Your search keyword '"Jia, Chunjing"' showing total 182 results

1. Detection of chiral spin fluctuations driven by frustration in Mott insulators

Author

Hsu, Kuan H., Jia, Chunjing, Zhang, Emily Z., Jost, Daniel, Moritz, Brian, Hackl, Rudi, and Devereaux, Thomas P.

Subjects

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

Abstract

Topologically ordered states, such as chiral spin liquids, have been proposed as candidates that host fractionalized excitations. However, detecting chiral character or proximity to these non-trivial states remains a challenge. Resonant Raman scattering can be a powerful tool for detecting chiral fluctuations, as the $A_{2g}$ channel probes excitations with broken time-reversal symmetry and local chiral order. Here, we use exact diagonalization to characterize the resonant $A_{2g}$ channel, alongside two-magnon scattering in $B_{1g}$ and $E_g$ channels, for the Hubbard model on lattices with increasing levels of geometric spin frustration, where tuning the incident energy near the Mott gap reveals strong chiral spin excitation intensity. Increased spin frustration in the Mott insulator results in an overall softening of the Raman $A_{2g}$ response, indicating a tendency toward low energy chiral-chiral fluctuations in Mott insulators with magnetic frustration and proximity to chiral spin liquid states that can potentially be tuned by external perturbations., Comment: 7+5 pages, 6+3 figures

Published

2025

2. Structural and Electronic Evolution of Bilayer Nickelates Under Biaxial Strain

Author

Bhatta, H C Regan B., Zhang, Xiaoliang, Zhong, Yong, and Jia, Chunjing

Subjects

Condensed Matter - Superconductivity

Abstract

The discovery of high-Tc superconductivity around 80K in bilayer nickelate La3Ni2O7 under high pressure has expanded the family of high-Tc superconductors above the nitrogen boiling temperature. Recent studies have further shown that ambient pressure superconductivity with a Tc exceeding 40K can be achieved in compressively strained La3Ni2O7 thin films, offering a tunable platform for investigating the pairing mechanism in high-Tc nickelates. A comprehensive understanding of the structural and electronic properties of bilayer nickelate under epitaxial strain is essential to advance this active field. In this work, we employ first-principles calculations to systematically explore the entire rare-earth (Re) series of bilayer nickelates Re3Ni2O7 in the realistic orthorhombic Amam phase under various compressive and tensile strain conditions. We highlight the materials properties change when strain is applied, and compare these results with those observed under high pressure. Our findings show that 2.5\% compressive strain increases the apical Ni-O-Ni bond angle toward 180 degree, and causes the Ni $d_{z^2}$ bands to move away from the Fermi level. The tight-binding parameters for the 2.5\% compressively strained La3Ni2O7 are quite similar to those of the unstrained material, except that the on-site energy difference between the Ni $d_{z^2}$ and $d_{x^2-y^2}$ orbitals increases by about 50 percent. Notably, the absence of the $d_{z^2}$ bands at the Fermi energy under compressive strain contrasts sharply with the electronic structure in the high-pressure {\it Fmmm} phase, suggesting that the presence of $d_{z^2}$ bands at the Fermi energy may not be a requisite for superconductivity.

Published

2025

3. Altermagnetism and Strain Induced Altermagnetic Transition in Cairo Pentagonal Monolayer

Author

Li, Shuyi, Zhang, Yu, Bahri, Adrian, Zhang, Xiaoliang, and Jia, Chunjing

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Altermagnetism, a recently discovered class of magnetic order characterized by vanishing net magnetization and spin-splitting band structures, has garnered significant research attention. In this work, we introduce a novel two-dimensional system that exhibits $g$-wave altermagnetism and undergoes a strain-induced transition from $g$-wave to $d$-wave altermagnetism. This system can be realized in an unconventional monolayer Cairo pentagonal lattice, for which we present a realistic tight-binding model that incorporates both magnetic and non-magnetic sites. Furthermore, we demonstrate that non-trivial band topology can emerge in this system by breaking the symmetry that protects the spin-polarized nodal points. Finally, \emph{ab initio} calculations on several candidate materials, such as FeS$_2$ and Nb$_2$FeB$_2$, which exhibit symmetry consistent with the proposed tight-binding Hamiltonian, are also presented. These findings open new avenues for exploring spintronic devices based on altermagnetic systems.

Published

2024

4. Orbital inversion and emergent lattice dynamics in infinite layer CaCoO$_2$

Author

Jost, Daniel, Lomeli, Eder G., Kim, Woo Jin, Been, Emily M., Rossi, Matteo, Agrestini, Stefano, Zhou, Kejin, Jia, Chunjing, Moritz, Brian, Shen, Zhi-Xun, Hwang, Harold Y., Devereaux, Thomas P., and Lee, Wei-Sheng

Subjects

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

Abstract

The layered cobaltate CaCoO$_2$ exhibits a unique herringbone-like structure. Serving as a potential prototype for a new class of complex lattice patterns, we study the properties of CaCoO$_2$ using X-ray absorption spectroscopy (XAS) and resonant inelastic X-ray scattering (RIXS). Our results reveal a significant inter-plane hybridization between the Ca $4s-$ and Co $3d-$orbitals, leading to an inversion of the textbook orbital occupation of a square planar geometry. Further, our RIXS data reveal a strong low energy mode, with anomalous intensity modulations as a function of momentum transfer close to a quasi-static response suggestive of electronic and/or orbital ordering. These findings indicate that the newly discovered herringbone structure exhibited in CaCoO$_2$ may serve as a promising laboratory for the design of materials having strong electronic, orbital and lattice correlations.

Published

2024

5. Active Learning for Discovering Complex Phase Diagrams with Gaussian Processes

Author

Zhu, Max, Yao, Jian, Mynatt, Marcus, Pugzlys, Hubert, Li, Shuyi, Bacallado, Sergio, Zhao, Qingyuan, and Jia, Chunjing

Subjects

Physics - Computational Physics

Abstract

We introduce a Bayesian active learning algorithm that efficiently elucidates phase diagrams. Using a novel acquisition function that assesses both the impact and likelihood of the next observation, the algorithm iteratively determines the most informative next experiment to conduct and rapidly discerns the phase diagrams with multiple phases. Comparative studies against existing methods highlight the superior efficiency of our approach. We demonstrate the algorithm's practical application through the successful identification of the entire phase diagram of a spin Hamiltonian with antisymmetric interaction on Honeycomb lattice, using significantly fewer sample points than traditional grid search methods and a previous method based on support vector machines. Our algorithm identifies the phase diagram consisting of skyrmion, spiral and polarized phases with error less than 5% using only 8% of the total possible sample points, in both two-dimensional and three-dimensional phase spaces. Additionally, our method proves highly efficient in constructing three-dimensional phase diagrams, significantly reducing computational and experimental costs. Our methodological contributions extend to higher-dimensional phase diagrams with multiple phases, emphasizing the algorithm's effectiveness and versatility in handling complex, multi-phase systems in various dimensions.

