. We further uncover the correlation between antiferromagnetism and charge order anisotropy, highlighting the unusual magnetic coupling of the charge order. Finally, we detect a pronounced edge state within the charge order energy gap, which is robust against the irregular shape of the kagome lattice edges. We discuss our results with the theoretically considered topological features of the kagome charge order including orbital magnetism and bulk-boundary correspondence.

Published

2022

38. Visualizing the out-of-plane electronic dispersions in an intercalated transition metal dichalcogenide

Author

Yang, Xian P., LaBollita, Harrison, Cheng, Zi-Jia, Bhandari, Hari, Cochran, Tyler A., Yin, Jia-Xin, Hossain, Md. Shafayat, Belopolski, Ilya, Zhang, Qi, Jiang, Yuxiao, Shumiya, Nana, Multer, Daniel, Liskevich, Maksim, Usanov, Dmitry A., Dang, Yanliu, Strocov, Vladimir N., Davydov, Albert V., Ghimire, Nirmal J., Botana, Antia S., and Hasan, M. Zahid

Subjects

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

Abstract

Layered transition metal dichalcogenides have rich phase diagram and they feature two dimensionality on numerous physical properties. Co1/3NbS2 is one of the newest members of this family where Co atoms are intercalated into the Van der Waals gaps between NbS2 layers. We study the three-dimensional electronic band structure of Co1/3NbS2 using both surface and bulk sensitive angle-resolved photoemission spectroscopy. We show that the electronic bands do not fit into the rigid-band-shift picture after the Co intercalation. Instead, Co1/3NbS2 displays a different orbital character near the Fermi level compared to the pristine NbS2 compound and has a clear band dispersion in kz direction despite its layered structure. Our photoemission study demonstrates the out-of-plane electronic correlations introduced by the Co intercalation, thus offering a new perspective on this compound. Finally, we propose how Fermi level tuning could lead to exotic phases such as spin density wave instability., Comment: Accepted by Physical Review B

Published

2022

39. Relativistic horizon of interacting Weyl fermions in condensed matter systems

Author

Chiu, Wei-Chi, Chang, Guoqing, Macam, Gennevieve, Belopolski, Ilya, Huang, Shin-Ming, Markiewicz, Robert, Yin, Jia-Xin, Cheng, Zi-jia, Lee, Chi-Cheng, Chang, Tay-Rong, Chuang, Feng-Chuan, Xu, Su-Yang, Lin, Hsin, Hasan, M. Zahid, and Bansil, Arun

Subjects

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

Abstract

The intersections of topology, geometry and strong correlations offer many opportunities for exotic quantum phases to emerge in condensed matter systems. Weyl fermions, in particular, provide an ideal platform for exploring the dynamical instabilities of single-particle physics under interactions. Despite its fundamental role in relativistic field theory, the concept of causality and the associated spacetime light cone and event horizon has not been considered in connection with interacting Weyl fermionic excitations in quantum matter. Here, by using charge-density wave (CDW) as an example, we unveil the behavior of interacting Weyl fermions and show that a Weyl fermion in a system can open a band gap by interacting only with other Weyl fermions that lie within its energy-momentum dispersion cone. In this sense, causal connections or interactions are only possible within overlapping dispersion cones and each dispersion cone thus constitutes a solid-state analogue of the more conventional `event horizon' of high-energy physics. Our study provides a universal framework for considering interacting relativistic quasiparticles in condensed matter by separating them into energy-like and momentum-like relationships in analogy with the time-like and space-like events in high-energy physics. Finally, we consider two different candidate materials for hosting the Weyl CDW phase: (TaSe$_4$)$_2$I and Mo$_3$Al$_2$C. Our study greatly enriches the phenomenology and unveils new connections between condensed matter and high-energy physics.

