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24 results on '"Heinsdorf, Niclas"'

1. Altermagnetic Instabilities from Quantum Geometry

Author

Heinsdorf, Niclas

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

Altermagnets are a newly identified type of collinear anti-ferromagnetism with vanishing net magnetic moment, characterized by lifted Kramers' degeneracy in parts of the Brillouin zone. Their time-reversal symmetry broken band structure has been observed experimentally and is theoretically well-understood. On the contrary, altermagnetic fluctuations and the formation of the corresponding instabilities remains largely unexplored. We establish a correspondence between the quantum metric of normal and the altermagnetic spin-splitting of ordered phases. We analytically derive a criterion for the formation of instabilities and show that the quantum metric favors altermagnetism. We recover the expression for conventional q=0 instabilities where the spin-splitting terms of the normal state model are locally absent. As an example, we construct an effective model of MnTe and illustrate the relationship between quantum geometry and altermagnetic fluctuations by explicitly computing the quantum metric and the generalized magnetic susceptibility.

Published
2024

2. Computational supremacy in quantum simulation

Author

King, Andrew D., Nocera, Alberto, Rams, Marek M., Dziarmaga, Jacek, Wiersema, Roeland, Bernoudy, William, Raymond, Jack, Kaushal, Nitin, Heinsdorf, Niclas, Harris, Richard, Boothby, Kelly, Altomare, Fabio, Berkley, Andrew J., Boschnak, Martin, Chern, Kevin, Christiani, Holly, Cibere, Samantha, Connor, Jake, Dehn, Martin H., Deshpande, Rahul, Ejtemaee, Sara, Farré, Pau, Hamer, Kelsey, Hoskinson, Emile, Huang, Shuiyuan, Johnson, Mark W., Kortas, Samuel, Ladizinsky, Eric, Lai, Tony, Lanting, Trevor, Li, Ryan, MacDonald, Allison J. R., Marsden, Gaelen, McGeoch, Catherine C., Molavi, Reza, Neufeld, Richard, Norouzpour, Mana, Oh, Travis, Pasvolsky, Joel, Poitras, Patrick, Poulin-Lamarre, Gabriel, Prescott, Thomas, Reis, Mauricio, Rich, Chris, Samani, Mohammad, Sheldan, Benjamin, Smirnov, Anatoly, Sterpka, Edward, Clavera, Berta Trullas, Tsai, Nicholas, Volkmann, Mark, Whiticar, Alexander, Whittaker, Jed D., Wilkinson, Warren, Yao, Jason, Yi, T. J., Sandvik, Anders W., Alvarez, Gonzalo, Melko, Roger G., Carrasquilla, Juan, Franz, Marcel, and Amin, Mohammad H.

Subjects
Quantum Physics, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Statistical Mechanics
Abstract

Quantum computers hold the promise of solving certain problems that lie beyond the reach of conventional computers. Establishing this capability, especially for impactful and meaningful problems, remains a central challenge. One such problem is the simulation of nonequilibrium dynamics of a magnetic spin system quenched through a quantum phase transition. State-of-the-art classical simulations demand resources that grow exponentially with system size. Here we show that superconducting quantum annealing processors can rapidly generate samples in close agreement with solutions of the Schr\"odinger equation. We demonstrate area-law scaling of entanglement in the model quench in two-, three- and infinite-dimensional spin glasses, supporting the observed stretched-exponential scaling of effort for classical approaches. We assess approximate methods based on tensor networks and neural networks and conclude that no known approach can achieve the same accuracy as the quantum annealer within a reasonable timeframe. Thus quantum annealers can answer questions of practical importance that classical computers cannot.

Published
2024

3. Discovery of Superconductivity and Electron-Phonon Drag in the Non-Centrosymmetric Weyl Semimetal LaRhGe$_3$

Author

Oudah, Mohamed, Kung, Hsiang-Hsi, Sahu, Samikshya, Heinsdorf, Niclas, Schulz, Armin, Philippi, Kai, Sanchez, Marta-Villa De Toro, Cai, Yipeng, Kojima, Kenji, Schnyder, Andreas P., Takagi, Hidenori, Keimer, Bernhard, Bonn, Doug A., and Hallas, Alannah M.

