Your search keyword '"Neupert, Titus"' showing total 834 results

1. Probing chiral symmetry with a topological domain wall sensor

Author

Wagner, Glenn, Neupert, Titus, Thomale, Ronny, Szczerbakow, Andrzej, Korczak, Jedrzej, Story, Tomasz, Bode, Matthias, and Odobesko, Artem

Subjects

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

Abstract

Chiral symmetry is a fundamental property with profound implications for the properties of elementary particles, that implies a spectral symmetry (i.e. E => -E ) in their dispersion relation. In condensed matter physics, chiral symmetry is frequently associated with superconductors or materials hosting Dirac fermions such as graphene or topological insulators. There, chiral symmetry is an emergent low-energy property, accompanied by an emergent spectral symmetry. While the chiral symmetry can be broken by crystal distortion or external perturbations, the spectral symmetry frequently survives. As the presence of spectral symmetry does not necessarily imply chiral symmetry, the question arises how these two properties can be experimentally differentiated. Here, we demonstrate how a system with preserved spectral symmetry can reveal underlying broken chiral symmetry using topological defects. Our study shows that these defects induce a spectral imbalance in the Landau level spectrum, providing direct evidence of symmetry alteration at topological domain walls. Using high-resolution STM/STS we demonstrate the intricate interplay between chiral and translational symmetry which is broken at step edges in topological crystalline insulator Pb$_{1-x}$Sn$_x$Se. The chiral symmetry breaking leads to a shift in the guiding center coordinates of the Landau orbitals near the step edge, thus resulting in a distinct chiral flow of the spectral density of Landau levels. This study underscores the pivotal role of topological defects as sensitive probes for detecting hidden symmetries, offering profound insights into emergent phenomena with implications for fundamental physics., Comment: 13 pages, 3 figures, Supplementary Material

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. Topological excitons in moir\'e MoTe$_2$/WSe$_2$ heterobilayers

Author

Froese, Paul, Neupert, Titus, and Wagner, Glenn

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Due to the presence of flat Chern bands, moir\'e transition metal dichalcogenide (TMD) bilayers are a platform to realize strongly correlated topological phases of fermions such as fractional Chern insulators. TMDs are also known to host long-lived excitons, which inherit the topology of the underlying Chern bands. For the particular example of MoTe$_2$/WSe$_2$ heterobilayers we perform a time-dependent Hartree-Fock calculation to identify a regime in the phase diagram where the excitons themselves form a topological flat band. This paves a way towards realizing strongly correlated states of bosons in moir\'e TMDs., Comment: 7 pages, 4 figures (4 pages in supplement)

Published

2024

4. Multifractal statistics of non-Hermitian skin effect on the Cayley tree

Author

Hamanaka, Shu, Iliasov, Askar A., Neupert, Titus, Bzdušek, Tomáš, and Yoshida, Tsuneya

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Statistical Mechanics, Quantum Physics

Abstract

Multifractal analysis is a powerful tool for characterizing the localization properties of wave functions. Despite its utility, this tool has been predominantly applied to disordered Hermitian systems. Multifractal statistics associated with the non-Hermitian skin effect remain largely unexplored. Here, we demonstrate that the tree geometry induces multifractal statistics for the single-particle skin states on the Cayley tree. This sharply contrasts with the absence of multifractal properties for conventional single-particle skin effects in crystalline lattices. Our work uncovers the unique feature of the skin effect on the Cayley tree and provides a novel mechanism for inducing multifractality in open quantum systems without disorder., Comment: 19 pages, 7 figures

Published

2024

5. Chiral kagome superconductivity modulations with residual Fermi arcs in KV3Sb5 and CsV3Sb5

Author

Deng, Hanbin, Qin, Hailang, Liu, Guowei, Yang, Tianyu, Fu, Ruiqing, Zhang, Zhongyi, Wu, Xianxin, Wang, Zhiwei, Shi, Youguo, Liu, Jinjin, Liu, Hongxiong, Yan, Xiao-Yu, Song, Wei, Xu, Xitong, Zhao, Yuanyuan, Yi, Mingsheng, Xu, Gang, Hohmann, Hendrik, Holbæk, Sofie Castro, Dürrnage, Matteo, Zhou, Sen, Chang, Guoqing, Yao, Yugui, Wang, Qianghua, Guguchia, Zurab, Neupert, Titus, Thomale, Ronny, Fischer, Mark H., and Yin, Jia-Xin

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Materials Science

Abstract

Superconductivity involving finite momentum pairing can lead to spatial gap and pair density modulations, as well as Bogoliubov Fermi states within the superconducting gap. However, the experimental realization of their intertwined relations has been challenging. Here, we detect chiral kagome superconductivity modulations with residual Fermi arcs in KV3Sb5 and CsV3Sb5 by normal and Josephson scanning tunneling microscopy down to 30mK with resolved electronic energy difference at microelectronvolt level. We observe a U-shaped superconducting gap with flat residual in-gap states. This gap exhibits chiral 2 by 2 spatial modulations with magnetic field tunable chirality, which align with the chiral 2 by 2 pair density modulations observed through Josephson tunneling. These findings demonstrate a chiral pair density wave (PDW) that breaks time-reversal symmetry. Quasiparticle interference imaging of the in-gap zero-energy states reveals segmented arcs, with high-temperature data linking them to parts of the reconstructed V d-orbital states within the charge order. The detected residual Fermi arcs can be explained by the partial suppression of these d-orbital states through an interorbital 2 by 2 PDW and thus serve as candidate Bogoliubov Fermi states. Additionally, we differentiate the observed PDW order from impurity-induced gap modulations. Our observations not only uncover a chiral PDW order with orbital-selectivity, but also illuminate the fundamental space-momentum correspondence inherent in finite momentum paired superconductivity., Comment: To appear in Nature (2024)

Published

2024

6. Local excitation of kagome spin ice magnetism in HoAgGe seen by scanning tunneling microscopy

Author

Deng, Hanbin, Yang, Tianyu, Liu, Guowei, Liu, Lu, Zhao, Lingxiao, Wang, Wu, Li, Tiantian, Song, Wei, Neupert, Titus, Liu, Xiang-Rui, Shao, Jifeng, Zhao, Y. Y., Xu, Nan, Deng, Hao, Huang, Li, Zhao, Yue, Zhang, Liyuan, Mei, Jia-Wei, Wu, Liusuo, He, Jiaqing, Liu, Qihang, Liu, Chang, and Yin, Jia-Xin

