Your search keyword '"Hirayama, Motoaki"' showing total 161 results

1. Designing single and degenerate flat bands in the Kagome lattice with long-range hopping

Author

Taguchi, Yuta, Hirayama, Motoaki, and Miyake, Takashi

Subjects

Condensed Matter - Materials Science

Abstract

We investigate the electronic structure of the kagome lattice model with first, second, and two kinds of third nearest-neighbor hoppings. We reveal that by tuning the third nearest-neighbor hoppings, not only single flat band but also degenerate flat band can be created on the \Gamma - M line. We provide the detailed conditions to realize them. The coexistence of these bands can be almost realized near the fundamental band gap in graphene with triangular defects in a superhoneycomb arrangement. Our results strongly indicate that long-range electron hopping has a new possibility for designing electronic structures., Comment: 6 pages, 4 figures and Supplemental Material

Published

2024

2. Ideal Spin-Orbit-Free Dirac Semimetal and Diverse Topological Transitions in Pr$_8$CoGa$_3$ Family

Author

Sato, Manabu, Bouaziz, Juba, Sumita, Shuntaro, Kobayashi, Shingo, Tateishi, Ikuma, Blügel, Stefan, Furusaki, Akira, and Hirayama, Motoaki

Subjects

Condensed Matter - Materials Science

Abstract

We propose from first-principles calculations that spin-orbit-free materials in the $RE_8\mathrm{Co}X_3$ group ($RE$ = rare earth elements, $X$ = Al, Ga, or In) are ideal spinless Dirac semimetals whose Fermi surfaces are fourfold degenerate band-crossing points (without including spin degeneracy). Despite the lack of space inversion symmetry in these materials, Dirac points are formed on the rotation-symmetry axis due to accidental degeneracies of two bands corresponding to different 2-dimensional irreducible representations of $C_{6v}$ group. The surface states have two midgap bands emanating from the projection in the surface Brillouin zone of the bulk Dirac points, in accordance with nontrivial Zak phases for each glide sector. We also investigate, through first-principles calculations and effective model analysis, various phase transitions caused by lattice distortion or elemental substitutions from the Dirac semimetal phase to distinct topological semimetallic phases such as nonmagnetic linked-nodal-line and Weyl semimetals (characterized by the second Stiefel-Whitney class) and ferromagnetic Weyl semimetals.

Published

2024

3. Topological Band Inversion and Chiral Majorana Mode in Hcp Thallium

Author

Hirayama, Motoaki, Nomoto, Takuya, and Arita, Ryotaro

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Materials Science

Abstract

The chiral Majorana fermion is an exotic particle that is its own antiparticle. It can arise in a one-dimensional edge of topological materials, and especially that in a topological superconductor can be exploited in non-Abelian quantum computation. While the chiral Majorana mode (CMM) remains elusive, a promising situation is realized when superconductivity coexists with a topologically non-trivial surface state. Here, we perform fully non-empirical calculation for the CMM considering superconductivity and surface relaxation, and show that hexagonal close-packed thallium (Tl) has an ideal electronic state that harbors the CMM. The $k_z=0$ plane of Tl is a mirror plane, realizing a full-gap band inversion corresponding to a topological crystalline insulating phase. Its surface and hinge are stable and easy to make various structures. Another notable feature is that the surface Dirac point is very close to the Fermi level, so that a small Zeeman field can induce a topological transition. Our calculation indicates that Tl will provide a new platform of the Majorana fermion., Comment: 10 pages, 6 figures

Published

2023

4. Crystal-symmetry-protected gapless vortex-line phases in superconducting Dirac semimetals

Author

Kobayashi, Shingo, Sumita, Shuntaro, Hirayama, Motoaki, and Furusaki, Akira

Subjects

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

Abstract

Vortex lines in superconducting Dirac semimetals realize crystal-symmetry-protected gapless vortex-line phases in which gapless excitations propagate inside a vortex line, in the presence of appropriate crystal symmetry, spin-orbit coupling, and multi-band structures. Here we present a general scheme to classify possible gapless vortex-line phases in superconducting Dirac semimetals with rotation (or screw) symmetry and inversion symmetry, assuming that the rotation (screw) axis is parallel to the vortex line. The rotation (screw)-symmetry-protected gapless modes are stable as long as they have different rotation (screw) eigenvalues. The underlying mechanism for the formation of gapless vortex bound states depends on irreducible representations of rotation (screw) symmetry subject to a vortex field and is classified into three types: (i) accidental band crossing of two vortex bound-state modes under rotation symmetry; (ii) accidental and (iii) enforced band crossing of four vortex bound-state modes under screw symmetry. We present a tight-binding model of screw-symmetry-protected Dirac semimetal with an $s$-wave pair potential, demonstrating a gapless vortex-line phase of type (ii). We obtain four gapless modes of vortex bound states whose gapless points (Majorana zero modes) pinned at a time-reversal invariant momentum (TRIM) when the Fermi energy is close to the Dirac points. As the Fermi energy is moved away from the Dirac points, the four gapless modes are split into a pair of two gapless modes with vanishing excitation energy at non-TRIMs. In closing, we discuss Nb$_3$Pt as a candidate material with the four-fold screw-symmetry-protected Dirac cones that can host a gapless vortex-line phase., Comment: 19 pages, 6 figures