Published

2024

6. Order by projection in single-band Hubbard model: a DMRG study

Author

Li, Shuyi, Peng, Cheng, Yu, Yue, Shastry, B. Sriram, and Jia, Chunjing

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Superconductivity

Abstract

In a Fermi system near or at half-filling, a specific superconducting pairing channel, if not explicitly included in the Hamiltonian, can be boosted by suppressing a competing pairing channel; this is exemplified by the enhancement of extended $s$-wave correlations upon suppressing $s$-wave Cooper pairing. This phenomenon, originally found by the use of generalized uncertainty relations is referred to as \emph{order by projection}. The case of zero on-site Coulomb interaction in the thermodynamic limit, confirms this mechanism through the analytical solution. In this study, we go further and systematically investigate this mechanism for a strongly correlated fermionic Hubbard model, now with finite on-site interaction, on a square lattice with an extended set of hopping parameters. We explore the behaviors of different pairing channels when one of them is suppressed, utilizing density matrix renormalization group calculations. Our findings provide numerical evidence supporting the existence of \emph{order by projection} in the strongly correlated system we studied. We also investigate the effect of the strength of Hubbard $U$, next-nearest neighbor $t'$, hole-doping, as well as finite-size scaling approaching the thermodynamic limit.

Published

2024

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

Author

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

Subjects

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

Abstract

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

Published

2024

8. Kitaev physics in the two-dimensional magnet NiPSe$_3$

Author

Peng, Cheng, Mardanya, Sougata, Petsch, Alexander N., Sharma, Vineet Kumar, Li, Shuyi, Jia, Chunjing, Bansil, Arun, Chowdhury, Sugata, and Turner, Joshua J.

Subjects

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

Abstract

The Kitaev interaction, found in candidate materials such as $\alpha$-RuCl$_3$, occurs through the metal ($M$)-ligand ($X$)-metal ($M$) paths of the edge-sharing octahedra because the large spin-orbit coupling (SOC) on the metal atoms activates directional spin interactions. Here, we show that even in $3d$ transition-metal compounds, where the SOC of the metal atom is negligible, heavy ligands can induce bond-dependent Kitaev interactions. In this work, we take as an example the $3d$ transition-metal chalcogenophosphate NiPSe$_3$ and show that the key is found in the presence of a sizable SOC on the Se $p$ orbital, one which mediates the super-exchange between the nearest-neighbor Ni sites. Our study provides a pathway for engineering enhanced Kitaev interactions through the interplay of SOC strength, lattice distortions, and chemical substitutions., Comment: Supplementary material is included in the package

Published

2024

9. Skyrmions: A review on materials perspective for future electronic devices

Author

Sharma, Vineet Kumar, Okullo, Alana, Garner, Jalen, Peng, Cheng, Plumley, Rajan, Feiguin, Adrian, Jia, Chunjing, Turner, Josh, Bansil, A., and Chowdhury, Sugata

Subjects

Condensed Matter - Materials Science, Physics - Applied Physics

Abstract

Recent years have witnessed an enormous rise in research interest in magnetic skyrmions owing to their capability to improve over contemporary spintronic devices. An overview of the various magnetic interactions responsible for the formation of skyrmion together with distinct noncentrosymmetric and centrosymmetric skyrmion candidates is given in this review article. The magnetic interactions known as Dzyaloshinskii-Moriya interactions (DMI) have been extensively studied over the years to better understand the mechanism of skyrmions in chiral magnets that have larger skyrmion sizes. Because of their low skyrmion size, the centrosymmetric frustrated magnets are dwelling to skyrmions controlled by long-range interactions such as the Ruderman-Kittel-Kasuya-Yosida interaction (RKKY), which may be useful in the development of high-density memory devices. To lay a solid foundation for the magnetic interactions involved in skyrmion formations and many other special physical properties, more research in the field of centrosymmetric skyrmions is required. Apart from studying candidates with low skyrmion sizes, one of the main goals for the future is to better understand the dynamics of skyrmion using polarized magnons, which has the potential to be extremely beneficial for spintronic applications.

Published

2024

10. The emergence of antiferromagnetic correlations and Kondo-like features in a two-band model for infinite-layer nickelates

Author

Liu, Fangze, Peng, Cheng, Huang, Edwin W., Moritz, Brian, Jia, Chunjing, and Devereaux, Thomas P.

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

We report a determinant quantum Monte Carlo study of a two-band model, inspired by infinite-layer nickelates, focusing on the influence of interlayer hybridization between $3d_{x^2-y^2}$ orbitals derived from Ni (or Ni and O) in one layer and rare-earth ($R$) 5d orbitals in the other layer, hereafter the NI and $R$ layers, respectively. For a filling with one electron shared between the two layers on average, interlayer hybridization leads to "self-doped" holes in the Ni layer and the absence of antiferromagnetic ordering, but rather the appearance of spin-density and charge-density stripe-like states. As the interlayer hybridization increases, both the Ni and $R$ layers develop antiferromagnetic correlations, even though either layer individually remains away from half-filling. For hybridization within an intermediate range, roughly comparable to the intralayer nearest-neighbor hopping $t_{\text{Ni}}$, the model develops signatures of Kondo-like physics.

Published

2024

11. Self-Supervised Generative Models for Crystal Structures

Author

Liu, Fangze, Chen, Zhantao, Liu, Tianyi, Song, Ruyi, Lin, Yu, Turner, Joshua J., and Jia, Chunjing

Subjects

Condensed Matter - Materials Science

Abstract

Drawing inspiration from the achievements of natural language processing, we adopt self-supervised learning and utilize an equivariant graph neural network to develop a unified platform designed for training generative models capable of generating crystal structures, as well as efficiently adapting to downstream tasks in material property prediction. To mitigate the challenge of incorporating large-scale assessment on the reliability of generated structures into the training process, we utilize the generative adversarial network (GAN) with its discriminator being a cost-effective evaluator for the generated structures, resulting in notable improvements in model performance. We demonstrate the utility of our model in finding the optimal crystal structure under predefined conditions. Without reliance on properties acquired experimentally or numerically, our model further displays its capability to comprehend the mechanism of crystal structure formation through its ability to grouping chemically similar elements. Therefore, this paper extends an invitation to explore deeper into the scientific understanding of material structures through generative models, offering a fresh perspective on broadening the scope and efficacy of machine learning in material science.

Published

2023

12. Molecular geometry specific Monte Carlo simulation of the efficacy of diamond crystal formation from diamondoids

Author

Tang, Ta, Park, Sulgiye, Devereaux, Thomas Peter, Lin, Yu, and Jia, Chunjing

Published

2024

13. Improving the creation of SiV centers in diamond via sub-μs pulsed annealing treatment

Author

Tzeng, Yan-Kai, Ke, Feng, Jia, Chunjing, Liu, Yayuan, Park, Sulgiye, Han, Minkyung, Frost, Mungo, Cai, Xinxin, Mao, Wendy L., Ewing, Rodney C., Cui, Yi, Devereaux, Thomas P., Lin, Yu, and Chu, Steven

Published

2024

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

Author

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

Subjects

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

Abstract

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

Published

2023

15. On Ultrafast X-ray Methods for Magnetism

Author

Plumley, Rajan, Chitturi, Sathya, Peng, Cheng, Assefa, Tadesse, Burdet, Nicholas, Shen, Lingjia, Reid, Alex, Dakovski, Georgi, Seaberg, Matthew, O'Dowd, Frank, Montoya, Sergio, Chen, Hongwei, Okullo, Alana, Mardanya, Sougata, Kevan, Stephen, Fischer, Peter, Fullerton, Eric, Sinha, Sunil, Colocho, William, Lutman, Alberto, Decker, Franz-Joseph, Roy, Sujoy, Fujioka, Jun, Tokura, Yoshinori, Minitti, Michael P., Johnson, Jeremy, Hoffmann, Matthias, Amoo, Michaela, Feiguin, Adrian, Yoon, Chuck, Thayer, Jana, Nashed, Yousseff, Jia, Chunjing, Bansil, Arun, Chowdhury, Sugata, Lindenberg, Aaron, Dunne, Mike, Blackburn, Elizabeth, and Turner, Joshua

Subjects

Condensed Matter - Materials Science, Condensed Matter - Other Condensed Matter, Quantum Physics

Abstract

With the introduction of x-ray free electron laser sources around the world, new scientific approaches for visualizing matter at fundamental length and time-scales have become possible. As it relates to magnetism and "magnetic-type" systems, advanced methods are being developed for studying ultrafast magnetic responses on the time-scales at which they occur. We describe three capabilities which have the potential to seed new directions in this area and present original results from each: pump-probe x-ray scattering with low energy excitation, x-ray photon fluctuation spectroscopy, and ultrafast diffuse x-ray scattering. By combining these experimental techniques with advanced modeling together with machine learning, we describe how the combination of these domains allows for a new understanding in the field of magnetism. Finally, we give an outlook for future areas of investigation and the newly developed instruments which will take us there.