Subjects
Condensed Matter - Superconductivity, Condensed Matter - Materials Science
Abstract

We present an exploration of the effect of electron-phonon coupling and broken inversion symmetry on the electronic and thermal properties of the semimetal LaRhGe$_3$. Our transport measurements reveal evidence for electron-hole compensation at low temperatures, resulting in a large magnetoresistance of 3000% at 1.8 K and 14 T. The carrier concentration is on the order of $10^{21}\rm{/cm}^3$ with high carrier mobilities of $2000~\rm{cm}^2/\rm{Vs}$. When coupled to our theoretical demonstration of symmetry-protected $\textit{almost movable}$ Weyl nodal lines, we conclude that LaRhGe$_3$ supports a Weyl semimetallic state. We discover superconductivity in this compound with a $T_{\text c}$ of 0.39(1) K and $B_{\rm{c}}(0)$ of 2.2(1) mT, with evidence from specific heat and transverse-field muon spin relaxation. We find an exponential dependence in the normal state electrical resistivity below $\sim50$ K, while Seebeck coefficient and thermal conductivity measurements each reveal a prominent peak at low temperatures, indicative of strong electron-phonon interactions. To this end, we examine the temperature-dependent Raman spectra of LaRhGe$_3$ and find that the lifetime of the lowest energy $A_1$ phonon is dominated by phonon-electron scattering instead of anharmonic decay. We conclude that LaRhGe$_3$ has strong electron-phonon coupling in the normal state, while the superconductivity emerges from weak electron-phonon coupling. These results open up the investigation of electron-phonon interactions in the normal state of superconducting non-centrosymmetric Weyl semimetals.

Published
2023

4. Quantum error mitigation in quantum annealing

Author

Amin, Mohammad H., King, Andrew D., Raymond, Jack, Harris, Richard, Bernoudy, William, Berkley, Andrew J., Boothby, Kelly, Smirnov, Anatoly, Altomare, Fabio, Babcock, Michael, Baron, Catia, Connor, Jake, Dehn, Martin, Enderud, Colin, Hoskinson, Emile, Huang, Shuiyuan, Johnson, Mark W., Ladizinsky, Eric, Lanting, Trevor, MacDonald, Allison J. R., Marsden, Gaelen, Molavi, Reza, Oh, Travis, Poulin-Lamarre, Gabriel, Ramp, Hugh, Rich, Chris, Clavera, Berta Trullas, Tsai, Nicholas, Volkmann, Mark, Whittaker, Jed D., Yao, Jason, Heinsdorf, Niclas, Kaushal, Nitin, Nocera, Alberto, and Franz, Marcel

Subjects
Quantum Physics
Abstract

Quantum Error Mitigation (QEM) presents a promising near-term approach to reduce error when estimating expectation values in quantum computing. Here, we introduce QEM techniques tailored for quantum annealing, using Zero-Noise Extrapolation (ZNE). We implement ZNE through zero-temperature extrapolation as well as energy-time rescaling. We conduct experimental investigations into the quantum critical dynamics of a transverse-field Ising spin chain, demonstrating the successful mitigation of thermal noise through both of these techniques. Moreover, we show that energy-time rescaling effectively mitigates control errors in the coherent regime where the effect of thermal noise is minimal. Our ZNE results agree with exact calculations of the coherent evolution over a range of annealing times that exceeds the coherent annealing range by almost an order of magnitude., Comment: 10 pages, 5 figures

Published
2023

5. Stable Bosonic Topological Edge Modes in the Presence of Many-Body Interactions

Author

Heinsdorf, Niclas, Joshi, Darshan G., Katsura, Hosho, and Schnyder, Andreas P.