Subjects

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

Abstract

The kagome spin ice can host frustrated magnetic excitations by flipping its local spin. Under an inelastic tunneling condition, the tip in a scanning tunneling microscope can flip the local spin, and we apply this technique to kagome metal HoAgGe with a long-range ordered spin ice ground state. Away from defects, we discover a pair of pronounced dips in the local tunneling spectrum at symmetrical bias voltages with negative intensity values, serving as a striking inelastic tunneling signal. This signal disappears above the spin ice formation temperature and has a dependence on the magnetic fields, demonstrating its intimate relation with the spin ice magnetism. We provide a two-level spin-flip model to explain the tunneling dips considering the spin ice magnetism under spin-orbit coupling. Our results uncover a local emergent excitation of spin ice magnetism in a kagome metal, suggesting that local electrical field induced spin flip climbs over a barrier caused by spin-orbital locking.

Published

2024

7. Topology of ultra-localized insulators and superconductors

Author

Lapierre, Bastien, Trifunovic, Luka, Neupert, Titus, and Brouwer, Piet W.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Disordered Systems and Neural Networks

Abstract

The topology of an insulator can be defined even when all eigenstates of the system are localized - an extreme case of Anderson insulators that we call ultra-localized. We derive the classification of such ultra-localized insulators in all symmetry classes and dimensions. We clarify their bulk-boundary correspondence and show that ultra-localized systems are in many instances phases of matter not described by the known classification of topological insulators and superconductors.

Published

2024

8. When Could Abelian Fractional Topological Insulators Exist in Twisted MoTe$_2$ (and Other Systems)

Author

Kwan, Yves H., Wagner, Glenn, Yu, Jiabin, Dagnino, Andrea Kouta, Jiang, Yi, Xu, Xiaodong, Bernevig, B. Andrei, Neupert, Titus, and Regnault, Nicolas

Subjects

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

Abstract

Using comprehensive exact diagonalization calculations on $\theta \approx 3.7 ^{\circ}$ twisted bilayer MoTe$_2$ ($t$MoTe$_2$), as well as idealized Landau level models also relevant for lower $\theta$, we extract general principles for engineering fractional topological insulators (FTIs) in realistic situations. First, in a Landau level setup at $\nu=1/3+1/3$, we investigate what features of the interaction destroy an FTI. For both pseudopotential interactions and realistic screened Coulomb interactions, we find that sufficient suppression of the short-range repulsion is needed for stabilizing an FTI. We then study $\theta \approx 3.7 ^{\circ}$ $t$MoTe$_2$ with realistic band-mixing and anisotropic non-local dielectric screening. Our finite-size calculations only find an FTI phase at $\nu=-4/3$ in the presence of a significant additional short-range attraction $g$ that acts to counter the Coulomb repulsion at short distances. We discuss how further finite-size drifts, dielectric engineering, Landau level character, and band-mixing effects may reduce the required value of $g$ closer towards the experimentally relevant conditions of $t$MoTe$_2$. Projective calculations into the $n=1$ Landau level, which resembles the second valence band of $\theta\simeq 2.1^\circ$ $t$MoTe$_2$, do not yield FTIs for any $g$, suggesting that FTIs at low-angle $t$MoTe$_2$ for $\nu=-8/3$ and $-10/3$ may be unlikely. While our study highlights the challenges, at least for the fillings considered, to obtaining an FTI with transport plateaus, even in large-angle $t$MoTe$_2$ where fractional Chern insulators are experimentally established, we also provide potential sample-engineering routes to improve the stability of FTI phases., Comment: 6+36 pages

Published

2024

9. 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

10. Floquet engineered inhomogeneous quantum chaos in critical systems

Author

Lapierre, Bastien, Numasawa, Tokiro, Neupert, Titus, and Ryu, Shinsei

Subjects

Condensed Matter - Strongly Correlated Electrons, High Energy Physics - Theory, Quantum Physics

Abstract

We study universal chaotic dynamics of a large class of periodically driven critical systems described by spatially inhomogeneous conformal field theories. By employing an effective curved spacetime approach, we show that the onset of quantum chaotic correlations, captured by the Lyapunov exponent of out-of-time-order correlators (OTOCs), is set by the Hawking temperature of emergent Floquet horizons. Furthermore, scrambling of quantum information is shown to be strongly inhomogeneous, leading to transitions from chaotic to non-chaotic regimes by tuning driving parameters. We finally use our framework to propose a concrete protocol to simulate and measure OTOCs in quantum simulators, by designing an efficient stroboscopic backward time evolution.

Published

2024

11. Interacting Crystalline Topological Insulators in two-dimensions with Time-Reversal Symmetry

Author

Soldini, Martina O., Aksoy, Ömer M., and Neupert, Titus

Subjects

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

Abstract

Topology is routinely used to understand the physics of electronic insulators. However, for strongly interacting electronic matter, such as Mott insulators, a comprehensive topological characterization is still lacking. When their ground state only contains short-range entanglement and does not break symmetries spontaneously, they generically realize crystalline fermionic symmetry-protected topological phases (cFSPTs), supporting gapless modes at the boundaries or at the lattice defects. Here, we provide an exhaustive classification of cFSPTs in two dimensions with $\mathrm{U}(1)$ charge-conservation and spinful time-reversal symmetries, namely, those generically present in spin-orbit coupled insulators, for any of the 17 wallpaper groups. It has been shown that the classification of cFSPTs can be understood from appropriate real-space decorations of lower-dimensional subspaces, and we expose how these relate to the Wyckoff positions of the lattice. We find that all nontrivial one-dimensional decorations require electronic interactions. Furthermore, we provide model Hamiltonians for various decorations, and discuss the signatures of cFSPTs. This classification paves the way to further explore topological interacting insulators, providing the backbone information in generic model systems and ultimately in experiments.