Published

2023

5. Topological invariant and domain connectivity in moir\'e materials

Author

Tateishi, Ikuma and Hirayama, Motoaki

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Recently, a moir\'e material has been proposed in which multiple domains of different topological phases appear in the moir\'e unit cell due to a large moir\'e modulation. Topological properties of such moir\'e materials may differ from that of the original untwisted layered material. In this paper, we study how the topological properties are determined in moir\'e materials with multiple topological domains. We show a correspondence between the topological invariant of moir\'e materials at the Fermi level and the topology of the domain structure in real space. We also find a bulk-edge correspondence that is compatible with a continuous change of the truncation condition, which is specific to moir\'e materials. We demonstrate these correspondences in the twisted Bernevig-Hughes-Zhang model by tuning its moir\'e periodic mass term. These results give a feasible method to evaluate a topological invariant for all occupied bands of a moir\'e material, and contribute to the design of topological moir\'e materials and devices., Comment: 12 pages, 12 figures

Published

2022

6. Signature of topological band crossing in ferromagnetic Cr1/3NbSe2 epitaxial thin film

Author

Saika, Bruno Kenichi, Hamao, Satoshi, Majima, Yuki, Huang, Xiang, Matsuoka, Hideki, Yoshida, Satoshi, Kitamura, Miho, Sakano, Masato, Hatanaka, Tatsuto, Nomoto, Takuya, Hirayama, Motoaki, Horiba, Koji, Kumigashira, Hiroshi, Arita, Ryotaro, Iwasa, Yoshihiro, Nakano, Masaki, and Ishizaka, Kyoko

Subjects

Condensed Matter - Materials Science

Abstract

In intercalated transition metal dichalcogenides (I-TMDC), transition metal intercalation introduces magnetic phases which in some cases induce topological band crossing. However, evidence of the topological properties remains elusive in such materials. Here we employ angle-resolved photoemission spectroscopy to reveal the band structure of epitaxially grown ferromagnetic Cr1/3NbSe2. Experimental evidence of the Weyl crossing shows Cr1/3NbSe2 to be a topological ferromagnet. This work highlights I-TMDC as platform towards the interplay of magnetic and topological physics in low-dimensional systems., Comment: 18 pages (including references), 4 figures (placed at the end)

Published

2022

7. $Ab$ $initio$ material design of Ag-based oxides for high-$T_c$ superconductor

Author

Hirayama, Motoaki, Schmid, Michael Thobias, Tadano, Terumasa, Misawa, Takahiro, and Imada, Masatoshi

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Strongly Correlated Electrons

Abstract

We propose silver-based oxides with layered perovskite structure as candidates of exhibiting intriguing feature of strongly correlated electrons. The compounds show unique covalence between Ag d and O p orbitals with the strong electron correlation of their antibonding orbital similar to the copper oxide high-temperature superconductors, but stronger covalency and slightly smaller correlation strength. We examine $A_2$AgO$_2X_2$ with $A$ =Sr and Ba and $X$ =F, I and Cl in detail. Among them, Sr$_2$AgO$_2$F$_2$ has the largest effective onsite Coulomb repulsion and shows an antiferromagnetic insulating ground state, which competes with correlated metals. It offers features both similar and distinct from the copper oxides, and paves a new route. The possibility of superconductivity in doped systems is discussed., Comment: 25 pages, 21 figures, and 17 tables

Published

2022

8. Efficient hydrogen evolution reaction due to topological polarization

Author

Jiang, Ming-Chun, Guo, Guang-Yu, Hirayama, Motoaki, Yu, Tonghua, Nomoto, Takuya, and Arita, Ryotaro

Subjects

Condensed Matter - Materials Science

Abstract

Materials carrying topological surface states (TSS) provide a fascinating platform for the hydrogen evolution reaction (HER). Based on systematic first-principles calculations for $A_3 B$ ($A$ = Ni, Pd, Pt; $B$ = Si, Ge, Sn), we propose that topological electric polarization characterized by the Zak phase can be crucial to designing efficient catalysts for the HER. For $A_3 B$, we show that the Zak phase takes a nontrivial value of $\pi$ in the whole (111) projected Brillouin zone, which causes quantized electric polarization charge at the surface. There, depending on the adsorption sites, the hydrogen (H) atom hybridizes with the TSS rather than with the bulk states. When the hybridization has an intermediate character between the covalent and ionic bond, the H states are localized in the energy spectrum, and the change in the Gibbs free energy ($\Delta G$) due to the H adsorption becomes small. Namely, the interaction between the H states and the substrate becomes considerably weak, which is a highly favorable situation for the HER. Notably, we show that $\Delta G$ for Pt$_3$Sn and Pd$_3$Sn are just -0.066 and -0.092 eV, respectively, which are almost half of the value of Pt., Comment: 12 pages, 6 figures

Published

2022

9. $Ab$ $initio$ low-energy effective Hamiltonians for high-temperature superconducting cuprates Bi$_2$Sr$_2$CuO$_6$, Bi$_2$Sr$_2$CaCu$_2$O$_8$, HgBa$_2$CuO$_4$ and CaCuO$_2$

Author

Morée, Jean-Baptiste, Hirayama, Motoaki, Schmid, Michael Thobias, Yamaji, Youhei, and Imada, Masatoshi