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

Many magnetic materials are predicted to exhibit bosonic topological edge modes in their excitation spectra, because of the nontrivial topology of their magnon, triplon or other quasi-particle band structures. However, there is a discrepancy between theory prediction and experimental observation, which suggests some underlying mechanism that intrinsically suppresses the expected experimental signatures, like the thermal Hall current. Many-body interactions that are not accounted for in the non-interacting quasi-particle picture are most often identified as the reason for the absence of the topological edge modes. Here we report stable bosonic edge modes at the boundaries of a ladder quantum paramagnet with gapped triplon excitations in the presence of the full many-body interaction. For the first time, we use tensor network methods to resolve topological edge modes in the time-dependent spin-spin correlations and the dynamical structure factor, which is directly accessible experimentally. We further show that these edge modes have anomalously long time coherence, discuss the topological phase diagram of the model, demonstrate the fractionalization of its low-lying excitations, and propose potential material candidates.

Published
2023

6. Nature of the current-induced insulator-to-metal transition in Ca$_2$RuO$_4$ as revealed by transport-ARPES

Author

Suen, Cissy T, Marković, Igor, Zonno, Marta, Heinsdorf, Niclas, Zhdanovich, Sergey, Jo, Na-Hyun, Schmid, Michael, Hansmann, Philipp, Puphal, Pascal, Fürsich, Katrin, Zimmerman, Valentin, Smit, Steef, Au-Yeung, Christine, Zwartsenberg, Berend, Krautloher, Maximilian, Elfimov, Ilya S, Koch, Roland, Gorovikov, Sergey, Jozwiak, Chris, Bostwick, Aaron, Franz, Marcel, Rotenberg, Eli, Keimer, Bernhard, and Damascelli, Andrea

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

The Mott insulator Ca$_2$RuO$_4$ exhibits a rare insulator-to-metal transition (IMT) induced by DC current. While structural changes associated with this transition have been tracked by neutron diffraction, Raman scattering, and x-ray spectroscopy, work on elucidating the response of the electronic degrees of freedom is still in progress. Here we unveil the current-induced modifications of the electronic states of Ca$_2$RuO$_4$ by employing angle-resolved photoemission spectroscopy (ARPES) in conjunction with four-probe transport. Two main effects emerge: a clear reduction of the Mott gap and a modification in the dispersion of the Ru-bands. The changes in dispersion occur exclusively along the $XM$ high-symmetry direction, parallel to the $b$-axis where the greatest in-plane lattice change occurs. These experimental observations, together with dynamical mean-field theory (DMFT) calculations simulated from the current-induced structural distortions, indicate the intimate interplay of lattice and orbital-dependent electronic response in the current-driven IMT. Furthermore, based on a free energy analysis, we demonstrate that the current-induced phase, albeit thermodynamically equivalent, is electronically distinct from the high-temperature zero-current metallic phase. Our results provide insight into the elusive nature of the current-induced IMT of Ca$_2$RuO$_4$ and advance the challenging, yet powerful, technique of transport-ARPES., Comment: 10 pages, 5 figures

Published
2023
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7. Higher Berry curvature from matrix product states

Author

Shiozaki, Ken, Heinsdorf, Niclas, and Ohyama, Shuhei

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

The higher Berry curvature was introduced by Kapustin and Spodyneiko as an extension of the Berry curvature in quantum mechanical systems with finite degrees of freedom to quantum many-body systems in finite spatial dimensions. In this paper, we propose an alternative formulation of the higher Berry curvature using translationally invariant matrix product states. They are the ground states of a set of gapped Hamiltonians which are evolved adiabatically through a discretized parameter space. Because matrix product states transform under a projective representation, evaluating the Berry curvature on a closed loop through parameter space is not sufficient to fix all the gauge degrees of freedom. To obtain a gauge-invariant real quantity, the higher-dimensional Berry curvature is evaluated on small tetrahedra in parameter space. Our numerical calculations confirm that the higher Berry curvature varies continuously throughout an adiabatic evolution and becomes quantized over a closed 3-dimensional parameter space., Comment: Sec. V-B-2, numerical calculation for random J1 J2 added

Published
2023

8. Fundamental laws of chiral band crossings: local constraints, global constraints, and topological phase diagrams

Author

Alpin, Kirill, Hirschmann, Moritz M., Heinsdorf, Niclas, Leonhardt, Andreas, Yau, Wan Yee, Wu, Xianxin, and Schnyder, Andreas P.