Published

2024

12. Strain-induced enhancement of the charge-density-wave in the kagome metal ScV$_6$Sn$_6$

Author

Tuniz, Manuel, Consiglio, Armando, Pokharel, Ganesh, Parmigiani, Fulvio, Neupert, Titus, Thomale, Ronny, Sangiovanni, Giorgio, Wilson, Stephen D., Vobornik, Ivana, Salvador, Federico, Cilento, Federico, Di Sante, Domenico, and Mazzola, Federico

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

The kagome geometry is an example of frustrated configuration in which rich physics takes place, including the emergence of superconductivity and charge density wave (CDW). Among the kagome metals, ScV$_6$Sn$_6$ hosts an unconventional CDW, with its electronic order showing a different periodicity than that of the phonon which generates it. In this material, a CDW-softened flat phonon band has a second-order collapse at the same time that the first order transition occurs. This phonon band originates from the out-of-plane vibrations of the Sc and Sn atoms, and it is at the base of the electron-phonon-coupling driven CDW phase of ScV$_6$Sn$_6$. Here, we use uniaxial strain to tune the frequency of the flat phonon band, tracking the strain evolution via time-resolved optical spectroscopy and first-principles calculations. Our findings emphasize the capability to induce an enhancement of the unconventional CDW properties in ScV$_6$Sn$_6$ kagome metal through control of strain., Comment: Main text + SM

Published

2024

13. Giant Strain Response of Charge Modulation and Singularity in a Kagome Superconductor

Author

Lin, Chun, Consiglio, Armando, Forslund, Ola Kenji, Kuspert, Julia, Denner, M. Michael, Lei, Hechang, Louat, Alex, Watson, Matthew D., Kim, Timur K., Cacho, Cephise, Carbone, Dina, Leandersson, Mats, Polley, Craig, Balasubramanian, Thiagarajan, Di Sante, Domenico, Thomale, Ronny, Guguchia, Zurab, Sangiovanni, Giorgio, Neupert, Titus, and Chang, Johan

Subjects

Condensed Matter - Materials Science, Condensed Matter - Superconductivity

Abstract

Tunable quantum materials hold great potential for applications. Of special interest are materials in which small lattice strain induces giant electronic responses. The kagome compounds AV3Sb5 (A = K, Rb, Cs) provide a testbed for such singular electronic states. In this study, through angle-resolved photoemission spectroscopy, we provide comprehensive spectroscopic measurements of the giant responses induced by compressive and tensile strains on the charge-density-wave (CDW) order parameter and high-order van Hove singularity (HO-VHS) in CsV3Sb5. We observe a tripling of the CDW gap magnitudes with ~1% strain, accompanied by the changes of both energy and mass of the saddle-point fermions. Our results reveal an anticorrelation between the unconventional CDW order parameter and the mass of a HO-VHS, and highlight the role of the latter in the superconducting pairing. The giant electronic responses uncover a rich strain tunability of the versatile kagome system in studying quantum interplays under lattice perturbations.

Published

2024

14. 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

15. 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

16. 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

17. Charge-4$e$ Superconductivity in a Hubbard model

Author

Soldini, Martina O., Fischer, Mark H., and Neupert, Titus

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Superconductivity

Abstract

A phase of matter in which fermion quartets form a superconducting condensate, rather than the paradigmatic Cooper pairs, is a recurrent subject of experimental and theoretical studies. However, a comprehensive microscopic understanding of charge-4$e$ superconductivity as a quantum phase is lacking. Here, we propose and study a two-orbital tight-binding model with attractive Hubbard-type interactions. Such a model naturally provides the Bose-Einstein condensate as a limit for electron quartets and supports charge-4$e$ superconductivity, as we show by mapping it to a spin-1/2 chain in this perturbative limit. Using both exact diagonalization and density matrix renormalization group calculations for the one-dimensional case, we further establish that the ground state is indeed a superfluid phase of 4$e$ charge carriers and that this phase can be stabilized well beyond the perturbative regime. Importantly, we demonstrate that 4$e$ condensation dominates over 2$e$ condensation even for nearly decoupled orbitals, a scenario suitable for experiments with ultracold atoms in the form of almost decoupled chains. Our model paves the way for both experimental and theoretical exploration of 4$e$ superconductivity and provides a natural starting point for future studies beyond one dimension or more intricate 4$e$ states.

Published

2023

18. 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

19. Van-Hove tuning of Fermi surface instabilities through compensated metallicity

Author

Hohmann, Hendrik, Dürrnagel, Matteo, Bunney, Matthew, Schwemmer, Tilman, Neupert, Titus, Rachel, Stephan, and Thomale, Ronny

Subjects

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

Abstract

Van-Hove (vH) singularities in the vicinity of the Fermi level facilitate the emergence of electronically mediated Fermi surface instabilities. This is because they provide a momentum-localized enhancement of density of states enhancing selective electronic scattering channels. High-temperature topological superconductivity has been argued for in graphene at vH filling which, however, has so far proven inaccessible due to the demanded large doping from pristine half filling. We propose compensated metallicity as a path to unlock vH-driven pairing close to half filling in an electronic honeycomb lattice model. It is enabled through the strong breaking of chiral symmetry from intra-sublattice hybridization, leading to the emergence of a hole pocket (hp) nearby the van-Hove points $M$ at the Brillouin zone boundary and an electron pocket (ep) around the zone center $\Gamma$. While the ep is radially symmetric and barely contributing to the electronic ordering selection, the hp is dominated by its vH signature and yields electronic order at elevated scales., Comment: 4 pages, 2 figures

Published

2023

20. Chiral kagome superconductivity modulations with residual Fermi arcs

Author

Deng, Hanbin, Qin, Hailang, Liu, Guowei, Yang, Tianyu, Fu, Ruiqing, Zhang, Zhongyi, Wu, Xianxin, Wang, Zhiwei, Shi, Youguo, Liu, Jinjin, Liu, Hongxiong, Yan, Xiao-Yu, Song, Wei, Xu, Xitong, Zhao, Yuanyuan, Yi, Mingsheng, Xu, Gang, Hohmann, Hendrik, Holbæk, Sofie Castro, Dürrnagel, Matteo, Zhou, Sen, Chang, Guoqing, Yao, Yugui, Wang, Qianghua, Guguchia, Zurab, Neupert, Titus, Thomale, Ronny, Fischer, Mark H., and Yin, Jia-Xin

Published

2024

21. 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

22. Topology of SmB6 revisited by means of topological quantum chemistry

Author

Iraola, Mikel, Robredo, Iñigo, Neupert, TItus, Mañes, Juan L., Valentí, Roser, and Vergniory, Maia G.