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

We derive $ab$ $initio$ low-energy effective Hamiltonians (LEH) for high-temperature superconducting (SC) copper oxides Bi$_2$Sr$_2$CuO$_6$ (Bi2201, $N_{\ell}=1$, $T_c^{\rm exp} \sim 10$ K), Bi$_2$Sr$_2$CaCu$_2$O$_8$ (Bi2212, $N_{\ell}=2$, $T_c^{\rm exp} \sim 84$ K), HgBa$_2$CuO$_4$ (Hg1201, $N_{\ell}=1$, $T_c^{\rm exp} \sim 90$ K) and CaCuO$_2$ (Ca11, $N_{\ell}=\infty$, $T_c^{\rm exp} \sim 110$ K), with different experimental optimal SC transition temperature $T_c^{\rm exp}$ and number $N_{\ell}$ of laminated CuO$_2$ planes between the two neighboring block layers. We apply the latest methodology of the multiscale $ab$ $initio$ scheme for correlated electron systems (MACE), and focus on the LEH consisting of one antibonding (AB) Cu$3d_{x^2-y^2}$/O$2p_{\sigma}$ orbital centered on each Cu atom. We discuss prominent features of this LEH: (1) The ratio $U/|t_1|$ between the onsite effective Coulomb repulsion (ECR) $U$ and amplitude of nearest neighbour hopping $t_1$ increases with $T^{\rm exp}_c$ and $N_{\ell}$, consistently with the expected increase in $d$-wave SC correlation function $P_{dd}$ with $U/|t_1|$. One possible cause of the increase of $U/|t_1|$ is the replacement of apical O atoms by Cu atoms from neighbouring CuO$_2$ planes when $N_{\ell}$ increases. Furthermore, we show that the increase in distance between Cu and apical O atoms decreases the effective screening (ES) by electrons outside of the LEH and increases $U/|t_1|$. (2) For Hg1201 and Ca11, we show that $U/|t_1|$ decreases when hole doping per AB orbital $\delta$ increases, which may partly account for the disappearance of SC when $\delta$ exceeds the optimal value in experiment. (3) For $N_{\ell} \geq 2$, off-site inter-CuO$_2$ plane ECR is comparable to off-site intra-CuO$_2$ plane ECR. We discuss contributions of inter-CuO$_2$ plane ECR to both $P_{dd}$ and the stability of the SC state., Comment: 26 pages, 8 figures, 11 tables. The Supplemental Material contains the complete list of parameters for effective Hamiltonians presented in the main text, as well as complementary effective Hamiltonians mentioned in Footnote 1 (Page 2) and Footnote 2 (Page 3). This Supplemental Material may be obtained from the authors upon request

Published

2022

10. $\textit{Ab initio}$ Materials Design of Superconductivity in $d^9$ Nickelates

Author

Kitatani, Motoharu, Nomura, Yusuke, Hirayama, Motoaki, and Arita, Ryotaro

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Strongly Correlated Electrons

Abstract

Motivated by the recent theoretical materials design of superconducting $d^9$ nickelates for which the charge transfer from the NiO$_2$ to the block layer is completely suppressed [M. Hirayama $\textit{et al.}$, Phys. Rev. B $\textbf{101}$, 075107 (2020)], we perform a calculation based on the dynamical vertex approximation and obtain the phase diagram of RbCa$_2$NiO$_3$ and $A_2$NiO$_2$Br$_2$ where $A$ is a cation with a valence of 2.5+. We show that the phase diagram of these nickelates exhibits the same essential features as those found in cuprates. Namely, superconductivity appears upon hole-doping into an antiferromagnetic Mott insulator, and the superconducting transition temperature shows a dome-like shape. This demonstrates that the electron correlations play an essential role in nickelate superconductors and we can control them by changing block layers., Comment: 7 pages, 6 figures

Published

2022

11. Interstitial-Electron-Induced Topological Molecular Crystals

Author

Yu, Tonghua, Arita, Ryotaro, and Hirayama, Motoaki

Subjects

Condensed Matter - Materials Science

Abstract

Topological phases usually are unreachable in molecular solids, which are characteristic of weakly dispersed energy bands with a large gap, in contrast to topological materials. In this work, however, we propose that nontrivial electronic topology may ubiquitously emerge in a class of molecular crystals that contain interstitial electronic states, the bands of which are prone to be inverted with those of molecular orbitals. We provide guidelines hunt for such interstitial-electron-induced topological molecular crystals, especially in the topological insulating state. They exhibit a variety of exceptional qualities, as brought about by the intrinsic interplay of molecular crystals, interstitial electrons, and topological nature: (1) They may host cleavable surfaces along multiple orientations, with pronounced topological boundary states free from dangling bonds. (2) Strong response to moderate mechanical perturbations, whereby topological phase transition would occur under relatively low pressure. (3) Inherent high-efficiency thermoelectricity as jointly contributed by the non-parabolic band structure (therewith high thermopower), highly mobile interstitial electrons (high electrical conductivity), and soft phonons (small lattice thermal conductivity). (4) Ultralow work function owing to the active interstitial electrons. We utilize first-principles calculations to demonstrate these properties with the representative candidate K$_4$Ba$_2$[SnBi$_4$]. Our work suggests a pathway of realizing topological phases in bulk molecular systems, which may advance the interdisciplinary research between topological and molecular materials., Comment: Main text (14 pages, 6 figures); Supporting Information (6 pages, 6 figures)

Published

2022

12. $\textit{Ab initio}$ downfolding based on the GW approximation for infinite-layer nickelates

Author

Hirayama, Motoaki, Nomura, Yusuke, and Arita, Ryotaro

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

We derive an effective three-orbital model for the infinite-layer nickelates based on the band structure obtained by the GW approximation (GWA), where we consider the Ni 3$d_{x^2-y^2}$ and O 2$p$ orbitals forming the $\sigma$-bond. In the GWA, the self-energy correction to the local density approximation (LDA) increases the energy difference between Ni $3d_{x^2-y^2}$ and O $2p$, which reduces the bandwidth of the antibonding 3$d_{x^2-y^2}$ orbitals. The isolation of the Ni $3d_{x^2-y^2}$ around the Fermi level suppresses the screening effect. As a result, the correlation effect becomes more significant than that in the model constructed by the LDA-based downfolding. Furthermore, the Mott-Hubbard type character is enhanced in the GWA-based effective model, because the charge-transfer energy increases more rapidly compared to the increase in the interaction parameters., Comment: 13 pages, 5 figures