Published

2023

16. Capturing dynamical correlations using implicit neural representations

Author

Chitturi, Sathya, Ji, Zhurun, Petsch, Alexander, Peng, Cheng, Chen, Zhantao, Plumley, Rajan, Dunne, Mike, Mardanya, Sougata, Chowdhury, Sugata, Chen, Hongwei, Bansil, Arun, Feiguin, Adrian, Kolesnikov, Alexander, Prabhakaran, Dharmalingam, Hayden, Stephen, Ratner, Daniel, Jia, Chunjing, Nashed, Youssef, and Turner, Joshua

Subjects

Condensed Matter - Strongly Correlated Electrons, Computer Science - Artificial Intelligence, Computer Science - Computer Vision and Pattern Recognition, Physics - Data Analysis, Statistics and Probability

Abstract

The observation and description of collective excitations in solids is a fundamental issue when seeking to understand the physics of a many-body system. Analysis of these excitations is usually carried out by measuring the dynamical structure factor, S(Q, $\omega$), with inelastic neutron or x-ray scattering techniques and comparing this against a calculated dynamical model. Here, we develop an artificial intelligence framework which combines a neural network trained to mimic simulated data from a model Hamiltonian with automatic differentiation to recover unknown parameters from experimental data. We benchmark this approach on a Linear Spin Wave Theory (LSWT) simulator and advanced inelastic neutron scattering data from the square-lattice spin-1 antiferromagnet La$_2$NiO$_4$. We find that the model predicts the unknown parameters with excellent agreement relative to analytical fitting. In doing so, we illustrate the ability to build and train a differentiable model only once, which then can be applied in real-time to multi-dimensional scattering data, without the need for human-guided peak finding and fitting algorithms. This prototypical approach promises a new technology for this field to automatically detect and refine more advanced models for ordered quantum systems., Comment: 12 pages, 7 figures

Published

2023

17. Testing the data framework for an AI algorithm in preparation for high data rate X-ray facilities

Author

Chen, Hongwei, Chitturi, Sathya R., Plumley, Rajan, Shen, Lingjia, Drucker, Nathan C., Burdet, Nicolas, Peng, Cheng, Mardanya, Sougata, Ratner, Daniel, Mishra, Aashwin, Yoon, Chun Hong, Song, Sanghoon, Chollet, Matthieu, Fabbris, Gilberto, Dunne, Mike, Nelson, Silke, Li, Mingda, Lindenberg, Aaron, Jia, Chunjing, Nashed, Youssef, Bansil, Arun, Chowdhury, Sugata, Feiguin, Adrian E., Turner, Joshua J., and Thayer, Jana B.

Subjects

Physics - Data Analysis, Statistics and Probability

Abstract

The advent of next-generation X-ray free electron lasers will be capable of delivering X-rays at a repetition rate approaching 1 MHz continuously. This will require the development of data systems to handle experiments at these type of facilities, especially for high throughput applications, such as femtosecond X-ray crystallography and X-ray photon fluctuation spectroscopy. Here, we demonstrate a framework which captures single shot X-ray data at the LCLS and implements a machine-learning algorithm to automatically extract the contrast parameter from the collected data. We measure the time required to return the results and assess the feasibility of using this framework at high data volume. We use this experiment to determine the feasibility of solutions for `live' data analysis at the MHz repetition rate.

Published

2022

18. Implicit neural representations for experimental steering of advanced experiments

Author

Chen, Zhantao, Petsch, Alexander N., Ji, Zhurun, Chitturi, Sathya R., Peng, Cheng, Jia, Chunjing, Kolesnikov, Alexander I., Thayer, Jana B., and Turner, Joshua J.

Published

2025

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

Author

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

Subjects

Quantum Physics, Physical Sciences, Condensed Matter Physics

Abstract

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

Published

2023

20. Rare-Earth Control of the Superconducting Upper Critical Field in Infinite-Layer Nickelates

Author

Wang, Bai Yang, Wang, Tiffany C., Hsu, Yu-Te, Osada, Motoki, Lee, Kyuho, Jia, Chunjing, Duffy, Caitlin, Li, Danfeng, Fowlie, Jennifer, Beasley, Malcolm R., Devereaux, Thomas P., Fisher, Ian R., Hussey, Nigel E., and Hwang, Harold Y.

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Strongly Correlated Electrons

Abstract

The consequences of varying the rare-earth element in the superconducting infinite-layer nickelates have been much debated. Here we show striking differences in the magnitude and anisotropy of the superconducting upper critical field across the La-, Pr-, and Nd-nickelates. These 5 distinctions originate from the 4f electron characteristics of the rare-earth ions in the lattice: they are absent for La3+, nonmagnetic for the Pr3+ singlet ground state, and magnetic for the Nd3+ Kramer's doublet. The unique polar and azimuthal angle-dependent magnetoresistance found in the Nd-nickelates can be understood to arise from the magnetic contribution of the Nd3+ 4f moments. In the absence of rare-earth effects, we find that the nickelates broadly violate the Pauli limit. Such robust and tunable superconductivity suggests potential in future high-field applications., Comment: 8 pages, 4 figures, 1 supplementary materials

Published

2022

21. A quantum-inspired tensor network method for constrained combinatorial optimization problems

Author

Hao, Tianyi, Huang, Xuxin, Jia, Chunjing, and Peng, Cheng

Subjects

Computer Science - Data Structures and Algorithms, Quantum Physics

Abstract

Combinatorial optimization is of general interest for both theoretical study and real-world applications. Fast-developing quantum algorithms provide a different perspective on solving combinatorial optimization problems. In this paper, we propose a quantum-inspired tensor-network-based algorithm for general locally constrained combinatorial optimization problems. Our algorithm constructs a Hamiltonian for the problem of interest, effectively mapping it to a quantum problem, then encodes the constraints directly into a tensor network state and solves the optimal solution by evolving the system to the ground state of the Hamiltonian. We demonstrate our algorithm with the open-pit mining problem, which results in a quadratic asymptotic time complexity. Our numerical results show the effectiveness of this construction and potential applications in further studies for general combinatorial optimization problems.