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

The mixed-valence compound SmB6 with partially filled samarium 4f flat bands hybridizing with 5d conduction bands is a paramount example of a correlated topological heavy-fermion system. In this study we revisit the topology of SmB6 with the band theory paradigm and uncover previously overlooked aspects resulting from the formation of multiple topological gaps in the electronic structure. By invoking topological quantum chemistry (TQC) we provide a detailed classification of the strong and crystalline topological features that derive from the existence of such topological gaps. To corroborate this classification, we calculate Wilson loops and simulate the surface electronic structure using a minimal tight-binding model, allowing us to describe its surface states and confirm the crystalline topology. We finally discuss its implications for experiments.

Published

2023

23. $\require{mhchem}$Quantum paramagnetism in the decorated square-kagome antiferromagnet $\ce{Na6Cu7BiO4(PO4)4Cl3}$

Author

Niggemann, Nils, Astrakhantsev, Nikita, Ralko, Arnaud, Ferrari, Francesco, Maity, Atanu, Müller, Tobias, Richter, Johannes, Thomale, Ronny, Neupert, Titus, Reuther, Johannes, Iqbal, Yasir, and Jeschke, Harald O.

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

$\require{mhchem}$The square-kagome lattice Heisenberg antiferromagnet is a highly frustrated Hamiltonian whose material realizations have been scarce. We theoretically investigate the recently synthesized $\ce{Na6Cu7BiO4(PO4)4Cl3}$ where a Cu$^{2+}$ spin-$1/2$ square-kagome lattice (with six site unit cell) is decorated by a seventh magnetic site alternatingly above and below the layers. The material does not show any sign of long-range magnetic order down to 50 mK despite a Curie-Weiss temperature of $-212$ K indicating a quantum paramagnetic phase. Our DFT energy mapping elicits a purely antiferromagnetic Hamiltonian that features longer range exchange interactions beyond the pure square-kagome model and, importantly, we find the seventh site to be strongly coupled to the plane. We combine two variational Monte Carlo approaches, pseudo-fermion/Majorana functional renormalization group and Schwinger-Boson mean field calculations to show that the complex Hamiltonian of $\ce{Na6Cu7BiO4(PO4)4Cl3}$ still features a nonmagnetic ground state. We explain how the seventh Cu$^{2+}$ site actually aids the stabilization of the disordered state. We predict static and dynamic spin structure factors to guide future neutron scattering experiments., Comment: 5 pages, 4 figures. Supplement: 7 pages, 11 figures v2: minor revisions in text and figure labels

Published

2023

24. Non-Hermitian Mott Skin Effect

Author

Yoshida, Tsuneya, Zhang, Song-Bo, Neupert, Titus, and Kawakami, Norio

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Quantum Gases, Condensed Matter - Statistical Mechanics, Quantum Physics

Abstract

We propose a novel type of skin effects in non-Hermitian quantum many-body systems which we dub a non-Hermitian Mott skin effect. This phenomenon is induced by the interplay between strong correlations and the non-Hermitian point-gap topology. The Mott skin effect induces extreme sensitivity to the boundary conditions only in the spin degree of freedom (i.e., the charge distribution is not sensitive to boundary conditions), which is in sharp contrast to the ordinary non-Hermitian skin effect in non-interacting systems. Concretely, we elucidate that a bosonic non-Hermitian chain exhibits the Mott skin effect in the strongly correlated regime by closely examining an effective Hamiltonian. The emergence of the Mott skin effect is also supported by numerical diagonalization of the bosonic chain. The difference between the ordinary non-Hermitian skin effect and the Mott skin effect is also reflected in the time-evolution of physical quantities; under the time-evolution spin accumulation is observed while the charge distribution remains spatially uniform., Comment: 8+17 pages, 3+16 figures, discussions of Liouvillian dynamics are revised

Published

2023

25. Understanding Symmetry Breaking in Twisted Bilayer Graphene from Cluster Constraints

Author

Astrakhantsev, Nikita, Wagner, Glenn, Westerhout, Tom, Neupert, Titus, and Fischer, Mark H.

Subjects

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

Abstract

Twisted bilayer graphene is an exciting platform for exploring correlated quantum phases, extremely tunable with respect to both the single-particle bands and the interaction profile of electrons. Here, we investigate the phase diagram of twisted bilayer graphene as described by an extended Hubbard model on the honeycomb lattice with two fermionic orbitals (valleys) per site. Besides the special extended {\it cluster interaction} $Q$, we incorporate the effect of gating through an onsite Hubbard-interaction $U$. Within Quantum Monte Carlo (QMC), we find valence-bond-solid, N\'eel-valley antiferromagnetic or charge-density wave phases. Further, we elucidate the competition of these phases by noticing that the cluster interaction induces an exotic constraint on the Hilbert space, which we dub {\it the cluster rule}, in analogy to the famous pyrochlore spin-ice rule. Formulating the perturbative Hamiltonian by projecting into the cluster-rule manifold, we perform exact diagonalization and construct the fixed-point states of the observed phases. Finally, we compute the local electron density patterns as signatures distinguishing these phases, which could be observed with scanning tunneling microscopy. Our work capitalizes on the notion of cluster constraints in the extended Hubbard model of twisted bilayer graphene, and suggests a scheme towards realization of several symmetry-breaking insulating phases in a twisted-bilayer graphene sheet., Comment: 10 pages, 6 figures

Published

2023

26. Hyperbolic non-Abelian semimetal

Author

Tummuru, Tarun, Chen, Anffany, Lenggenhager, Patrick M., Neupert, Titus, Maciejko, Joseph, and Bzdušek, Tomáš

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Other Condensed Matter, Quantum Physics

Abstract

We extend the notion of topologically protected semi-metallic band crossings to hyperbolic lattices in a negatively curved plane. Because of their distinct translation group structure, such lattices are associated with a high-dimensional reciprocal space. In addition, they support non-Abelian Bloch states which, unlike conventional Bloch states, acquire a matrix-valued Bloch factor under lattice translations. Combining diverse numerical and analytical approaches, we uncover an unconventional scaling in the density of states at low energies, and illuminate a nodal manifold of codimension five in the reciprocal space. The nodal manifold is topologically protected by a nonzero second Chern number, reminiscent of the characterization of Weyl nodes by the first Chern number., Comment: 5 pages (4 figures) + 15 pages of supplementary material (9 figures)