Published

2022

40. What's knot to like? Observation of a linked loop quantum state

Author

Belopolski, Ilya, Chang, Guoqing, Cochran, Tyler A., Cheng, Zi-Jia, Yang, Xian P., Hugelmeyer, Cole, Manna, Kaustuv, Yin, Jia-Xin, Cheng, Guangming, Multer, Daniel, Litskevich, Maksim, Shumiya, Nana, Zhang, Songtian S., Shekhar, Chandra, Schröter, Niels B. M., Chikina, Alla, Polley, Craig, Thiagarajan, Balasubramanian, Leandersson, Mats, Adell, Johan, Huang, Shin-Ming, Yao, Nan, Strocov, Vladimir N., Felser, Claudia, and Hasan, M. Zahid

Subjects

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

Abstract

Quantum phases can be classified by topological invariants, which take on discrete values capturing global information about the quantum state. Over the past decades, these invariants have come to play a central role in describing matter, providing the foundation for understanding superfluids, magnets, the quantum Hall effect, topological insulators, Weyl semimetals and other phenomena. Here we report a remarkable linking number (knot theory) invariant associated with loops of electronic band crossings in a mirror-symmetric ferromagnet. Using state-of-the-art spectroscopic methods, we directly observe three intertwined degeneracy loops in the material's bulk Brillouin zone three-torus, $\mathbb{T}^3$. We find that each loop links each other loop twice. Through systematic spectroscopic investigation of this linked loop quantum state, we explicitly draw its link diagram and conclude, in analogy with knot theory, that it exhibits linking number $(2,2,2)$, providing a direct determination of the invariant structure from the experimental data. On the surface of our samples, we further predict and observe Seifert boundary states protected by the bulk linked loops, suggestive of a remarkable Seifert bulk-boundary correspondence. Our observation of a quantum loop link motivates the application of knot theory to the exploration of exotic properties of quantum matter., Comment: See popular summary at https://research.princeton.edu/news/electrons-crystal-exhibit-linked-and-knotted-quantum-twists

Published

2021

41. Structural instability and charge modulations in the Kagome superconductor $A$V$_3$Sb$_5$

Author

Ye, Zijin, Luo, Aiyun, Yin, Jia-Xin, Hasan, M Zahid, and Xu, Gang

Subjects

Condensed Matter - Materials Science

Abstract

Recently, both charge density wave (CDW) and superconductivity have been observed in Kagome compounds $A$V$_3$Sb$_5$. However, the nature of CDW that results in many novel charge modulations is still under hot debate. By means of the first-principles calculations, we discover two kinds of CDW states, the trimerized and hexamerized 2$\times$2 phase and dimerized 4$\times$1 phase existing in $A$V$_3$Sb$_5$. Our phonon excitation spectrum and electronic Lindhard function calculations reveal that the most intensive structural instability in $A$V$_3$Sb$_5$ originates from a combined in-plane vibration mode of V atoms through the electron-phonon coupling, rather than the Fermi surface nesting effect. Crucially, a metastable 4$\times$1 phase with V-V dimer pattern and twofold symmetric bowtie shaped charge modulation is revealed in CsV$_3$Sb$_5$, implying that both dimerization and trimerization exist in the V Kagome layers. These results provide essential understanding of CDW instability and new thoughts for the novel charge modulation patterns.

Published

2021

42. Electron-phonon coupling in the charge density wave state of CsV$_3$Sb$_5$

Author

Xie, Yaofeng, Li, Yongkai, Bourges, Philippe, Ivanov, Alexandre, Ye, Zijin, Yin, Jia-Xin, Hasan, M Zahid, Luo, Aiyun, Yao, Yugui, Wang, Zhiwei, Xu, Gang, and Dai, Pengcheng

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Metallic materials with kagome lattice structure are interesting because their electronic structures can host flat bands, Dirac cones, and van Hove singularities, resulting in strong electron correlations, nontrivial band topology, charge density wave (CDW), and unconventional superconductivity. Recently, kagome lattice compounds AV$_3$Sb$_5$ (A = K, Rb, Cs) are found to have intertwined CDW order and superconductivity. The origin of the CDW has been suggested to be purely electronic, arising from Fermi-surface instabilities of van Hove singularity (saddle point) near the M points. Here we use neutron scattering experiments to demonstrate that the CDW order in CsV$_3$Sb$_5$ is associated with static lattice distortion and a sudden hardening of the B3u longitudinal optical phonon mode, thus establishing that electron-phonon coupling must also play an important role in the CDW order of AV$_3$Sb$_5$.