Published

2022

22. Anisotropy of the magnetic and transport properties in EuZn$_2$As$_2$

Author

Wang, Zhi-Cheng, Been, Emily, Gaudet, Jonathan, Alqasseri, Gadeer Matook A., Fruhling, Kyle, Yao, Xiaohan, Stuhr, Uwe, Zhu, Qinqing, Ren, Zhi, Cui, Yi, Jia, Chunjing, Moritz, Brian, Chowdhury, Sugata, Devereaux, Thomas, and Tafti, Fazel

Subjects

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

Abstract

Several recent studies have shown that the anisotropy in the magnetic structure of \ECA\ plays a significant role in stabilizing the Weyl nodes. To investigate the relationship between magnetic anisotropy and Weyl physics, we present a comparative study between EuZn$_2$As$_2$ and EuCd$_2$As$_2$ that are isostructural but with different magnetic anisotropy. We performed structural analysis, electronic transport, and magnetization experiments on millimeter-sized single crystals of EuZn$_2$As$_2$, and compared the results to those of EuCd$_2$As$_2$. By combining the first principle calculations and neutron diffraction experiment, we identify the magnetic ground state of EuZn$_2$As$_2$ as A-type antiferromagnetic order with a transition temperature ($T_\mathrm{N}$ = 19.6 K) twice that of EuCd$_2$As$_2$. Like EuCd$_2$As$_2$, the negative magnetoresistance of EuZn$_2$As$_2$ is observed after suppressing the resistivity peak at $T_\mathrm{N}$ with increasing fields. However, the anisotropy in both transport and magnetization are much reduced in EuZn$_2$As$_2$. The difference could be ascribed to the weaker spin-orbit coupling, more localized $d$-orbitals, and a larger contribution from the Eu $s$-orbitals in the zinc compound, as suggested by the electronic band calculations. The same band structure effect could be also responsible for the observation of a smaller non-linear anomalous Hall effect in EuZn$_2$As$_2$ compared to EuCd$_2$As$_2$.

Published

2022

23. Evidences for the exciton gas phase and its condensation in monolayer 1T-ZrTe2

Author

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

Subjects

Condensed Matter - Materials Science

Abstract

The excitonic insulator (EI) is a Bose-Einstein condensation (BEC) of excitons bound by electron-hole interaction in a solid, which could support high-temperature BEC transition. The material realization of EI has been elusive, which is further challenged by the difficulty of distinguishing it from a conventional charge density wave (CDW) state. In the BEC limit, the pre-condensation exciton gas phase is a hallmark to distinguish EI from conventional CDW, yet direct experimental evidence has been lacking. Here we report a distinct correlated phase beyond the $2\times2$ CDW ground state emerging in epitaxially grown monolayer 1T-ZrTe2 and its investigation by angle-resolved photoemission spectroscopy (ARPES) and scanning tunneling microscopy (STM). The results show novel band- and energy-dependent folding behavior in a two-step process, evidenced by an exciton gas phase prior to its condensation into the final CDW state. The excellent agreement between experiments and theoretical predictions on the recovery of the pristine band structure by carrier-density-dependent suppression of the CDW state further corroborates the monolayer 1T-ZrTe2 as an EI. Our findings provide a versatile two-dimensional platform that allows tuning of the excitonic effect., Comment: 22 pages, 4 figures

Published

2022

24. On the nature of valence charge and spin excitations via multi-orbital Hubbard models for infinite-layer nickelates

Author

Been, Emily M., Hsu, Kuan H., Hu, Yi, Moritz, Brian, Cui, Yi, Jia, Chunjing, and Devereaux, Thomas P.

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Strongly Correlated Electrons

Abstract

Building upon the recent progress on the intriguing underlying physics for the newly discovered infinite-layer nickelates, in this article we review an examination of valence charge and spin excitations via multi-orbital Hubbard models as way to determine the fundamental building blocks for Hamiltonians that can describe the low energy properties of infinite-layer nickelates. We summarize key results from density-functional approaches, and apply them to the study of x-ray absorption to determine the valence ground states of infinite-layer nickelates in their parent form, and show that a fundamental $d^9$ configuration as in the cuprates is incompatible with a self-doped ground state having holes in both $d_{x^2-y^2}$ and a rare-earth-derived axial orbital. When doped, we determine that the rare-earth-derived orbitals empty and additional holes form low spin $(S=0)$ $d^8$ Ni states, which can be well-described as a doped single-band Hubbard model. Using exact diagonalization for a 2-orbital model involving Ni and rare earth orbitals, we find clear magnons at 1/2 filling that persist when doped, albeit with larger damping, and with a dependence on the precise orbital energy separation between the Ni- and rare-earth-derived orbitals. Taken together, a full two-band model for infinite-layer nickelates can well describe the valence charge and spin excitations observed experimentally.

Published

2021

25. Electronic structure of superconducting nickelates probed by resonant photoemission spectroscopy

Author

Chen, Zhuoyu, Osada, Motoki, Li, Danfeng, Been, Emily M, Chen, Su-Di, Hashimoto, Makoto, Lu, Donghui, Mo, Sung-Kwan, Lee, Kyuho, Wang, Bai Yang, Rodolakis, Fanny, McChesney, Jessica L, Jia, Chunjing, Moritz, Brian, Devereaux, Thomas P, Hwang, Harold Y, and Shen, Zhi-Xun

Abstract

The discovery of infinite-layer nickelate superconductors has spurred enormous interest. While the Ni1+ cations possess nominally the same 3d9 configuration as Cu2+ in cuprates, the electronic structure variances remain elusive. Here, we present a soft X-ray photoemission spectroscopy study on parent and doped infinite-layer Pr-nickelate thin films with a doped perovskite reference. By identifying the Ni character with resonant photoemission and comparison with density functional theory + U (on-site Coulomb repulsion energy) calculations, we estimate U ∼5 eV, smaller than the charge transfer energy Δ ∼8 eV, confirming the Mott-Hubbard electronic structure in contrast to charge-transfer cuprates. Near the Fermi level (EF), we observe a signature of occupied rare-earth states in the parent compound, which is consistent with a self-doping picture. Our results demonstrate a correlation between the superconducting transition temperature and the oxygen 2p hybridization near EF when comparing hole-doped nickelates and cuprates.

Published

2022

26. Charge order and superconductivity in a minimal two-band model for infinite-layer nickelates

Author

Peng, Cheng, Jiang, Hong-Chen, Moritz, Brian, Devereaux, Thomas P., and Jia, Chunjing

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

The recent discovery of superconductivity in infinite-layer nickelates has drawn considerable attention; however, a consensus on the fundamental building blocks and common ingredients necessary to understand and describe their ground states and emergent properties is lacking. A series of experimental and theoretical studies have suggested that an effective two-band Hubbard model with Ni 3$d_{x^2-y^2}$ and rare-earth ($R$) 5$d$ character may describe the low-energy physics. Here, we study the ground state properties of this two-band model on four-leg cylinders using the density-matrix renormalization group (DMRG) technique to better grasp whether such a simple model can embody the essential physics. A key difference compared to single-band Hubbard materials is that the system is self-doped: even at overall half-filling, the $R$-band acts as an electron reservoir, hole-doping the Ni-layer and fundamentally altering the physics expected from an undoped antiferromagnet. On the four-leg cylinder, the ground state is consistent with a Luttinger liquid, with anti-phase modulations of the charge density in the Ni- and $R$-layers having corresponding wavevectors that lock together. Light hole doping away from 1/2 filling releases the locking between the Ni and the $R$ charge modulations, as the electron density in the $R$-band decreases and eventually becomes exhausted at a hole doping concentration that depends sensitively on the effective splitting between the Ni and the $R$ orbitals. The ground state of the doped system is consistent with a Luther-Emery liquid, possessing quasi-long-range superconducting correlations in the Ni layer, similar to the single-band Hubbard model. Our results are consistent with experimental observations and may help to reveal the microscopic mechanism for pairing and other emergent properties., Comment: 9 pages, 3 figures