Published

2022

13. Quantum spin Hall effect from multi-scale band inversion in twisted bilayer Bi$_2$(Te$_{1-x}$Se$_x$)$_3$

Author

Tateishi, Ikuma and Hirayama, Motoaki

Subjects

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

Abstract

Moir\'e materials have become one of the most active fields in material science in recent years due to their high tunability, and their unique properties emerge from the Moir\'e-scale structure modulation. Here, we propose twisted bilayer Bi$_2$(Te$_{1-x}$Se$_x$)$_3$ as a new Moir\'e material where the Moir\'e-scale modulation induces a topological phase transition. We show, in twisted bilayer Bi$_2$(Te$_{1-x}$Se$_x$)$_3$, a topological insulator domain and a normal insulator domain coexist in the Moir\'e lattice structure, and edge states on the domain boundary make nearly flat bands that dominate the material properties. The edge states further contribute to a Moir\'e-scale band inversion, resulting in Moir\'e-scale topological states. There are corresponding Moir\'e-scale edge states and they are so to speak "edge state from edge state", which is a unique feature of twisted bilayer Bi$_2$(Te$_{1-x}$Se$_x$)$_3$. Our result not only proposes novel quantum phases in twisted bilayer Bi$_2$Te$_3$-family, but also suggests the twisting of stacking sensitive topological materials paves an avenue in the search for novel quantum materials and devices., Comment: 27 pages, 21 figures

Published

2021

14. Colossal negative magnetoresistance in field-induced Weyl semimetal of magnetic half-Heusler compound

Author

Ueda, Kentaro, Yu, Tonghua, Hirayama, Motoaki, Kurokawa, Ryo, Nakajima, Taro, Saito, Hiraku, Kriener, Markus, Hoshino, Manabu, Hashizume, Daisuke, Arima, Taka-hisa, Arita, Ryotaro, and Tokura, Yoshinori

Published

2023

15. Iron phosphide nanocrystals as an air-stable heterogeneous catalyst for liquid-phase nitrile hydrogenation

Author

Tsuda, Tomohiro, Sheng, Min, Ishikawa, Hiroya, Yamazoe, Seiji, Yamasaki, Jun, Hirayama, Motoaki, Yamaguchi, Sho, Mizugaki, Tomoo, and Mitsudome, Takato

Published

2023

16. Anisotropic superconductivity in topological crystalline metal Pb$_{1/3}$TaS$_2$ with multiple Dirac fermions

Author

Yang, Xiaohui, Yu, Tonghua, Xu, Chenchao, Wang, Jialu, Hu, Wanghua, Xu, Zhuokai, Wang, Tao, Zhang, Chao, Ren, Zhi, Xu, Zhu-an, Hirayama, Motoaki, Arita, Ryotaro, and Lin, Xiao

Subjects

Condensed Matter - Superconductivity

Abstract

Topological crystalline metals/semimetals (TCMs) have stimulated a great research interest, which broaden the classification of topological phases and provide a valuable platform to explore topological superconductivity. Here, we report the discovery of superconductivity and topological features in Pb-intercalated transition-metal dichalcogenide Pb$_{1/3}$TaS$_2$. Systematic measurements indicate that Pb$_{1/3}$TaS$_2$ is a quasi-two-dimensional (q-2D) type-II superconductor ({\em T}$_c \approx$ 2.8 K) with a significantly enhanced anisotropy of upper critical field ($\gamma_{H_{c2}}$ = $H_{c2}^{ab}/H_{c2}^{c}$ $\approx$ 17). In addition, first-principles calculations reveal that Pb$_{1/3}$TaS$_2$ hosts multiple topological Dirac fermions in the electronic band structure. We discover four groups of Dirac nodal lines on the $k_z = \pi$ plane and two sets of Dirac points on the rotation/screw axes, which are protected by crystalline symmetries and robust against spin-orbit coupling (SOC). Dirac-cone-like surface states emerge on the (001) surface because of band inversion. Our work shows that the TCM candidate Pb$_{1/3}$TaS$_2$ is a promising arena to study the interplay between superconductivity and topological Dirac fermions.

Published

2021

17. Emergence of spin-orbit coupled ferromagnetic surface state derived from Zak phase in a nonmagnetic insulator FeSi

Author

Ohtsuka, Yusuke, Kanazawa, Naoya, Hirayama, Motoaki, Matsui, Akira, Nomoto, Takuya, Arita, Ryotaro, Nakajima, Taro, Hanashima, Takayasu, Ukleev, Victor, Aoki, Hiroyuki, Mogi, Masataka, Fujiwara, Kohei, Tsukazaki, Atsushi, Ichikawa, Masakazu, Kawasaki, Masashi, and Tokura, Yoshinori

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

A chiral compound FeSi is a nonmagnetic narrow-gap insulator, exhibiting peculiar charge and spin dynamics beyond a simple band-structure picture. Those unusual features have been attracting renewed attention from topological aspects. Although a signature of surface conduction was indicated according to size-dependent resistivity in bulk crystals, its existence and topological properties remain elusive. Here we demonstrate an inherent surface ferromagnetic-metal state of FeSi thin films and its strong spin-orbit-coupling (SOC) properties through multiple characterizations of the two-dimensional (2D) conductance, magnetization and spintronic functionality. Terminated covalent-bonding orbitals constitute the polar surface state with momentum-dependent spin textures due to Rashba-type spin splitting, as corroborated by unidirectional magnetoresistance measurements and first-principles calculations. As a consequence of the spin-momentum locking, non-equilibrium spin accumulation causes magnetization switching. These surface properties are closely related to the Zak phase of the bulk band topology. Our findings propose another route to explore noble-metal-free materials for SOC-based spin manipulation., Comment: 22 pages, 6 figures, supplementary materials

Published

2021

18. Absence of conventional room temperature superconductivity at high pressure in carbon doped H$_3$S

Author

Wang, Tianchun, Hirayama, Motoaki, Nomoto, Takuya, Koretsune, Takashi, Arita, Ryotaro, and Flores-Livas, José A.