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

We derive two fundamental laws of chiral band crossings: (i) a local constraint relating the Chern number to phase jumps of rotation eigenvalues; and (ii) a global constraint determining the number of chiral crossings on rotation axes. Together with the fermion doubling theorem, these laws describe all conditions that a network of chiral band crossing must satisfy. We apply the fundamental laws to prove the existence of enforced double Weyl points, nodal planes, and generic Weyl points, among others. In addition, we show that chiral space-group symmetries cannot stabilize nodal lines with finite Chern numbers. Combining the local constraint with explicit low-energy models, we determine the generic topological phase diagrams of all multi-fold crossings. Remarkably, we find a four-fold crossing with Chern number 5, which exceeds the previously conceived maximum Chern number of 4. We identify BaAsPt as a suitable material with this four-fold crossing exhibiting Chern number 5 near the Fermi energy., Comment: 34 pages, 16 figures

Published
2023
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9. Symmetry-enforced topological band crossings in orthorhombic crystals: Classification and materials discovery

Author

Leonhardt, Andreas, Hirschmann, Moritz M., Heinsdorf, Niclas, Wu, Xianxin, Fabini, Douglas H., and Schnyder, Andreas P.

Subjects
Condensed Matter - Materials Science
Abstract

We identify all symmetry-enforced band crossings in nonmagnetic orthorhombic crystals with and without spin-orbit coupling and discuss their topological properties. We find that orthorhombic crystals can host a large number of different band degeneracies, including movable Weyl and Dirac points with hourglass dispersions, fourfold double Weyl points, Weyl and Dirac nodal lines, almost movable nodal lines, nodal chains, and topological nodal planes. Interestingly, spin-orbit coupled materials in the space groups 18, 36, 44, 45, and 46 can have band pairs with only two Weyl points in the entire Brillouin zone. This results in a simpler connectivity of the Fermi arcs and more pronounced topological responses than in materials with four or more Weyl points. In addition, we show that the symmetries of the space groups 56, 61, and 62 enforce nontrivial weak $\mathbb{Z}_2$ topology in materials with strong spin-orbit coupling, leading to helical surface states. With these classification results in hand, we perform extensive database searches for orthorhombic materials crystallizing in the relevant space groups. We find that Sr$_2$Bi$_3$ and Ir$_2$Si have bands crossing the Fermi energy with a symmetry-enforced nontrivial $\mathbb{Z}_2$ invariant, CuIrB possesses nodal chains near the Fermi energy, Pd$_7$Se$_4$ and Ag$_2$Se exhibit fourfold double Weyl points, the latter one even in the absence of spin-orbit coupling, whereas the fourfold degeneracies in AuTlSb are made up from intersecting nodal lines. For each of these examples we compute the ab-initio band structures, discuss their topologies, and for some cases also calculate the surface states., Comment: 26 pages, 14 figures, supplemental material

Published
2021
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10. A semimetallic square-octagon (fes) two-dimensional polymer with high mobility

Author

Liu, Tsai-Jung, Springer, Maximilian A., Heinsdorf, Niclas, Kuc, Agnieszka, Valentí, Roser, and Heine, Thomas