Published

2021

27. Evolution of the electronic structure in Ta$_2$NiSe$_5$ across the structural transition revealed by resonant inelastic x-ray scattering

Author

Lu, Haiyu, Ross, Matteo, Kim, 1Jung-ho, Yavas, Hasan, Said, Ayman, Nag, Abhishek, Garcia-Fernandez, Mirian, Agrestini, Stefano, Zhou, Kejin, Jia, Chunjing, Moritz, Brian, Devereaux, Thomas P., Shen, Zhi-Xun, and Lee, Wei-Sheng

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

We utilized high-energy-resolution resonant inelastic X-ray scattering (RIXS) at both the Ta and Ni $L_3$-edges to map out element-specific particle-hole excitations in Ta$_2$NiSe$_5$ across the phase transition. Our results reveal a momentum dependent gap-like feature in the low energy spectrum, which agrees well with the band gap in element-specific joint density of states calculations based on ab initio estimates of the electronic structure in both the low temperature monoclinic and the high temperature orthorhombic structure. Below $T_c$, the RIXS energy-momentum map shows a minimal gap at the Brillouin zone center ($\sim$ 0.16 eV), confirming that Ta$_2$NiSe$_5$ possesses a direct band gap in its low temperature ground state. However, inside the gap, no signature of anticipated collective modes with an energy scale comparable to the gap size can be identified. Upon increasing the temperature to above $T_c$, whereas the gap at the zone center closes, the RIXS map at finite momenta still possesses the gross features of the low temperature map, suggesting a substantial mixing between the Ta and Ni orbits in the conduction and valence bands, which does not change substantially across the phase transition. Our experimental observations and comparison to the theoretical calculations lend further support that the phase transition and the corresponding gap opening in Ta$_2$NiSe$_5$ is largely structural by nature with possible minor contribution from the putative exciton condensate., Comment: The manuscript has been accepted by Physical Review B

Published

2021

28. Electronic structure of superconducting nickelates probed by resonant photoemission spectroscopy

Author

Chen, Zhuoyu, Osada, Motoki, Li, Danfeng, Been, Emily M., Chen, Su-Di, Hashimoto, Makoto, Lu, Donghui, Mo, Sung-Kwan, Lee, Kyuho, Wang, Bai Yang, Rodolakis, Fanny, McChesney, Jessica L., Jia, Chunjing, Moritz, Brian, Devereaux, Thomas P., Hwang, Harold Y., and Shen, Zhi-Xun

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Strongly Correlated Electrons

Abstract

The discovery of infinite-layer nickelate superconductors has spurred enormous interest. While the Ni$^{1+}$ cations possess nominally the same 3$d^9$ configuration as Cu$^{2+}$ in cuprates, the electronic structure variances remain elusive. Here, we present a soft x-ray photoemission spectroscopy study on parent and doped infinite-layer Pr-nickelate thin films with a doped perovskite reference. By identifying the Ni character with resonant photoemission and comparison to density functional theory + U (on-site Coulomb repulsion energy) calculations, we estimate U ~5 eV, smaller than the charge transfer energy $\Delta$ ~8 eV, confirming the Mott-Hubbard electronic structure in contrast to charge-transfer cuprates. Near the Fermi level ($E_F$), we observe a signature of occupied rare-earth states in the parent compound, which is consistent with a self-doping picture. Our results demonstrate a correlation between the superconducting transition temperature and the oxygen 2$p$ hybridization near $E_F$ when comparing hole-doped nickelates and cuprates., Comment: 28 pages, 10 figures

Published

2021

29. Gauge invariance of light-matter interactions in first-principle tight-binding models

Author

Schüler, Michael, Marks, Jacob A., Murakami, Yuta, Jia, Chunjing, and Devereaux, Thomas P.

Subjects

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

Abstract

We study the different ways of introducing light-matter interaction in first-principle tight-binding (TB) models. The standard way of describing optical properties is the velocity gauge, defined by linear coupling to the vector potential. In finite systems a transformation to represent the electromagnetic radiation by the electric field instead is possible, albeit subtleties arise in periodic systems. The resulting dipole gauge is a multi-orbital generalization of Peierl's substitution. In this work, we investigate accuracy of both pathways, with particular emphasis on gauge invariance, for TB models constructed from maximally localized Wannier functions. Focusing on paradigmatic two-dimensional materials, we construct first-principle models and calculate the response to electromagnetic fields in linear response and for strong excitations. Benchmarks against fully converged first-principle calculations allow for ascertaining the accuracy of the TB models. We find that the dipole gauge provides a more accurate description than the velocity gauge in all cases. The main deficiency of the velocity gauge is an imperfect cancellation of paramagnetic and diamagnetic current. Formulating a corresponding sum rule however provides a way to explicitly enforce this cancellation. This procedure corrects the TB models in the velocity gauge, yielding excellent agreement with dipole gauge and thus gauge invariance., Comment: 13 pages, 6 figures

Published

2021

30. Geometric frustration of Jahn–Teller order in the infinite-layer lattice

Author

Kim, Woo Jin, Smeaton, Michelle A., Jia, Chunjing, Goodge, Berit H., Cho, Byeong-Gwan, Lee, Kyuho, Osada, Motoki, Jost, Daniel, Ievlev, Anton V., Moritz, Brian, Kourkoutis, Lena F., Devereaux, Thomas P., and Hwang, Harold Y.

Published

2023

31. Electronic Structure Trends Across the Rare-Earth Series in Superconducting Infinite Layer Nickelates

Author

Been, Emily, Lee, Wei-Sheng, Hwang, Harold Y., Cui, Yi, Zaanen, Jan, Devereaux, Thomas, Moritz, Brian, and Jia, Chunjing

Subjects

Condensed Matter - Superconductivity

Abstract

The recent discovery of superconductivity in oxygen-reduced monovalent nickelates has raised a new platform for the study of unconventional superconductivity, with similarities and differences with the cuprate high temperature superconductors. In this paper we investigate the family of infinite-layer nickelates $R$NiO$_2$ with rare-earth $R$ spanning across the lanthanide series, introducing a new and non-trivial "knob" with which to tune nickelate superconductivity. When traversing from La to Lu, the out-of-plane lattice constant decreases dramatically with an accompanying increase of Ni $ d_{x^2-y^2}$ bandwidth; however, surprisingly, the role of oxygen charge transfer diminishes. In contrast, the magnetic exchange grows across the lanthanides which may be favorable to superconductivity. Moreover, compensation effects from the itinerant $5d$ electrons present a closer analogy to Kondo lattices, indicating a stronger interplay between charge transfer, bandwidth renormalization, compensation, and magnetic exchange. We also obtain the microscopic Hamiltonian using Wannier downfolding technique, which will provide the starting point for further many-body theoretical studies.

Published

2020

32. Emergence of Quasiparticles in a Doped Mott Insulator

Author

Wang, Yao, He, Yu, Wohlfeld, Krzysztof, Hashimoto, Makoto, Huang, Edwin W., Lu, Donghui, Mo, Sung-Kwan, Komiya, Seiki, Jia, Chunjing, Moritz, Brian, Shen, Zhi-Xun, and Devereaux, Thomas P.