Published

2021

43. Room-temperature quantum spin Hall edge state in a higher-order topological insulator Bi$_4$Br$_4$

Author

Shumiya, Nana, Hossain, Md Shafayat, Yin, Jia-Xin, Wang, Zhiwei, Litskevich, Maksim, Yoon, Chiho, Li, Yongkai, Yang, Ying, Jiang, Yu-Xiao, Cheng, Guangming, Lin, Yen-Chuan, Zhang, Qi, Cheng, Zi-Jia, Cochran, Tyler A., Multer, Daniel, Yang, Xian P., Casas, Brian, Chang, Tay-Rong, Neupert, Titus, Yuan, Zhujun, Jia, Shuang, Lin, Hsin, Yao, Nan, Balicas, Luis, Zhang, Fan, Yao, Yugui, and Hasan, M. Zahid

Subjects

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

Abstract

Room-temperature realization of macroscopic quantum phenomena is one of the major pursuits in fundamental physics. The quantum spin Hall state, a topological quantum phenomenon that features a two-dimensional insulating bulk and a helical edge state, has not yet been realized at room temperature. Here, we use scanning tunneling microscopy to visualize a quantum spin Hall edge state on the surface of the higher-order topological insulator Bi4Br4. We find that the atomically resolved lattice exhibits a large insulating gap of over 200meV, and an atomically sharp monolayer step edge hosts a striking in-gap gapless state, suggesting the topological bulk-boundary correspondence. An external magnetic field can gap the edge state, consistent with the time-reversal symmetry protection inherent to the underlying topology. We further identify the geometrical hybridization of such edge states, which not only attests to the Z2 topology of the quantum spin Hall state but also visualizes the building blocks of the higher-order topological insulator phase. Remarkably, both the insulating gap and topological edge state are observed to persist up to 300K. Our results point to the realization of the room-temperature quantum spin Hall edge state in a higher-order topological insulator.

Published

2021

44. Kagome superconductors AV$_3$Sb$_5$ (A=K, Rb, Cs)

Author

Jiang, Kun, Wu, Tao, Yin, Jia-Xin, Wang, Zhenyu, Hasan, M. Zahid, Wilson, Stephen D., Chen, Xianhui, and Hu, Jiangping

Subjects

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

Abstract

The quasi two-dimensional (quasi-2D) kagome materials AV$_3$Sb$_5$ (A=K, Rb, Cs) were found to be a prime example of kagome superconductors, a new quantum platform to investigate the interplay between electron correlation effects, topology and geometric frustration. In this review, we report recent progress on the experimental and theoretical studies of AV$_3$Sb$_5$ and provide a broad picture of this fast-developing field in order to stimulate an expanded search for unconventional kagome superconductors. We review the electronic properties of AV$_3$Sb$_5$, the experimental measurements of the charge density wave state, evidence of time-reversal symmetry breaking, and other potential hidden symmetry breaking in these materials. A variety of theoretical proposals and models that address the nature of the time-reversal symmetry breaking are discussed. Finally, we review the superconducting properties of AV$_3$Sb$_5$, especially the potential pairing symmetries and the interplay between superconductivity and the charge density wave state., Comment: A review on kagome superconductors AV$_3$Sb$_5$, including 14 pages and 9 figures

Published

2021

45. Causal structure of interacting Weyl fermions in condensed matter systems

Author

Chiu, Wei-Chi, Chang, Guoqing, Macam, Gennevieve, Belopolski, Ilya, Huang, Shin-Ming, Markiewicz, Robert, Yin, Jia-Xin, Cheng, Zi-Jia, Lee, Chi-Cheng, Chang, Tay-Rong, Chuang, Feng-Chuan, Xu, Su-Yang, Lin, Hsin, Hasan, M. Zahid, and Bansil, Arun