Subjects
Condensed Matter - Materials Science
Abstract

The electronic properties of $\pi$-conjugated two-dimensional (2D) polymers near the Fermi level are determined by structural topology and chemical composition. Thus, tight-binding (TB) calculations of the corresponding fundamental network can be used to explore the parameter space to find configurations with intriguing properties before designing the the atomistic 2D polymer network. The vertex-transitive \textbf{fes} lattice, which is also called square-octagon lattice, is rich in interesting topological features including Dirac points and flat bands. Herein, we study its electronic and topological properties within the TB framework using representative parameters for chemical systems. Secondly, we demonstrate that the rational implementation of band structure features obtained from TB calculations into 2D polymers is feasible with a family of 2D polymers possessing \textbf{fes} structure. A one-to-one band structure correspondence between fundamental network and 2D polymers is found. Moreover, changing the relative length of linkers connecting the triangulene units in the 2D polymers reflect tuning of hopping parameters in the TB model. These perturbations allow to open sizeable local band gaps at various positions in the Brillouin zone. From analysis of Berry curvature flux, none of the polymers exhibits a large topologically non-trivial band gap. However, we find a particular configuration of semimetallic characteristics with separate electron and hole pockets, which possess very low effective masses both for electrons (as small as $m^*_\mathrm{e} = 0.05$) and holes (as small as $m^*_\mathrm{h} = 0.01$).

Published
2021
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11. Towards a Topological Quantum Chemistry description of correlated systems: the case of the Hubbard diamond chain

Author

Iraola, Mikel, Heinsdorf, Niclas, Tiwari, Apoorv, Lessnich, Dominik, Mertz, Thomas, Ferrari, Francesco, Fischer, Mark H., Winter, Stephen M., Pollmann, Frank, Neupert, Titus, Valentí, Roser, and Vergniory, Maia G.

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

The recently introduced topological quantum chemistry (TQC) framework has provided a description of universal topological properties of all possible band insulators in all space groups based on crystalline unitary symmetries and time reversal. While this formalism filled the gap between the mathematical classification and the practical diagnosis of topological materials, an obvious limitation is that it only applies to weakly interacting systems-which can be described within band theory. It is an open question to which extent this formalism can be generalized to correlated systems that can exhibit symmetry protected topological phases which are not adiabatically connected to any band insulator. In this work we address the many facettes of this question by considering the specific example of a Hubbard diamond chain. This model features a Mott insulator, a trivial insulating phase and an obstructed atomic limit phase. Here we discuss the nature of the Mott insulator and determine the phase diagram and topology of the interacting model with infinite density matrix renormalization group calculations, variational Monte Carlo simulations and with many-body topological invariants. We then proceed by considering a generalization of the TQC formalism to Green's functions combined with the concept of topological Hamiltonian to identify the topological nature of the phases, using cluster perturbation theory to calculate the Green's functions. The results are benchmarked with the above determined phase diagram and we discuss the applicability and limitations of the approach and its possible extensions., Comment: 16 pages, 13 figures

Published
2021
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12. Anisotropic superconductivity and Fermi surface reconstruction in the spin-vortex antiferromagnetic superconductor CaK(Fe$_{0.95}$Ni$_{0.05}$)$_4$As$_4$

Author

Llorens, José Benito, Herrera, Edwin, Barrena, Víctor, Wu, Beilun, Heinsdorf, Niclas, Borisov, Vladislav, Valentí, Roser, Meier, William R., Bud'ko, Sergey, Canfield, Paul C., Guillamón, Isabel, and Suderow, Hermann

Subjects
Condensed Matter - Superconductivity
Abstract

High critical temperature superconductivity often occurs in systems where an antiferromagnetic order is brought near $T=0K$ by slightly modifying pressure or doping. CaKFe$_4$As$_4$ is a superconducting, stoichiometric iron pnictide compound showing optimal superconducting critical temperature with $T_c$ as large as $38$ K. Doping with Ni induces a decrease in $T_c$ and the onset of spin-vortex antiferromagnetic order, which consists of spins pointing inwards to or outwards from alternating As sites on the diagonals of the in-plane square Fe lattice. Here we study the band structure of CaK(Fe$_{0.95}$Ni$_{0.05}$)$_4$As$_4$ (T$_c$ = 10 K, T$_N$ = 50 K) using quasiparticle interference with a Scanning Tunneling Microscope (STM) and show that the spin-vortex order induces a Fermi surface reconstruction and a fourfold superconducting gap anisotropy., Comment: 5 pages, 4 figures, Supplemental Material on request