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Materials Science

Abstract

In this work, we show that the same theoretical tools that successfully explain other hydrides systems under pressure seem to be at odds with the recently claimed conventional room temperature superconductivity of the carbonaceous sulfur hydride. We support our conclusions with I) the absence of a dominant low-enthalpy stoichiometry and crystal structure in the ternary phase diagram. II) Only the thermodynamics of C-doping phases appears to be marginally competing in enthalpy against H$_3$S. III) Accurate results of the transition temperature given by ab initio Migdal-Eliashberg calculations differ by more than 110 K to recently theoretical claims explaining the high-temperature superconductivity in carbonaceous-hydrogen sulfide. A novel mechanism of superconductivity or a breakdown of current theories in this system is possibly behind the disagreement., Comment: 6 pages, 3 figures

Published

2021

19. Quantum transport observed in films of magnetic topological semimetal EuSb$_2$

Author

Ohno, Mizuki, Uchida, Masaki, Kurihara, Ryosuke, Minami, Susumu, Nakazawa, Yusuke, Sato, Shin, Kriener, Markus, Hirayama, Motoaki, Miyake, Atsushi, Taguchi, Yasujiro, Arita, Ryotaro, Tokunaga, Masashi, and Kawasaki, Masashi

Subjects

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

Abstract

We report fabrication of EuSb$_2$ single-crystalline films and investigation of their quantum transport. First-principles calculations demonstrate that EuSb$_2$ is a magnetic topological nodal-line semimetal protected by nonsymmorphic symmetry. Observed Shubnikov-de Haas oscillations with multiple frequency components exhibit small effective masses and two-dimensional field-angle dependence even in a 250 nm thick film, further suggesting possible contributions of surface states. This finding of the high-mobility magnetic topological semimetal will trigger further investigation of exotic quantum transport phenomena by controlling magnetic order in topological semimetal films., Comment: 14 pages, 4 figures + supplementary 6 pages, 5 figures

Published

2021

20. Multipole representation for anisotropic Coulomb interactions

Author

Iimura, Shoma, Hirayama, Motoaki, and Hoshino, Shintaro

Subjects

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

Abstract

Multipole representation is proposed for the anisotropic Coulomb interactions in solids. Any local interactions can be expressed as the product of two multipole operators, and the interaction parameters are systematically classified based on the point group symmetry. The form of the multipole interactions are restricted not only by the symmetry and Hermiticity but also by the spatial structure of the interaction, which is closely related to the presence or absence of the odd-rank multipoles. As an exemplary demonstration, the screened Coulomb interaction for SrVO$_3$ is considered, where only a few parameters are necessary for its description. By comparing it with the unscreened version, the totally symmetric $A_1$ representation is found to be strongly suppressed, but the $A_1$ component still gives a dominant contribution for the anisotropic part of the interaction. The anisotropic interactions are also applied to the localized two $f$-electron wave functions, which give the same-order contribution as the one-body level splitting estimated by the band structure calculation., Comment: 9 pages, 3 figures (submitted to PRB)

Published

2021

21. First-Principles Design of Halide-Reduced Electrides: Magnetism and Topological Phases

Author

Yu, Tonghua, Hirayama, Motoaki, Flores-Livas, José A., Huebsch, Marie-Therese, Nomoto, Takuya, and Arita, Ryotaro

Subjects

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

Abstract

We propose a design scheme for potential electrides derived from conventional materials. Starting with rare-earth-based ternary halides, we exclude halogens and perform global structure optimization to obtain thermodynamically stable or metastable phases but having an excess of electrons confined inside interstitial cavities. Then, spin-polarized interstitial states are induced by chemical substitution with magnetic lanthanides. To demonstrate the capability of our approach, we test with 11 ternary halides and successfully predict 30 stable and metastable phases of nonmagnetic electrides subject to 3 different stoichiometric categories, and successively 28 magnetic electrides via chemical substitution with Gd. 56 out of these 58 designed electrides are discovered for the first time. Two electride systems, the monoclinic $A$C ($A=$ La, Gd) and the orthorhombic $A_2$Ge ($A=$ Y, Gd), are thoroughly studied to exemplify the set of predicted crystals. Interestingly, both systems turn out to be topological nodal line electrides (TNLE) in the absence of spin-orbit coupling and manifest spin-polarized interstitial states in the case of $A=$ Gd. Our work establishes a novel computational approach of functional electrides design and highlights the magnetism and topological phases embedded in electrides., Comment: 13 pages, 10 figures

Published

2020

22. Enhancement of transverse thermoelectric conductivity originating from stationary points in nodal line

Author

Minami, Susumu, Ishii, Fumiyuki, Hirayama, Motoaki, Nomoto, Takuya, Koretsune, Takashi, and Arita, Ryotaro