Published

2023

27. Two-dimensional Shiba lattices as possible platform for crystalline topological superconductivity

Author

Soldini, Martina O., Küster, Felix, Wagner, Glenn, Das, Souvik, Aldarawsheh, Amal, Thomale, Ronny, Lounis, Samir, Parkin, Stuart S. P., Sessi, Paolo, and Neupert, Titus

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Superconductivity

Abstract

Localized or propagating Majorana boundary modes are the key feature of topological superconductors. They are rare in naturally-occurring compounds, but the tailored manipulation of quantum matter offers opportunities for their realization. Specifically, lattices of Yu-Shiba-Rusinov bound states $-$ Shiba lattices $-$ that arise when magnetic adatoms are placed on the surface of a conventional superconductor can be used to create topological bands within the superconducting gap of the substrate. Here, using scanning tunnelling microscopy to create and probe adatom lattices with single atom precision we reveal two signatures consistent with the realization of two types of mirror symmetry protected topological superconductors. The first has edge modes as well as higher-order corner states, and the second has symmetry-protected bulk nodal points. In principle, their topological character and boundary modes should be protected by the spatial symmetries of the adatom lattice. Our results highlight the potential of Shiba lattices as a platform to design the topology and sample geometry of 2D superconductors., Comment: Published in Nature Physics (https://doi.org/10.1038/s41567-023-02104-5)

Published

2023

28. Phenomenology of bond and flux orders in kagome metals

Author

Wagner, Glenn, Guo, Chunyu, Moll, Philip J. W., Neupert, Titus, and Fischer, Mark H.

Subjects

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

Abstract

Despite much experimental and theoretical work, the nature of the charge order in the kagome metals belonging to the family of materials AV$_3$Sb$_5$ (A=Cs,Rb,K) remains controversial. A crucial ingredient for the identification of the ordering in these materials is their response to external perturbations, such as strain or magnetic fields. To this end, we provide a comprehensive symmetry classification of the possible charge orders in kagome materials with a $2\times2$ increase of the unit cell. Motivated by the experimental reports of time-reversal-symmetry breaking and rotational anisotropy, we consider the interdependence of flux and bond orders. Deriving the relevant Landau free energy for possible orders, we study the effect of symmetry-breaking perturbations such as strain and magnetic fields. Our results, thus, provide a roadmap for future tests of these intricate orders., Comment: 15 pages (+7 pages appendix), 4 figures (+6 figures appendix), included corrections as published under "Erratum Phys. Rev. B 110, 159901 (2024)"

Published

2023

29. Distinct switching of chiral transport in the kagome metals KV$_3$Sb$_5$ and CsV$_3$Sb$_5$

Author

Guo, Chunyu, van Delft, Maarten R., Gutierrez-Amigo, Martin, Chen, Dong, Putzke, Carsten, Wagner, Glenn, Fischer, Mark H., Neupert, Titus, Errea, Ion, Vergniory, Maia G., Wiedmann, Steffen, Felser, Claudia, and Moll, Philip J. W.

Subjects

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

Abstract

The kagome metals AV$_3$Sb$_5$ (A=K,Rb,Cs) present an ideal sandbox to study the interrelation between multiple coexisting correlated phases such as charge order and superconductivity. So far, no consensus on the microscopic nature of these states has been reached as the proposals struggle to explain all their exotic physical properties. Among these, field-switchable electric magneto-chiral anisotropy (eMChA) in CsV$_3$Sb$_5$ provides intriguing evidence for a rewindable electronic chirality, yet the other family members have not been likewise investigated. Here, we present a comparative study of magneto-chiral transport between CsV$_3$Sb$_5$ and KV$_3$Sb$_5$. Despite their similar electronic structure, KV$_3$Sb$_5$ displays negligible eMChA, if any, and with no field switchability. This is in stark contrast to the non-saturating eMChA in CsV$_3$Sb$_5$ even in high fields up to 35 T. In light of their similar band structures, the stark difference in eMChA suggests its origin in the correlated states. Clearly, the V kagome nets alone are not sufficient to describe the physics and the interactions with their environment are crucial in determining the nature of their low-temperature state.

Published

2023

30. Finite-momentum Cooper pairing in proximitized altermagnets

Author

Zhang, Song-Bo, Hu, Lun-Hui, and Neupert, Titus

Published

2024

31. Distinct switching of chiral transport in the kagome metals KV3Sb5 and CsV3Sb5

Author

Guo, Chunyu, van Delft, Maarten R., Gutierrez-Amigo, Martin, Chen, Dong, Putzke, Carsten, Wagner, Glenn, Fischer, Mark H., Neupert, Titus, Errea, Ion, Vergniory, Maia G., Wiedmann, Steffen, Felser, Claudia, and Moll, Philip J. W.

Published

2024

32. 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

33. 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

34. Correlated order at the tipping point in the kagome metal CsV3Sb5

Author

Guo, Chunyu, Wagner, Glenn, Putzke, Carsten, Chen, Dong, Wang, Kaize, Zhang, Ling, Gutierrez-Amigo, Martin, Errea, Ion, Vergniory, Maia G., Felser, Claudia, Fischer, Mark H., Neupert, Titus, and Moll, Philip J. W.

Published

2024

35. Infernal and Exceptional Edge Modes: Non-Hermitian Topology Beyond the Skin Effect

Author

Denner, M. Michael, Neupert, Titus, and Schindler, Frank

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

The classification of point gap topology in all local non-Hermitian symmetry classes has been recently established. However, many entries in the resulting periodic table have only been discussed in a formal setting and still lack a physical interpretation in terms of their bulk-boundary correspondence. Here, we derive the edge signatures of all two-dimensional phases with intrinsic point gap topology. While in one dimension point gap topology invariably leads to the non-Hermitian skin effect, non-Hermitian boundary physics is significantly richer in two dimensions. We find two broad classes of non-Hermitian edge states: (1) Infernal points, where a skin effect occurs only at a single edge momentum, while all other edge momenta are devoid of edge states. Under semi-infinite boundary conditions, the point gap thereby closes completely, but only at a single edge momentum. (2) Non-Hermitian exceptional point dispersions, where edge states persist at all edge momenta and furnish an anomalous number of symmetry-protected exceptional points. Surprisingly, the latter class of systems allows for a finite, non-extensive number of edge states with a well defined dispersion along all generic edge terminations. Instead, the point gap only closes along the real and imaginary eigenvalue axes, realizing a novel form of non-Hermitian spectral flow., Comment: 6 pages, 3 figures, 13 pages supplementary material

Published

2023

36. Correlated order at the tipping point in the kagome metal CsV$_3$Sb$_5$

Author

Guo, Chunyu, Wagner, Glenn, Putzke, Carsten, Chen, Dong, Wang, Kaize, Zhang, Ling, Gutierrez-Amigo, Martin, Errea, Ion, Vergniory, Maia G., Felser, Claudia, Fischer, Mark H., Neupert, Titus, and Moll, Philip J. W.