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Superconductivity

Abstract

How a Mott insulator develops into a weakly coupled metal upon doping is a central question to understanding various emergent correlated phenomena. To analyze this evolution and its connection to the high-$T_c$ cuprates, we study the single-particle spectrum for the doped Hubbard model using cluster perturbation theory on superclusters. Starting from extremely low doping, we identify a heavily renormalized quasiparticle dispersion that immediately develops across the Fermi level, and a weakening polaronic side band at higher binding energy. The quasiparticle spectral weight roughly grows at twice the rate of doping in the low doping regime, but this rate is halved at optimal doping. In the heavily doped regime, we find both strong electron-hole asymmetry and a persistent presence of Mott spectral features. Finally, we discuss the applicability of the single-band Hubbard model to describe the evolution of nodal spectra measured by angle-resolved photoemission spectroscopy (ARPES) on the single-layer cuprate La$_{2-x}$Sr$_x$CuO$_4$ ($0 \le x \le 0.15$). This work benchmarks the predictive power of the Hubbard model for electronic properties of high-$T_c$ cuprates., Comment: 7 pages, 5 figures

Published

2019

33. Time-Resolved Resonant Inelastic X-Ray Scattering in a Pumped Mott Insulator

Author

Wang, Yao, Chen, Yuan, Jia, Chunjing, Moritz, Brian, and Devereaux, Thomas P.

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Collective excitations contain rich information about photoinduced transient states in correlated systems. In a Mott insulator, charge degrees of freedom are frozen, but can be activated by photodoping. The energy-momentum distribution of the charge excitation spectrum reflects the propagation of charge degrees of freedom, and provides information about the interplay among various intertwined instabilities on the time scale set by the pump. To reveal charge excitations out of equilibrium, we simulate time-resolved x-ray absorption and resonant inelastic x-ray scattering using a Hubbard model. After pumping, the former resolves photodoping, while the latter characterizes the formation, dispersion, weight, and nonlinear effects of collective excitations. Intermediate-state information from time-resolved resonant inelastic x-ray scattering (trRIXS) can be used to decipher the origin of these excitations, including bimagnons, Mott-gap excitations, doublon and single-electron in-gap states, and anti-Stokes relaxation during an ultrafast pump. This paper provides a theoretical foundation for existing and future trRIXS experiments., Comment: 15 pages, 11 figures

Published

2019

34. Metallic surface states in a correlated d-electron topological Kondo insulator candidate FeSb2

Author

Xu, Ke-Jun, Chen, Su-Di, He, Yu, He, Junfeng, Tang, Shujie, Jia, Chunjing, Yue, Eric, Mo, Sung-Kwan, Lu, Donghui, Hashimoto, Makoto, Devereaux, Thomas P, and Shen, Zhi-Xun

Subjects

Physical Sciences, Condensed Matter Physics, angle-resolved photoemission spectroscopy, quantum materials, topological materials, correlated materials

Abstract

The resistance of a conventional insulator diverges as temperature approaches zero. The peculiar low-temperature resistivity saturation in the 4f Kondo insulator (KI) SmB6 has spurred proposals of a correlation-driven topological Kondo insulator (TKI) with exotic ground states. However, the scarcity of model TKI material families leaves difficulties in disentangling key ingredients from irrelevant details. Here we use angle-resolved photoemission spectroscopy (ARPES) to study FeSb2, a correlated d-electron KI candidate that also exhibits a low-temperature resistivity saturation. On the (010) surface, we find a rich assemblage of metallic states with two-dimensional dispersion. Measurements of the bulk band structure reveal band renormalization, a large temperature-dependent band shift, and flat spectral features along certain high-symmetry directions, providing spectroscopic evidence for strong correlations. Our observations suggest that exotic insulating states resembling those in SmB6 and YbB12 may also exist in systems with d instead of f electrons.

Published

2020

35. Theory for Time-Resolved Resonant Inelastic X-ray Scattering

Author

Chen, Yuan, Wang, Yao, Jia, Chunjing, Moritz, Brian, Shvaika, Andrij M., Freericks, James K., and Devereaux, Thomas P.

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Other Condensed Matter

Abstract

Time-resolved measurements of materials provide a wealth of information on quasiparticle dynamics, and have been the focus of optical studies for decades. In this paper, we develop a theory for explicitly evaluating time-resolved resonant inelastic X-ray scattering (tr-RIXS). We apply the theory to a non-interacting electronic system and reveal the particle-hole spectrum and its evolution during the pump pulse. With a high-frequency pump, the frequency and amplitude dependence analysis of the spectra agrees well with the steady-state assumptions and Floquet excitations. When the pump frequency is low, the spectrum extracts real-time dynamics of the particle-hole continuum in momentum space. These results verify the correctness of our theory and demonstrate the breadth of physical problems that tr-RIXS could shed light on., Comment: 14 pages, 7 figures

Published

2019

36. Metallic surface states in a correlated d-electron topological Kondo insulator candidate FeSb2

Author

Xu, Ke-Jun, Chen, Su-Di, He, Yu, He, Junfeng, Tang, Shujie, Jia, Chunjing, Ma, Eric Yue, Mo, Sung-Kwan, Lu, Dong-Hui, Hashimoto, Makoto, Devereaux, Thomas P., and Shen, Zhi-Xun

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

The resistance of a conventional insulator diverges as temperature approaches zero. The peculiar low temperature resistivity saturation in the 4f Kondo insulator (KI) SmB6 has spurred proposals of a correlation-driven topological Kondo insulator (TKI) with exotic ground states. However, the scarcity of model TKI material families leaves difficulties in disentangling key ingredients from irrelevant details. Here we use angle-resolved photoemission spectroscopy (ARPES) to study FeSb2, a correlated d-electron KI candidate that also exhibits a low temperature resistivity saturation. On the (010) surface, we find a rich assemblage of metallic states with two-dimensional dispersion. Measurements of the bulk band structure reveal band renormalization, a large temperature-dependent band shift, and flat spectral features along certain high symmetry directions, providing spectroscopic evidence for strong correlations. Our observations suggest that exotic insulating states resembling those in SmB6 and YbB12 may also exist in systems with d instead of f electrons.

Published

2018

37. A Wannier orbital based method for resonant inelastic x-ray scattering simulation

Author

Jia, Chunjing

Subjects

Condensed Matter - Materials Science

Abstract

We report one algorithm for simulating oxygen $K$-edge RIXS for weakly correlated systems, using maximally localized Wannier functions as the basis set. The $N$-electron wavefunction is formulated using the single Slater determinant, and the many-body effect is treated explicitly at the dipole matrix element level. The simulated result of oxygen $K$-edge RIXS for solid state Li$_2$CO$_3$ matches well with the experimental data. Besides being efficient and reasonably accurate, this algorithm also shows potential to extent to more complex RIXS problems.