Subjects

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

Abstract

Motivated by the recent discovery of a large anomalous Nernst effect in Co$_2$MnGa, Fe$_3X$ ($X$=Al, Ga) and Co$_3$Sn$_2$S$_2$, we performed a first-principles study to clarify the origin of the enhancement of the transverse thermoelectric conductivity ($\alpha_{ij}$) in these ferromagnets. The intrinsic contribution to $\alpha_{ij}$ can be understood in terms of the Berry curvature ($\Omega$) around the Fermi level, and $\Omega$ is singularly large along nodal lines (which are gapless in the absence of the spin-orbit coupling) in the Brillouin zone. We find that not only the Weyl points but also stationary points in the energy dispersion of the nodal lines play a crucial role. The stationary points make sharp peaks in the density of states projected onto the nodal line, clearly identifying the characteristic Fermi energies at which $\alpha_{ij}$ is most dramatically enhanced. We also find that $\alpha_{ij}/T$ breaks the Mott relation and show a peculiar temperature dependence at these energies. The present results suggest that the stationary points will give us a useful guiding principle to design magnets showing a large anomalous Nernst effect.

Published

2020

23. Magnetic exchange coupling in cuprate-analog $d^9$ nickelates

Author

Nomura, Yusuke, Nomoto, Takuya, Hirayama, Motoaki, and Arita, Ryotaro

Subjects

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

Abstract

Motivated by the recent discovery of superconductivity in doped NdNiO$_2$, we study the magnetic exchange interaction $J$ in layered $d^9$ nickelates from first principles. The mother compounds of the high-$T_{\rm c}$ cuprates belong to the charge-transfer regime in the Zaanen-Sawatzky-Allen diagram and have $J$ larger than 100 meV. While this feature makes the cuprates very different from other transition metal oxides, it is of great interest whether layered $d^9$ nickelates can also have such a large $J$. However, one complexity is that NdNiO$_2$ is not a Mott insulator due to carrier doping from the block layer. To compare the cuprates and $d^9$ nickelates on an equal basis, we study RbCa$_2$NiO$_3$ and $A_{2}$NiO$_{2}$Br$_2$ ($A$: a cation with the valence of $2.5+$), which were recently designed theoretically by block-layer engineering. These nickelates are free from the self-doping effect and belong to the Mott-Hubbard regime. We show that these nickelates share a common thread with the high-$T_{\rm c}$ cuprates in that they also have a significant exchange interaction $J$ as large as about 100 meV., Comment: 10 pages, 3 figures

Published

2020

24. Anomalous dielectric response in insulators with the pi Zak phase

Author

Aihara, Yusuke, Hirayama, Motoaki, and Murakami, Shuichi

Subjects

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

Abstract

In various topological phases, nontrivial states appear at the boundaries of the system. In this paper, we investigate anomalous dielectric response caused by such states caused by the pi Zak phase. First, by using the one-dimensional Su-Schrieffer-Heeger model, we show that, when the system is insulating and the Zak phase is pi, the polarization suddenly rises to a large value close to e/2, by application of an external electric field. The pi Zak phase indicates existence of half-filled edge states, and we attribute this phenomenon to charge transfer between the edge states at the two ends of the system. We extend this idea to two- and three-dimensional insulators with the pi Zak phase over the Brillouin zone, and find similar anomalous dielectric response. We also show that diamond and silicon slabs with (111) surfaces have the pi Zak phase by ab intio calculations, and show that this anomalous response survives even surface reconstruction involving an odd number of original surface unit cells. Another material example with an anomalous dielectric response is polytetrafluoroethylene (PTFE), showing plateaus of polarization at +e by ab initio calculation, in agreement with our theory., Comment: 19 pages, 15 figures

Published

2020

25. Vortex bound state of Kondo lattice coupled to compensated metal

Author

Iimura, Shoma, Hirayama, Motoaki, and Hoshino, Shintaro

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Strongly Correlated Electrons

Abstract

We theoretically study physical properties of the low-energy quasiparticle excitations at the vortex core in the full-gap superconducting state of the Kondo lattice coupled to compensated metals. Based on the mean-field description of the superconducting state, we numerically solve the Bogoliubov-de Gennes (BdG) equations for the tight-binding Hamiltonian. The isolated vortex is characterized by a length scale independent of the magnitude of the interaction and the energy level of the core bound state is the same order as the bulk gap. These properties are in strong contrast to the conventional s-wave superconductor. To gain further insights, we also consider the effective Hamiltonian in the continuous limit and construct the theoretical framework of the quasiclassical Green's function of conduction electrons. With the use of the Kramer-Pesch approximation, we analytically derive the spectral function describing the quasiparticle excitations which is consistent with the numerics. It has been revealed that the properties of the vortex bound state are closely connected to the characteristic odd frequency dependence of both the normal and anomalous self-energies which is proportional to the inverse of frequency., Comment: 16 pages, 6 figures

Published

2020

26. Higher-Order Topological Crystalline Insulating Phase and Quantized Hinge Charge in Topological Electride Apatite

Author

Hirayama, Motoaki, Takahashi, Ryo, Matsuishi, Satoru, Hosono, Hideo, and Murakami, Shuichi