Subjects

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

Abstract

Spontaneously broken symmetries are at the heart of many phenomena of quantum matter and physics more generally. However, determining the exact symmetries broken can be challenging due to imperfections such as strain, in particular when multiple electronic orders form complex interactions. This is exemplified by charge order in some kagome systems, which are speculated to show nematicity and flux order from orbital currents. We fabricated highly symmetric samples of a member of this family, CsV$_3$Sb$_5$, and measured their transport properties. We find the absence of measurable anisotropy at any temperature in the unperturbed material, however, a striking in-plane transport anisotropy appears when either weak magnetic fields or strains are present. A symmetry analysis indicates that a perpendicular magnetic field can indeed lead to in-plane anisotropy by inducing a flux order coexisting with more conventional bond order. Our results provide a unifying picture for the controversial charge order in kagome metals and highlight the need for microscopic materials control in the identification of broken symmetries.

Published

2023

37. Single-parameter variational wavefunctions for quantum Hall bilayers

Author

Hu, Qi, Neupert, Titus, and Wagner, Glenn

Subjects

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

Abstract

Bilayer quantum Hall states have been shown to be described by a BCS-paired state of composite fermions. However, finding a qualitatively accurate model state valid across all values of the bilayer separation is challenging. Here, we introduce two variational wavefunctions, each with a single variational parameter, which can be thought of as a proxy for the BCS order parameter. Studying systems of up to 9+9 electrons in a spherical geometry using Monte Carlo methods, we show that the ground state can be accurately described by these single-parameter variational states. In addition, for the first time we provide a numerically exact wavefunction for the Halperin-111 state in terms of composite fermions., Comment: 7 pages + 3 figures main text (7 pages + 4 figures supplement)

Published

2023

38. Finite-momentum Cooper pairing in proximitized altermagnets

Author

Zhang, Song-Bo, Hu, Lun-Hui, and Neupert, Titus

Subjects

Condensed Matter - Superconductivity

Abstract

Finite-momentum Cooper pairing is an unconventional form of superconductivity that is widely believed to require finite magnetization. Altermagnetism is an emerging magnetic phase with highly anisotropic spin-splitting of specific symmetries, but zero net magnetization. Here, we study Cooper pairing in metallic altermagnets connected to conventional $s$-wave superconductors. Remarkably, we find that the Cooper pairs induced in the altermagnets acquire a finite centre-of-mass momentum, despite the \textit{zero} net magnetization in the system. This anomalous Cooper-pair momentum strongly depends on the propagation direction and exhibits unusual symmetric patterns. Furthermore, it yields several unique features: (i) highly orientation-dependent oscillations in the order parameter, (ii) controllable 0-$\pi$ transitions in the Josephson supercurrent, (iii) large-oblique-angle Cooper-pair transfer trajectories in junctions parallel with the direction where spin splitting vanishes, and (iv) distinct Fraunhofer patterns in junctions oriented along different directions. Finally, we discuss the implementation of our predictions in candidate materials such as RuO$_{2}$ and KRu$_{4}$O$_{8}$., Comment: 11 pages, 6 figures, Published in Nature Communications

Published

2023

39. A Hybrid Quantum-Classical Method for Electron-Phonon Systems

Author

Denner, M. Michael, Miessen, Alexander, Yan, Haoran, Tavernelli, Ivano, Neupert, Titus, Demler, Eugene, and Wang, Yao

Subjects

Condensed Matter - Strongly Correlated Electrons, Quantum Physics

Abstract

Interactions between electrons and phonons play a crucial role in quantum materials. Yet, there is no universal method that would simultaneously accurately account for strong electron-phonon interactions and electronic correlations. By combining methods of the variational quantum eigensolver and the variational non-Gaussian solver, we develop a hybrid quantum-classical algorithm suitable for this type of correlated systems. This hybrid method tackles systems with arbitrarily strong electron-phonon coupling without increasing the number of required qubits and quantum gates, as compared to purely electronic models. We benchmark the new method by applying it to the paradigmatic Hubbard-Holstein model at half filling, and show that it correctly captures the competition between charge density wave and antiferromagnetic phases, quantitatively consistent with exact diagonalization., Comment: 8 pages, 4 figures; 4 pages Supplemental Material

Published

2023

40. Variational Benchmarks for Quantum Many-Body Problems

Author

Wu, Dian, Rossi, Riccardo, Vicentini, Filippo, Astrakhantsev, Nikita, Becca, Federico, Cao, Xiaodong, Carrasquilla, Juan, Ferrari, Francesco, Georges, Antoine, Hibat-Allah, Mohamed, Imada, Masatoshi, Läuchli, Andreas M., Mazzola, Guglielmo, Mezzacapo, Antonio, Millis, Andrew, Moreno, Javier Robledo, Neupert, Titus, Nomura, Yusuke, Nys, Jannes, Parcollet, Olivier, Pohle, Rico, Romero, Imelda, Schmid, Michael, Silvester, J. Maxwell, Sorella, Sandro, Tocchio, Luca F., Wang, Lei, White, Steven R., Wietek, Alexander, Yang, Qi, Yang, Yiqi, Zhang, Shiwei, and Carleo, Giuseppe

Subjects

Quantum Physics, Condensed Matter - Strongly Correlated Electrons, Physics - Computational Physics

Abstract

The continued development of computational approaches to many-body ground-state problems in physics and chemistry calls for a consistent way to assess its overall progress. In this work, we introduce a metric of variational accuracy, the V-score, obtained from the variational energy and its variance. We provide an extensive curated dataset of variational calculations of many-body quantum systems, identifying cases where state-of-the-art numerical approaches show limited accuracy, and future algorithms or computational platforms, such as quantum computing, could provide improved accuracy. The V-score can be used as a metric to assess the progress of quantum variational methods toward a quantum advantage for ground-state problems, especially in regimes where classical verifiability is impossible., Comment: 27 pages, 6 figures