Published

2018

38. Spectroscopic Signature of Oxidized Oxygen States in Peroxides

Author

Zhuo, Zengqing, Pemmaraju, Chaitanya Das, Vinson, John, Jia, Chunjing, Moritz, Brian, Lee, Ilkyu, Sallies, Shawn, Li, Qinghao, Wu, Jinpeng, Dai, Kehua, Chuang, Yi-de, Hussain, Zahid, Pan, Feng, Devereaux, Thomas P., and Yang, Wanli

Subjects

Physics - Chemical Physics, Condensed Matter - Materials Science, Physics - Applied Physics

Abstract

Recent debates on the oxygen redox behaviors in battery electrodes have triggered a pressing demand for the reliable detection and understanding of non-divalent oxygen states beyond conventional absorption spectroscopy. Here, enabled by high-efficiency mapping of resonant inelastic X-ray scattering (mRIXS) coupled with first-principles calculations, we report distinct mRIXS features of the oxygen states in Li2O, Li2CO3, and especially, Li2O2, which are successfully reproduced and interpreted theoretically. mRIXS signals are dominated by valence-band decays in Li2O and Li2CO3. However, the oxidized oxygen in Li2O2 leads to partially unoccupied O-2p states that yield a specific intra-band excitonic feature in mRIXS. Such a feature displays a specific emission energy in mRIXS, which disentangles the oxidized oxygen states from the dominating transition-metal/oxygen hybridization features in absorption spectroscopy, thus providing critical hints for both detecting and understanding the oxygen redox reactions in transition-metal oxide based battery materials., Comment: 25 pages, 4 figures, plus 11 pages of Supplementary Information with 4 figures

Published

2018

39. Theoretical Understanding of Photon Spectroscopies in Correlated Materials In and Out of Equilibrium

Author

Wang, Yao, Claassen, Martin, Pemmaraju, Chaitanya Das, Jia, Chunjing, Moritz, Brian, and Devereaux, Thomas P.

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Photon-based spectroscopies have had a significant impact on both fundamental science and applications by providing an efficient approach to investigate the microscopic physics of materials. Together with the development of synchrotron X-ray techniques, theoretical understanding of the spectroscopies themselves and the underlying physics that they reveal has progressed through advances in numerical methods and scientific computing. In this review, we provide an overview of theories for angle-resolved photoemission spectroscopy and resonant inelastic X-ray scattering applied to quantum materials. First, we discuss methods for studying equilibrium spectroscopies, including first-principles approaches, numerical many-body methods and a few analytical advances. Second, we assess the recent development of ultrafast techniques for out-of-equilibrium spectroscopies, from characterizing equilibrium properties to generating transient or metastable states, mainly from a theoretical point of view. Finally, we identify the main challenges and provide an outlook for the future direction of the field., Comment: 14 pages, 7 figures

Published

2018

40. Emergence of quasiparticles in a doped Mott insulator

Author

Wang, Yao, He, Yu, Wohlfeld, Krzysztof, Hashimoto, Makoto, Huang, Edwin W, Lu, Donghui, Mo, Sung-Kwan, Komiya, Seiki, Jia, Chunjing, Moritz, Brian, Shen, Zhi-Xun, and Devereaux, Thomas P

Subjects

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

Abstract

How a Mott insulator develops into a weakly coupled metal upon doping is a central question to understanding various emergent correlated phenomena. To analyze this evolution and its connection to the high-Tc cuprates, we study the single-particle spectrum for the doped Hubbard model using cluster perturbation theory on superclusters. Starting from extremely low doping, we identify a heavily renormalized quasiparticle dispersion that immediately develops across the Fermi level, and a weakening polaronic side band at higher binding energy. The quasiparticle spectral weight roughly grows at twice the rate of doping in the low doping regime, but this rate is halved at optimal doping. In the heavily doped regime, we find both strong electron-hole asymmetry and a persistent presence of Mott spectral features. Finally, we discuss the applicability of the single-band Hubbard model to describe the evolution of nodal spectra measured by angle-resolved photoemission spectroscopy (ARPES) on the single-layer cuprate La2−xSrxCuO4 (0 ≤ x ≤ 0.15). This work benchmarks the predictive power of the Hubbard model for electronic properties of high-Tc cuprates.

Published

2020

41. Realization of Quantum Spin Hall State in Monolayer 1T'-WTe2

Author

Tang, Shujie, Zhang, Chaofan, Wong, Dillon, Pedramrazi, Zahra, Tsai, Hsin-Zon, Jia, Chunjing, Moritz, Brian, Claassen, Martin, Ryu, Hyejin, Kahn, Salman, Jiang, Juan, Yan, Hao, Hashimoto, Makoto, Lu, Donghui, Moore, Robert G., Hwang, Chancuk, Hwang, Choongyu, Hussain, Zahid, Chen, Yulin, Ugeda, Miguel M., Liu, Zhi, Xie, Xiaoming, Devereaux, Thomas P., Crommie, Michael F., Mo, Sung-Kwan, and Shen, Zhi-Xun

Subjects

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

Abstract

A quantum spin Hall (QSH) insulator is a novel two-dimensional quantum state of matter that features quantized Hall conductance in the absence of magnetic field, resulting from topologically protected dissipationless edge states that bridge the energy gap opened by band inversion and strong spin-orbit coupling. By investigating electronic structure of epitaxially grown monolayer 1T'-WTe2 using angle-resolved photoemission (ARPES) and first principle calculations, we observe clear signatures of the topological band inversion and the band gap opening, which are the hallmarks of a QSH state. Scanning tunneling microscopy measurements further confirm the correct crystal structure and the existence of a bulk band gap, and provide evidence for a modified electronic structure near the edge that is consistent with the expectations for a QSH insulator. Our results establish monolayer 1T'-WTe2 as a new class of QSH insulator with large band gap in a robust two-dimensional materials family of transition metal dichalcogenides (TMDCs)., Comment: 19 pages, 4 figures; includes Supplemental Material (11 pages, 7 figures)

Published

2017

42. Emergence of antiferromagnetic correlations and Kondolike features in a model for infinite layer nickelates

Author

Liu, Fangze, primary, Peng, Cheng, additional, Huang, Edwin W., additional, Moritz, Brian, additional, Jia, Chunjing, additional, and Devereaux, Thomas P., additional

Published

2024

43. Web-based methods for X-ray and photoelectron spectroscopies

Author

Devereaux, Thomas P., Moritz, Brian, Jia, Chunjing, Kas, Joshua J., and Rehr, John. J.

Published

2021

44. Distinct Electronic Structure for the Extreme Magnetoresistance in YSb

Author

He, Junfeng, Zhang, Chaofan, Ghimire, Nirmal J., Liang, Tian, Jia, Chunjing, Jiang, Juan, Tang, Shujie, Chen, Sudi, He, Yu, Mo, S. -K., Hwang, C. C., Hashimoto, M., Lu, D. H., Moritz, B., Devereaux, T. P., Chen, Y. L., Mitchell, J. F., and Shen, Z. -X.

Subjects

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

Abstract

An extreme magnetoresistance (XMR) has recently been observed in several non-magnetic semimetals. Increasing experimental and theoretical evidence indicates that the XMR can be driven by either topological protection or electron-hole compensation. Here, by investigating the electronic structure of a XMR material, YSb, we present spectroscopic evidence for a special case which lacks topological protection and perfect electron-hole compensation. Further investigations reveal that a cooperative action of a substantial difference between electron and hole mobility and a moderate carrier compensation might contribute to the XMR in YSb.

Published

2016

45. All-Optical Materials Design of Chiral Edge Modes in Transition-Metal Dichalcogenides

Author

Claassen, Martin, Jia, Chunjing, Moritz, Brian, and Devereaux, Thomas P.