Subjects

Condensed Matter - Materials Science

Abstract

In higher-order topological insulators, bulk and surface electronic states are gapped, while there appear gapless hinge states protected by spatial symmetry. Here we show by ab initio calculations that the La apatite electride is a higher-order topological crystalline insulator. It is a one-dimensional electride, in which the one-dimensional interstitial hollows along the $c$ axis support anionic electrons, and the electronic states in these one-dimensional channels are well approximated by the one-dimensional Su-Schrieffer-Heeger model. When the crystal is cleaved into a hexagonal prism, the 120$^\circ$ hinges support gapless hinge states, with their filling quantized to be 2/3. This quantization of the filling comes from a topological origin. We find that the quantized value of the filling depends on the fundamental blocks that constitute the crystal. The apatite consists of the triangular blocks, which is crucial for giving nontrivial fractional charge at the hinge., Comment: 13 pages, 11 figures

Published

2020

27. Material design with the van der Waals stacking of bismuth-halide chains realizing a higher-order topological insulator

Author

Noguchi, Ryo, Kobayashi, Masaru, Jiang, Zhanzhi, Kuroda, Kenta, Takahashi, Takanari, Xu, Zifan, Lee, Daehun, Hirayama, Motoaki, Ochi, Masayuki, Shirasawa, Tetsuroh, Zhang, Peng, Lin, Chun, Bareille, Cédric, Sakuragi, Shunsuke, Tanaka, Hiroaki, Kunisada, So, Kurokawa, Kifu, Yaji, Koichiro, Harasawa, Ayumi, Kandyba, Viktor, Giampietri, Alessio, Barinov, Alexei, Kim, Timur K., Cacho, Cephise, Hashimoto, Makoto, Lu, Donghui, Shin, Shik, Arita, Ryotaro, Lai, Keji, Sasagawa, Takao, and Kondo, Takeshi

Subjects

Condensed Matter - Materials Science

Abstract

The van der Waals (vdW) materials with low dimensions have been extensively studied as a platform to generate exotic quantum properties. Advancing this view, a great deal of attention is currently paid to topological quantum materials with vdW structures. Here, we provide a new concept of designing topological materials by the vdW stacking of quantum spin Hall insulators (QSHIs). Most interestingly, a slight shift of inversion center in the unit cell caused by a modification of stacking is found to induce the topological variation from a trivial insulator to a higher-order topological insulator (HOTI). Based on that, we present the first experimental realization of a HOTI by investigating a bismuth bromide Bi4Br4 with angle-resolved photoemission spectroscopy (ARPES). The unique feature in bismuth halides capable of selecting various topology only by differently stacking chains, combined with the great advantage of the vdW structure, offers a fascinating playground for engineering topologically non-trivial edge-states toward future spintronics applications., Comment: Nature Materials, in press. The final version of this article is available online at https://doi.org/10.1038/s41563-020-00871-7

Published

2020

28. Materials design of dynamically stable $d^9$ layered nickelates

Author

Hirayama, Motoaki, Tadano, Terumasa, Nomura, Yusuke, and Arita, Ryotaro

Subjects

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

Abstract

Motivated by the recent discovery of superconductivity in the Sr-doped layered nickelate NdNiO$_2$, we perform a systematic computational materials design of layered nickelates that are dynamically stable and whose electronic structure better mimics the electronic structure of high-$T_c$ cuprates than NdNiO$_2$. While the Ni $3d$ orbitals are self-doped from the $d^9$ configuration in NdNiO$_2$ and the Nd-layer states form Fermi pockets, we find more than 10 promising compounds for which the self-doping is almost or even completely suppressed. We derive effective single-band models for those materials and find that they are in the strongly-correlated regime. We also investigate the possibility of palladate analogues of high-$T_c$ cuprates. Once synthesized, these nickelates and palladates will provide a firm ground for studying superconductivity in the Mott-Hubbard regime of the Zaanen-Sawatzky-Allen classification., Comment: 20 pages, 11 figures

Published

2019

29. Formation of 2D single-component correlated electron system and band engineering in the nickelate superconductor NdNiO2

Author

Nomura, Yusuke, Hirayama, Motoaki, Tadano, Terumasa, Yoshimoto, Yoshihide, Nakamura, Kazuma, and Arita, Ryotaro

Subjects

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

Abstract

Motivated by the recent experimental discovery of superconductivity in the infinite-layer nickelate Nd0.8Sr0.2NiO2 [Li et al., Nature 572, 624 (2019)], we study how the correlated Ni 3dx2-y2 electrons in the NiO2 layer interact with the electrons in the Nd layer. We show that three orbitals are necessary to represent the electronic structure around the Fermi level: Ni 3dx2-y2, Nd 5d3z2-r2, and a bonding orbital made from an interstitial s orbital in the Nd layer and the Nd 5dxy orbital. By constructing a three-orbital model for these states, we find that the hybridization between the Ni 3dx2-y2 state and the states in the Nd layer is tiny. We also find that the metallic screening by the Nd layer is not so effective in that it reduces the Hubbard U between the Ni 3dx2-y2 electrons just by 10--20 %. On the other hand, the electron-phonon coupling is not strong enough to mediate superconductivity of Tc ~ 10 K. These results indicate that NdNiO2 hosts an almost isolated correlated 3dx2-y2 orbital system. We further study the possibility of realizing a more ideal single-orbital system in the Mott-Hubbard regime. We find that the Fermi pockets formed by the Nd-layer states dramatically shrink when the hybridization between the interstitial s state and Nd 5dxy state becomes small. By an extensive materials search, we find that the Fermi pockets almost disappear in NaNd2NiO4 and NaCa2NiO3., Comment: 12 peges, 7 figures, 5 tables, selected as "editor's suggestion" in Phys. Rev. B

Published

2019

30. Pressure-induced topological phase transition in noncentrosymmetric elemental Tellurium

Author

Ideue, Toshiya, Hirayama, Motoaki, Taiko, Hiroaki, Takahashi, Takanari, Murase, Masayuki, Miyake, Takashi, Murakami, Shuichi, Sasagawa, Takao, and Iwasa, Yoshihiro