Published

2023

41. Single monkey-saddle singularity of a Fermi surface and its instabilities

Author

Aksoy, Ömer M., Chandrasekaran, Anirudh, Tiwari, Apoorv, Neupert, Titus, Chamon, Claudio, and Mudry, Christopher

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Fermi surfaces can undergo sharp transitions under smooth changes of parameters. Such transitions can have a topological character, as is the case when a higher-order singularity, one that requires cubic or higher-order terms to describe the electronic dispersion near the singularity, develops at the transition. When time-reversal and inversion symmetries are present, odd singularities can only appear in pairs within the Brillouin zone. In this case, the combination of the enhanced density of states that accompany these singularities and the nesting between the pairs of singularities leads to interaction driven instabilities. We present examples of single $n=3$ (monkey saddle) singularities when time-reversal and inversion symmetries are broken. We then turn to the question of what instabilities are possible when the singularities are isolated. For spinful electrons, we find that the inclusion of repulsive interactions destroys any isolated monkey-saddle singularity present in the noninteracting spectrum by developing Stoner or Lifshitz instabilities. In contrast, for spinless electrons and at the mean-field level, we show that an isolated monkey-saddle singularity can be stabilized in the presence of short-range repulsive interactions., Comment: 13 pages, 7 figures

Published

2023

42. Enhancement of Second-Order Non-Hermitian Skin Effect by Magnetic Fields

Author

Li, Chang-An, Trauzettel, Björn, Neupert, Titus, and Zhang, Song-Bo

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The non-Hermitian skin effect is a unique phenomenon in which an extensive number of eigenstates are localized at the boundaries of a non-Hermitian system. Recent studies show that the non-Hermitian skin effect is significantly suppressed by magnetic fields. In contrast, we demonstrate that the second-order skin effect (SOSE) is robust and can even be enhanced by magnetic fields. Remarkably, SOSE can also be induced by magnetic fields from a trivial non-Hermitian system that does not experience any skin effect at zero field. These properties are intimately related to to the persistence and emergence of topological line gaps in the complex energy spectrum in presence of magnetic fields. Moreover, we show that a magnetic field can drive a non-Hermitian system from a hybrid skin effect, where the first-order skin effect and SOSE coexist, to pure SOSE. Our results describe a qualitatively new magnetic field behavior of the non-Hermitian skin effect., Comment: 8+9 pages, 4+12 figures

Published

2022

43. Interacting topological quantum chemistry of Mott atomic limits

Author

Soldini, Martina O., Astrakhantsev, Nikita, Iraola, Mikel, Tiwari, Apoorv, Fischer, Mark H., Valentí, Roser, Vergniory, Maia G., Wagner, Glenn, and Neupert, Titus

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Topological quantum chemistry (TQC) is a successful framework for identifying (noninteracting) topological materials. Based on the symmetry eigenvalues of Bloch eigenstates at maximal momenta, which are attainable from first principles calculations, a band structure can either be classified as an atomic limit, in other words adiabatically connected to independent electronic orbitals on the respective crystal lattice, or it is topological. For interacting systems, there is no single-particle band structure and hence, the TQC machinery grinds to a halt. We develop a framework analogous to TQC, but employing $n$-particle Green's function to classify interacting systems. Fundamentally, we define a class of interacting reference states that generalize the notion of atomic limits, which we call Mott atomic limits, and are symmetry protected topological states. Our formalism allows to fully classify these reference states (with $n=2$), which can themselves represent symmetry protected topological states. We present a comprehensive classification of such states in one-dimension and provide numerical results on model systems. With this, we establish Mott atomic limit states as a generalization of the atomic limits to interacting systems.

Published

2022

44. Weak-signal extraction enabled by deep-neural-network denoising of diffraction data

Author

Oppliger, Jens, Denner, M. Michael, Küspert, Julia, Frison, Ruggero, Wang, Qisi, Morawietz, Alexander, Ivashko, Oleh, Dippel, Ann-Christin, von Zimmermann, Martin, Biało, Izabela, Martinelli, Leonardo, Fauqué, Benoît, Choi, Jaewon, Garcia-Fernandez, Mirian, Zhou, Ke-Jin, Christensen, Niels B., Kurosawa, Tohru, Momono, Naoki, Oda, Migaku, Natterer, Fabian D., Fischer, Mark H., Neupert, Titus, and Chang, Johan

Subjects

Electrical Engineering and Systems Science - Image and Video Processing, Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Superconductivity, Computer Science - Machine Learning

Abstract

Removal or cancellation of noise has wide-spread applications for imaging and acoustics. In every-day-life applications, denoising may even include generative aspects, which are unfaithful to the ground truth. For scientific use, however, denoising must reproduce the ground truth accurately. Here, we show how data can be denoised via a deep convolutional neural network such that weak signals appear with quantitative accuracy. In particular, we study X-ray diffraction on crystalline materials. We demonstrate that weak signals stemming from charge ordering, insignificant in the noisy data, become visible and accurate in the denoised data. This success is enabled by supervised training of a deep neural network with pairs of measured low- and high-noise data. We demonstrate that using artificial noise does not yield such quantitatively accurate results. Our approach thus illustrates a practical strategy for noise filtering that can be applied to challenging acquisition problems., Comment: 14 pages, 10 figures; extended study, additional supplementary information, results unchanged

Published

2022

45. Theory of Glide Symmetry Protected Helical Edge States in WTe$_{2}$ Monolayer

Author

Bieniek, Maciej, Väyrynen, Jukka I., Li, Gang, Neupert, Titus, and Thomale, Ronny

Subjects

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

Abstract

Helical edge states in quantum spin Hall (QSH) materials are central building blocks of topological matter design and engineering. Despite their principal topological protection against elastic backscattering, the level of operational stability depends on manifold parameters such as the band gap of the given semiconductor system in the 'inverted' regime, temperature, disorder, and crystal orientation. We theoretically investigate electronic and transport properties of QSH edge states in large gap 1-T' WTe$_{2}$ monolayers. We explore the impact of edge termination, disorder, temperature, and interactions on experimentally addressable edge state observables, such as local density of states and conductance. We show that conductance quantization can remain surprisingly robust even for heavily disordered samples because of an anomalously small edge state decay length and additional protection related to the large direct gap allowed by glide symmetry. From the simulation of temperature-dependent resistance, we find that moderate disorder enhances the stability of conductance by localizing bulk states. We evaluate the edge state velocity and Luttinger liquid parameter as functions of the chemical potential, finding prospects for physics beyond linear helical Luttinger liquids in samples with ultra-clean and well-defined edges.