Published

2023

46. The Magnetic Genome of Two-Dimensional van der Waals Materials

Author

Wang, Qing Hua, Bedoya-Pinto, Amilcar, Blei, Mark, Dismukes, Avalon H, Hamo, Assaf, Jenkins, Sarah, Koperski, Maciej, Liu, Yu, Sun, Qi-Chao, Telford, Evan J, Kim, Hyun Ho, Augustin, Mathias, Vool, Uri, Yin, Jia-Xin, Li, Lu Hua, Falin, Alexey, Dean, Cory R, Casanova, Fèlix, Evans, Richard FL, Chshiev, Mairbek, Mishchenko, Artem, Petrovic, Cedomir, He, Rui, Zhao, Liuyan, Tsen, Adam W, Gerardot, Brian D, Brotons-Gisbert, Mauro, Guguchia, Zurab, Roy, Xavier, Tongay, Sefaattin, Wang, Ziwei, Hasan, M Zahid, Wrachtrup, Joerg, Yacoby, Amir, Fert, Albert, Parkin, Stuart, Novoselov, Kostya S, Dai, Pengcheng, Balicas, Luis, and Santos, Elton JG

Subjects

Engineering, Electronics, Sensors and Digital Hardware, Physical Sciences, Condensed Matter Physics, Computing Methodologies, Quantum Theory, Magnetic Phenomena, 2D magnetic materials, CrI3, Fe3GeTe2, atomistic spin dynamics, magnetic genome, magneto-optical effect, neutron scattering, van der Waals, Nanoscience & Nanotechnology

Abstract

Magnetism in two-dimensional (2D) van der Waals (vdW) materials has recently emerged as one of the most promising areas in condensed matter research, with many exciting emerging properties and significant potential for applications ranging from topological magnonics to low-power spintronics, quantum computing, and optical communications. In the brief time after their discovery, 2D magnets have blossomed into a rich area for investigation, where fundamental concepts in magnetism are challenged by the behavior of spins that can develop at the single layer limit. However, much effort is still needed in multiple fronts before 2D magnets can be routinely used for practical implementations. In this comprehensive review, prominent authors with expertise in complementary fields of 2D magnetism (i.e., synthesis, device engineering, magneto-optics, imaging, transport, mechanics, spin excitations, and theory and simulations) have joined together to provide a genome of current knowledge and a guideline for future developments in 2D magnetic materials research.

Published

2022

47. Observation of a linked-loop quantum state in a topological magnet

Author

Belopolski, Ilya, Chang, Guoqing, Cochran, Tyler A, Cheng, Zi-Jia, Yang, Xian P, Hugelmeyer, Cole, Manna, Kaustuv, Yin, Jia-Xin, Cheng, Guangming, Multer, Daniel, Litskevich, Maksim, Shumiya, Nana, Zhang, Songtian S, Shekhar, Chandra, Schröter, Niels BM, Chikina, Alla, Polley, Craig, Thiagarajan, Balasubramanian, Leandersson, Mats, Adell, Johan, Huang, Shin-Ming, Yao, Nan, Strocov, Vladimir N, Felser, Claudia, and Hasan, M Zahid

Subjects

Mathematical Physics, Mathematical Sciences, Physical Sciences, Condensed Matter Physics, General Science & Technology

Abstract

Quantum phases can be classified by topological invariants, which take on discrete values capturing global information about the quantum state1-13. Over the past decades, these invariants have come to play a central role in describing matter, providing the foundation for understanding superfluids5, magnets6,7, the quantum Hall effect3,8, topological insulators9,10, Weyl semimetals11-13 and other phenomena. Here we report an unusual linking-number (knot theory) invariant associated with loops of electronic band crossings in a mirror-symmetric ferromagnet14-20. Using state-of-the-art spectroscopic methods, we directly observe three intertwined degeneracy loops in the material's three-torus, T3, bulk Brillouin zone. We find that each loop links each other loop twice. Through systematic spectroscopic investigation of this linked-loop quantum state, we explicitly draw its link diagram and conclude, in analogy with knot theory, that it exhibits the linking number (2, 2, 2), providing a direct determination of the invariant structure from the experimental data. We further predict and observe, on the surface of our samples, Seifert boundary states protected by the bulk linked loops, suggestive of a remarkable Seifert bulk-boundary correspondence. Our observation of a quantum loop link motivates the application of knot theory to the exploration of magnetic and superconducting quantum matter.