Published
2020
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16. Towards a topological quantum chemistry description of correlated systems: The case of the Hubbard diamond chain

Author

Iraola, Mikel, primary, Heinsdorf, Niclas, additional, Tiwari, Apoorv, additional, Lessnich, Dominik, additional, Mertz, Thomas, additional, Ferrari, Francesco, additional, Fischer, Mark H., additional, Winter, Stephen M., additional, Pollmann, Frank, additional, Neupert, Titus, additional, Valentí, Roser, additional, and Vergniory, Maia G., additional

Published
2021
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19. Prediction of Double-Weyl Points in the Iron-Based Superconductor CaKFe$_4$As$_4$

Author

Heinsdorf, Niclas, Christensen, Morten H., Iraola, Mikel, Zhang, Shang-Shun, Yang, Fan, Birol, Turan, Batista, Cristian D., Valenti, Roser, and Fernandes, Rafael M.

Subjects
Condensed Matter - Strongly Correlated Electrons, SEMIMETAL, Strongly Correlated Electrons (cond-mat.str-el), TOTAL-ENERGY CALCULATIONS, DISCOVERY, FOS: Physical sciences, STATE
Abstract

Employing a combination of symmetry analysis, low-energy modeling, and ab initio simulations, we predict the presence of magnetic-field-induced Weyl points close to the Fermi level in CaKFe$_4$As$_4$. Depending on the relative strengths of the magnetic field and of the spin-orbit coupling, the Weyl fermions can carry a topological charge of $\pm1$ or $\pm2$, making CaKFe$_4$As$_4$ a rare realization of a double-Weyl semimetal. We further predict experimental manifestations of these Weyl points, both in bulk properties, such as the anomalous Hall effect, and in surface properties, such as the emergence of prominent Fermi arcs. Because CaKFe$_4$As$_4$ displays unconventional fully-gapped superconductivity below 30 K, our findings open a novel route to investigate the interplay between superconductivity and Weyl fermions.

Published
2021

20. Anisotropic superconductivity in the spin-vortex antiferromagnetic superconductor CaK(Fe0.95Ni0.05)4As4

Author

Benito Llorens, José, Herrera Vasco, Edwin, Barrena Escolar, Víctor, Wu, Beilun, Heinsdorf, Niclas, Borisov, Vladislav, Valentí, Roser, Meier, William R., Bud’ko, Sergey, Canfield, Paul C., Guillamón Gómez, Isabel, Suderow Rodríguez, Hermann Jesús, and UAM. Departamento de Física de la Materia Condensada

Subjects
Superconductivity, Física, Iron-based Superconductors, Group 5A Compounds
Published
2021

21. Towards a topological quantum chemistry description of correlated systems: The case of the Hubbard diamond chain

Author

Iraola, Mikel; https://orcid.org/0000-0002-4228-9864, Heinsdorf, Niclas, Tiwari, Apoorv; https://orcid.org/0000-0003-4742-775X, Lessnich, Dominik; https://orcid.org/0000-0001-6576-558X, Mertz, Thomas; https://orcid.org/0000-0002-3273-6050, Ferrari, Francesco; https://orcid.org/0000-0003-1543-2861, Fischer, Mark H; https://orcid.org/0000-0003-0810-6064, Winter, Stephen M, Pollmann, Frank, Neupert, Titus; https://orcid.org/0000-0003-0604-041X, Valentí, Roser; https://orcid.org/0000-0003-0497-1165, Vergniory, Maia G, Iraola, Mikel; https://orcid.org/0000-0002-4228-9864, Heinsdorf, Niclas, Tiwari, Apoorv; https://orcid.org/0000-0003-4742-775X, Lessnich, Dominik; https://orcid.org/0000-0001-6576-558X, Mertz, Thomas; https://orcid.org/0000-0002-3273-6050, Ferrari, Francesco; https://orcid.org/0000-0003-1543-2861, Fischer, Mark H; https://orcid.org/0000-0003-0810-6064, Winter, Stephen M, Pollmann, Frank, Neupert, Titus; https://orcid.org/0000-0003-0604-041X, Valentí, Roser; https://orcid.org/0000-0003-0497-1165, and Vergniory, Maia G