Published

2022

46. Interaction effects in a 1D flat band at a topological crystalline step edge

Author

Wagner, Glenn, Das, Souvik, Jung, Johannes, Odobesko, Artem, Küster, Felix, Keller, Florian, Korczak, Jedrzej, Szczerbakow, Andrzej, Story, Tomasz, Parkin, Stuart, Thomale, Ronny, Neupert, Titus, Bode, Matthias, and Sessi, Paolo

Subjects

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

Abstract

Step edges of topological crystalline insulators can be viewed as predecessors of higher-order topology, as they embody one-dimensional edge channels embedded in an effective three-dimensional electronic vacuum emanating from the topological crystalline insulator. Using scanning tunneling microscopy and spectroscopy we investigate the behaviour of such edge channels in Pb$_{1-x}$Sn$_{x}$Se under doping. Once the energy position of the step edge is brought close to the Fermi level, we observe the opening of a correlation gap. The experimental results are rationalized in terms of interaction effects which are enhanced since the electronic density is collapsed to a one-dimensional channel. This constitutes a unique system to study how topology and many-body electronic effects intertwine, which we model theoretically through a Hartree-Fock analysis., Comment: 8 pages, 5 figures (main text) and 5 pages, 6 figures (Supplementary Material)

Published

2022

47. Weak signal extraction enabled by deep neural network denoising of diffraction data

Author

Oppliger, Jens, Denner, M. Michael, Küspert, Julia, Frison, Ruggero, Wang, Qisi, Morawietz, Alexander, Ivashko, Oleh, Dippel, Ann-Christin, Zimmermann, Martin von, Biało, Izabela, Martinelli, Leonardo, Fauqué, Benoît, Choi, Jaewon, Garcia-Fernandez, Mirian, Zhou, Ke-Jin, Christensen, Niels Bech, Kurosawa, Tohru, Momono, Naoki, Oda, Migaku, Natterer, Fabian D., Fischer, Mark H., Neupert, Titus, and Chang, Johan

Published

2024

48. Topological Zero-Dimensional Defect and Flux States in Three-Dimensional Insulators

Author

Schindler, Frank, Tsirkin, Stepan S., Neupert, Titus, Bernevig, B. Andrei, and Wieder, Benjamin J.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

In insulating crystals, it was previously shown that defects with two fewer dimensions than the bulk can bind topological electronic states. We here further extend the classification of topological defect states by demonstrating that the corners of crystalline defects with integer Burgers vectors can bind 0D higher-order end (HEND) states with anomalous charge and spin. We demonstrate that HEND states are intrinsic topological consequences of the bulk electronic structure and introduce new bulk topological invariants that are predictive of HEND dislocation states in solid-state materials. We demonstrate the presence of first-order 0D defect states in PbTe monolayers and HEND states in 3D SnTe crystals. We relate our analysis to magnetic flux insertion in insulating crystals. We find that $\pi$-flux tubes in inversion- and time-reversal-symmetric (helical) higher-order topological insulators bind Kramers pairs of spin-charge-separated HEND states, which represent observable signatures of anomalous surface half quantum spin Hall states., Comment: Final version, 23 pg main text + 76 pg appendix, 8 + 24 figures

Published

2022

49. Pinch-points to half-moons and up in the stars: the kagome skymap

Author

Kiese, Dominik, Ferrari, Francesco, Astrakhantsev, Nikita, Niggemann, Nils, Ghosh, Pratyay, Müller, Tobias, Thomale, Ronny, Neupert, Titus, Reuther, Johannes, Gingras, Michel J. P., Trebst, Simon, and Iqbal, Yasir

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Pinch point singularities, associated with flat band magnetic excitations, are tell-tale signatures of Coulomb spin liquids. While their properties in the presence of quantum fluctuations have been widely studied, the fate of the complementary non-analytic features -- shaped as half-moons and stars -- arising from adjacent shallow dispersive bands has remained unexplored. Here, we address this question for the spin $S=1/2$ Heisenberg antiferromagnet on the kagome lattice with second and third neighbor couplings, which allows one to tune the classical ground state from flat bands to being governed by shallow dispersive bands for intermediate coupling strengths. Employing the complementary strengths of variational Monte Carlo, pseudo-fermion functional renormalization group, and density-matrix renormalization group, we establish the quantum phase diagram. The U(1) Dirac spin liquid ground state of the nearest-neighbor antiferromagnet remains remarkably robust till intermediate coupling strengths when it transitions into a pinwheel valence bond crystal displaying signatures of half-moons in its structure factor. Our work thus identifies a microscopic setting that realizes one of the proximate orders of the Dirac spin liquid identified in a recent work [Song, Wang, Vishwanath, He, Nat. Commun. 10, 4254 (2019)]. For larger couplings, we obtain a collinear magnetically ordered ground state characterized by star-like patterns., Comment: 7 pages, 5 figures. Supplemental Material appended

Published

2022

50. Hyperbolic Matter in Electrical Circuits with Tunable Complex Phases

Author

Chen, Anffany, Brand, Hauke, Helbig, Tobias, Hofmann, Tobias, Imhof, Stefan, Fritzsche, Alexander, Kießling, Tobias, Stegmaier, Alexander, Upreti, Lavi K., Neupert, Titus, Bzdušek, Tomáš, Greiter, Martin, Thomale, Ronny, and Boettcher, Igor

Subjects

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

Abstract

Curved spaces play a fundamental role in many areas of modern physics, from cosmological length scales to subatomic structures related to quantum information and quantum gravity. In tabletop experiments, negatively curved spaces can be simulated with hyperbolic lattices. Here we introduce and experimentally realize hyperbolic matter as a paradigm for topological states through topolectrical circuit networks relying on a complex-phase circuit element. The experiment is based on hyperbolic band theory that we confirm here in an unprecedented numerical survey of finite hyperbolic lattices. We implement hyperbolic graphene as an example of topologically nontrivial hyperbolic matter. Our work sets the stage to realize more complex forms of hyperbolic matter to challenge our established theories of physics in curved space, while the tunable complex-phase element developed here can be a key ingredient for future experimental simulation of various Hamiltonians with topological ground states., Comment: 6 pages + methods + supplementary information

Published

2022