Subjects

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

Abstract

Manipulating materials properties far from equilibrium recently garnered significant attention, with experimental emphasis on transient melting, enhancement, or induction of electronic order. A more tantalizing aspect of the matter-light interaction regards the possibility to access dynamical steady states with distinct non-equilibrium phase transitions to affect electronic transport. Here, we show that the interplay of crystal symmetry and optical pumping of monolayer transition-metal dichalcogenides (TMDCs) provides a novel avenue to engineer topologically-protected chiral edge modes. In stark contrast to graphene and previously-discussed toy models, the underlying generic mechanism relies on the intrinsic three-band nature of TMDCs near the band edges. Photo-induced band inversions scale linearly in applied pump field and exhibit a transition from one to two chiral edge modes upon sweeping from red to blue detuning. We develop a strategy to understand non-equilibrium Floquet-Bloch bands and topological transitions directly from ab initio calculations, and illustrate for the example of WS$_2$ that control of chiral edge modes can be dictated solely from symmetry principles and is not qualitatively sensitive to microscopic materials details., Comment: 17 pages, 7 figures, 2 tables

Published

2016

46. Publisher Correction: Geometric frustration of Jahn–Teller order in the infinite-layer lattice

Author

Kim, Woo Jin, Smeaton, Michelle A., Jia, Chunjing, Goodge, Berit H., Cho, Byeong-Gwan, Lee, Kyuho, Osada, Motoki, Jost, Daniel, Ievlev, Anton V., Moritz, Brian, Kourkoutis, Lena F., Devereaux, Thomas P., and Hwang, Harold Y.

Published

2023

47. Electronic structure of monolayer 1T′-MoTe2 grown by molecular beam epitaxy

Author

Tang, Shujie, Zhang, Chaofan, Jia, Chunjing, Ryu, Hyejin, Hwang, Choongyu, Hashimoto, Makoto, Lu, Donghui, Liu, Zhi, Devereaux, Thomas P, Shen, Zhi-Xun, and Mo, Sung-Kwan

Subjects

Physical Sciences, Condensed Matter Physics, Electrical and Electronic Engineering, Materials Engineering, Mechanical Engineering, Materials engineering, Nanotechnology, Condensed matter physics

Abstract

Monolayer transition metal dichalcogenides (TMDCs) in the 1T′ structural phase have drawn a great deal of attention due to the prediction of quantum spin Hall insulator states. The band inversion and the concomitant changes in the band topology induced by the structural distortion from 1T to 1T′ phases are well established. However, the bandgap opening due to the strong spin-orbit coupling (SOC) is only verified for 1T′-WTe2 recently and still debated for other TMDCs. Here we report a successful growth of high-quality monolayer 1T′-MoTe2 on a bilayer graphene substrate through molecular beam epitaxy. Using in situ angle-resolved photoemission spectroscopy (ARPES), we have investigated the low-energy electronic structure and Fermi surface topology. The SOC-induced breaking of the band degeneracy points between the valence and conduction bands is clearly observed by ARPES. However, the strength of SOC is found to be insufficient to open a bandgap, which makes monolayer 1T′-MoTe2 on bilayer graphene a semimetal.

Published

2018

48. Quantum spin Hall state in monolayer 1T'-WTe2

Author

Tang, Shujie, Zhang, Chaofan, Wong, Dillon, Pedramrazi, Zahra, Tsai, Hsin-Zon, Jia, Chunjing, Moritz, Brian, Claassen, Martin, Ryu, Hyejin, Kahn, Salman, Jiang, Juan, Yan, Hao, Hashimoto, Makoto, Lu, Donghui, Moore, Robert G, Hwang, Chan-Cuk, Hwang, Choongyu, Hussain, Zahid, Chen, Yulin, Ugeda, Miguel M, Liu, Zhi, Xie, Xiaoming, Devereaux, Thomas P, Crommie, Michael F, Mo, Sung-Kwan, and Shen, Zhi-Xun

Subjects

Quantum Physics, Physical Sciences, Condensed Matter Physics, cond-mat.mtrl-sci, cond-mat.mes-hall, Mathematical Sciences, Fluids & Plasmas, Mathematical sciences, Physical sciences

Abstract

A quantum spin Hall (QSH) insulator is a novel two-dimensional quantum state of matter that features quantized Hall conductance in the absence of a magnetic field, resulting from topologically protected dissipationless edge states that bridge the energy gap opened by band inversion and strong spin-orbit coupling. By investigating the electronic structure of epitaxially grown monolayer 1T'-WTe 2 using angle-resolved photoemission (ARPES) and first-principles calculations, we observe clear signatures of topological band inversion and bandgap opening, which are the hallmarks of a QSH state. Scanning tunnelling microscopy measurements further confirm the correct crystal structure and the existence of a bulk bandgap, and provide evidence for a modified electronic structure near the edge that is consistent with the expectations for a QSH insulator. Our results establish monolayer 1T'-WTe 2 as a new class of QSH insulator with large bandgap in a robust two-dimensional materials family of transition metal dichalcogenides (TMDCs).

Published

2017

49. Hybrid metal–organic chalcogenide nanowires with electrically conductive inorganic core through diamondoid-directed assembly

Author

Yan, Hao, Hohman, J Nathan, Li, Fei Hua, Jia, Chunjing, Solis-Ibarra, Diego, Wu, Bin, Dahl, Jeremy EP, Carlson, Robert MK, Tkachenko, Boryslav A, Fokin, Andrey A, Schreiner, Peter R, Vailionis, Arturas, Kim, Taeho Roy, Devereaux, Thomas P, Shen, Zhi-Xun, and Melosh, Nicholas A

Subjects

Inorganic Chemistry, Macromolecular and Materials Chemistry, Chemical Sciences, Chalcogens, Diamond, Electric Conductivity, Metal-Organic Frameworks, Models, Molecular, Molecular Conformation, Nanodiamonds, Nanotechnology, Nanowires, Nanoscience & Nanotechnology

Abstract

Controlling inorganic structure and dimensionality through structure-directing agents is a versatile approach for new materials synthesis that has been used extensively for metal-organic frameworks and coordination polymers. However, the lack of 'solid' inorganic cores requires charge transport through single-atom chains and/or organic groups, limiting their electronic properties. Here, we report that strongly interacting diamondoid structure-directing agents guide the growth of hybrid metal-organic chalcogenide nanowires with solid inorganic cores having three-atom cross-sections, representing the smallest possible nanowires. The strong van der Waals attraction between diamondoids overcomes steric repulsion leading to a cis configuration at the active growth front, enabling face-on addition of precursors for nanowire elongation. These nanowires have band-like electronic properties, low effective carrier masses and three orders-of-magnitude conductivity modulation by hole doping. This discovery highlights a previously unexplored regime of structure-directing agents compared with traditional surfactant, block copolymer or metal-organic framework linkers.

Published

2017

50. Using Nonequilibrium Dynamics to Probe Competing Orders in a Mott-Peierls System

Author

Wang, Yao, Moritz, Brian, Chen, Cheng-Chien, Jia, Chunjing, van Veenendaal, Michel, and Devereaux, Thomas P.

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Competition between ordered phases, and their associated phase transitions, are significant in the study of strongly correlated systems. Here we examine one aspect, the nonequilibrium dynamics of a photoexcited Mott-Peierls system, using an effective Peierls-Hubbard model and exact diagonalization. Near a transition where spin and charge become strongly intertwined, we observe anti-phase dynamics and a coupling-strength-dependent suppression or enhancement in the static structure factors. The renormalized bosonic excitations coupled to a particular photoexcited electron can be extracted, which provides an approach for characterizing the underlying bosonic modes. The results from this analysis for different electronic momenta show an uneven softening due to a stronger coupling near $k_F$. This behavior reflects the strong link between the fermionic momenta, the coupling vertices, and ultimately the bosonic susceptibilities when multiple phases compete for the ground state of the system., Comment: 6 pages, 3 figures

Published

2015