Published

2022

48. Electron-phonon coupling in the charge density wave state of CsV3Sb5

Author

Xie, Yaofeng, Li, Yongkai, Bourges, Philippe, Ivanov, Alexandre, Ye, Zijin, Yin, Jia-Xin, Hasan, M Zahid, Luo, Aiyun, Yao, Yugui, Wang, Zhiwei, Xu, Gang, and Dai, Pengcheng

Subjects

Physical Sciences, Chemical Sciences, Engineering, Fluids & Plasmas

Abstract

Metallic materials with kagome lattice structure are interesting because their electronic structures can host flat bands, Dirac cones, and van Hove singularities, resulting in strong electron correlations, nontrivial band topology, charge density wave (CDW), and unconventional superconductivity. Recently, kagome lattice compounds AV3Sb5 (A=K, Rb, Cs) are found to have intertwined CDW order and superconductivity. The origin of the CDW has been suggested to arise from Fermi-surface instabilities of van Hove singularity (saddle point) near the M points with weak electron-phonon coupling. Here we use neutron scattering experiments to demonstrate that the CDW order in CsV3Sb5 is associated with static lattice distortion and a sudden hardening of the B3u longitudinal optical phonon mode at the Brillouin zone boundary, thus establishing that the wave vector dependent electron-phonon coupling must also play an important role in the CDW order of AV3Sb5.

Published

2022

49. Visualizing the out-of-plane electronic dispersions in an intercalated transition metal dichalcogenide

Author

Yang, Xian P, LaBollita, Harrison, Cheng, Zi-Jia, Bhandari, Hari, Cochran, Tyler A, Yin, Jia-Xin, Hossain, Shafayat, Belopolski, Ilya, Zhang, Qi, Jiang, Yuxiao, Shumiya, Nana, Multer, Daniel, Liskevich, Maksim, Usanov, Dmitry A, Dang, Yanliu, Strocov, Vladimir N, Davydov, Albert V, Ghimire, Nirmal J, Botana, Antia S, and Hasan, M Zahid

Subjects

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

Abstract

Layered transition metal dichalcogenides have a rich phase diagram and they feature two-dimensionality in numerous physical properties. Co1/3NbS2 is one of the newest members of this family where Co atoms are intercalated into the van der Waals gaps between NbS2 layers. We study the three-dimensional electronic band structure of Co1/3NbS2 using both surface and bulk sensitive angle-resolved photoemission spectroscopy. We show that the electronic bands do not fit into the rigid band shift picture after the Co intercalation. Instead, Co1/3NbS2 displays a different orbital character near the Fermi level compared to the pristine NbS2 compound and has a clear band dispersion in the kz direction despite its layered structure. Our photoemission study demonstrates the out-of-plane electronic correlations introduced by the Co intercalation, thus offering a different perspective on this compound. Finally, we propose how Fermi level tuning could lead to exotic phases such as spin density wave instability.

Published

2022

50. Helicoid-arc van Hove singularities in topological chiral crystals

Author

Sanchez, Daniel S., Cochran, Tyler A., Belopolski, Ilya, Cheng, Zi-Jia, Yang, Xian P., Liu, Yiyuan, Xu, Xitong, Manna, Kaustuv, Yin, Jia-Xin, Borrmann, Horst, Chikina, Alla, Denlinger, Jonathan, Strocov, Vladimir N., Felser, Claudia, Jia, Shuang, Chang, Guoqing, and Hasan, M. Zahid

Subjects

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

Abstract

Van Hove singularity are electronic instabilities that lead to many fascinating interactions, such as superconductivity and charge-density waves. And despite much interest, the nexus of emergent correlation effects from van Hove singularities and topological states of matter remains little explored in experiments. By utilizing synchrotron-based angle-resolved photoemission spectroscopy and Density Functional Theory, here we provide the first discovery of the helicoid quantum nature of topological Fermi arcs inducing van Hove singularities. In particular, in topological chiral conductors RhSi and CoSi we directly observed multiple types of inter- and intra-helicoid-arc mediated singularities, which includes the type-I and type-II van Hove singularity. We further demonstrate that the energy of the helicoid-arc singularities are easily tuned by chemical engineering. Taken together, our work provides a promising route to engineering new electronic instabilities in topological quantum materials.

Published

2021