Abstract

The recently introduced topological quantum chemistry (TQC) framework has provided a description of universal topological properties of all possible band insulators in all space groups based on crystalline unitary symmetries and time reversal. While this formalism filled the gap between the mathematical classification and the practical diagnosis of topological materials, an obvious limitation is that it only applies to weakly interacting systems, which can be described within band theory. It is an open question to which extent this formalism can be generalized to correlated systems that can exhibit symmetry-protected topological phases which are not adiabatically connected to any band insulator. In this work, we address the many facets of this question by considering the specific example of an extended version of a Hubbard diamond chain. This model features a Mott insulator, a trivial insulating phase, and an obstructed atomic limit phase. Here we first discuss the nature of the Mott insulator and determine the phase diagram and topology of the interacting model with infinite density matrix renormalization group calculations, variational Monte Carlo simulations, and with many-body topological invariants. We then proceed by considering a generalization of the TQC formalism to Green's functions combined with the concept of a topological Hamiltonian to identify the topological nature of the phases. Here we use cluster perturbation theory to calculate the Green's functions. The results are benchmarked with the above-determined phase diagram, and we discuss the applicability and limitations of the approach and its possible extensions in the diagnosis of topological phases in materials, in contrast to the use of many-body topological invariants.

Published
2021

22. Anisotropic superconductivity and Fermi surface reconstruction in the spin-vortex antiferromagnetic superconductor CaK(Fe$_{0.95}$Ni$_{0.05}$)$_4$As$_4$

Author

Llorens, Jos�� Benito, Herrera, Edwin, Barrena, V��ctor, Wu, Beilun, Heinsdorf, Niclas, Borisov, Vladislav, Valent��, Roser, Meier, William R., Bud'ko, Sergey, Canfield, Paul C., Guillam��n, Isabel, and Suderow, Hermann

Subjects
Superconductivity (cond-mat.supr-con), Condensed Matter::Superconductivity, Condensed Matter - Superconductivity, FOS: Physical sciences, Condensed Matter::Strongly Correlated Electrons
Abstract

High critical temperature superconductivity often occurs in systems where an antiferromagnetic order is brought near $T=0K$ by slightly modifying pressure or doping. CaKFe$_4$As$_4$ is a superconducting, stoichiometric iron pnictide compound showing optimal superconducting critical temperature with $T_c$ as large as $38$ K. Doping with Ni induces a decrease in $T_c$ and the onset of spin-vortex antiferromagnetic order, which consists of spins pointing inwards to or outwards from alternating As sites on the diagonals of the in-plane square Fe lattice. Here we study the band structure of CaK(Fe$_{0.95}$Ni$_{0.05}$)$_4$As$_4$ (T$_c$ = 10 K, T$_N$ = 50 K) using quasiparticle interference with a Scanning Tunneling Microscope (STM) and show that the spin-vortex order induces a Fermi surface reconstruction and a fourfold superconducting gap anisotropy., 5 pages, 4 figures, Supplemental Material on request

Published
2020

23. Anisotropic superconductivity in the spin-vortex antiferromagnetic superconductor CaK(Fe0.95Ni0.05)4As4

Author

Llorens, José Benito, primary, Herrera, Edwin, additional, Barrena, Víctor, additional, Wu, Beilun, additional, Heinsdorf, Niclas, additional, Borisov, Vladislav, additional, Valentí, Roser, additional, Meier, William R., additional, Bud'ko, Sergey, additional, Canfield, Paul C., additional, Guillamón, Isabel, additional, and Suderow, Hermann, additional

Published
2021
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