Subjects

Condensed Matter - Materials Science

Abstract

Recent progress in understanding the electronic band topology and emergent topological properties encourage us to reconsider the band structure of well-known materials including elemental substances. Controlling such a band topology by external field is of particular interest from both fundamental and technological view point. Here we report the pressure-induced topological phase transition from a semiconductor to a Weyl semimetal in elemental tellurium probed by transport measurements. Pressure variation of the periods of Shubnikov-de Haas oscillations, as well as oscillations phases, shows an anomaly around the pressure theoretically predicted for topological phase transition. This behavior can be well understood by the pressure-induced band deformation and resultant band crossing effect. Moreover, effective cyclotron mass is reduced toward the critical pressure, potentially reflecting the emergence of massless linear dispersion. The present result paves the way for studying the electronic band topology in well-known compounds and topological phase transition by the external field.

Published

2019

31. Topological semimetal phases manifested in transition metal dichalcogenides intercalated with 3d metals

Author

Inoshita, Takeshi, Hirayama, Motoaki, Hamada, Noriaki, Hosono, Hideo, and Murakami, Shuichi

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

In the search for stable topological semimetals with clean band profiles, we have screened all the 3$d$ metal-intercalated transition-metal dichalcogenides (3dI-TMDCs) by performing hybrid-functional-based ab initio calculations. Two classes of topological materials featuring twelve Weyl nodes in the $k_z=0$ plane (without spin-orbit interactions) are identified: (a) time-reversal-breaking Weyl semimetals VT$_3$X$_6$ (ferromagnetic) and (b) spinless Weyl semimetals MnT$_3$X$_6$ (nonmagnetic), where T=Nb, Ta; X=S, Se. VNb$_3$S$_6$, prototypical of class (a), is half-metallic with only two bands crossing at the Fermi level to form Weyl nodes. MnNb$_3$S$_6$ in the nonmagnetic phase is essentially a spinless version of VNb$_3$S$_6$ featuring an equally clean and simple band profile. Although the space group symmetry (P6$_3$22) implies that the degeneracy between the two bands is lifted for $k$ away from the Weyl nodes, the gap remains extremely small ($\ll$ 0.1 meV) along a loop connecting the Weyl nodes. This quasi-nodal-line degeneracy is explained in terms of the quasi-mirror symmetry of the lattice, induced by the in-plane twofold rotation axes, and the specific orbital nature of the bands. 3dI-TMDCs are chemically and thermally stable stoichiometric compounds containing no toxic elements and are a viable platform for the study of topological condensed-matter physics., Comment: Revised to include a detailed discussion of the effect of spin-orbit interactions on the topology of VNb$_3$S$_6$. [See Figs. 2(d) and (e).] The other figures were also updated for enhanced clarity

Published

2019

32. Unconventional full-gap superconductivity in Kondo lattice with semi-metallic conduction bands

Author

Iimura, Shoma, Hirayama, Motoaki, and Hoshino, Shintaro

Subjects

Condensed Matter - Superconductivity

Abstract

A mechanism of superconductivity is proposed for the Kondo lattice which has semi-metallic conduction bands with electron and hole Fermi surfaces. At high temperatures, the $f$ electron's localized spins/pseudospins are fluctuating between electron and hole Fermi surfaces to seek for a partner to couple with. This system tries to resolve this frustration at low temperatures and chooses to construct a quantum mechanically entangled state composed of the Kondo singlet with electron surface and that with hole surface, to break the U(1) gauge symmetry. The corresponding order parameter is given by a composite pairing amplitude as a three-body bound states of localized spin/pseudospin, electron and hole. The electromagnetic response is considered, where composite pair itself does not contribute to the Meissner effect, but the induced pair between conduction electrons, which inevitably mixes due to e.g. a band cutoff effect at high energies, carries the superconducting current under the external field. Possible applications to real heavy-electron materials are also discussed., Comment: 11 pages, 3 figures

Published

2019

33. Ab Initio Study on Superconductivity and Inhomogeneity in Hg-based Cuprate Superconductor

Author

Ohgoe, Takahiro, Hirayama, Motoaki, Misawa, Takahiro, Ido, Kota, Yamaji, Youhei, and Imada, Masatoshi

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Understanding physics of high-$T_c$ cuprate superconductors remains one of the important problems in materials science. Though a number of diverse theories argue about the superconductivity and competing orders, ab initio and quantitative understanding is lacking. Here, we reproduce the experimental phase diagram of HgBa$_2$CuO$_{4+y}$ by solving its ab initio low-energy effective Hamiltonian without adjustable parameters. It shows a superconducting phase in a wide range of hole density $\delta$, and its competition with charge period-4 plus spin period-8 stripe order near $\delta \sim 0.1$, in agreement with experimental results including recent X-ray scattering. Then a crucial role of off-site interactions in stabilizing the superconductivity is elucidated with emphasis on charge fluctuations. It also clarifies the condensation energy mainly contributed from the onsite Coulomb interaction. The present achievement will enable deeper, predictable understanding on open issues of the high-$T_c$ superconducting mechanism and promote ab initio studies on strongly correlated electrons beyond parametrized model studies.

Published

2019

34. Effective Hamiltonian for cuprate superconductors derived from multi-scale ab initio scheme with level renormalization

Author

Hirayama, Motoaki, Misawa, Takahiro, Ohgoe, Takahiro, Yamaji, Youhei, and Imada, Masatoshi

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Superconductivity

Abstract

Three-types (three-band, two-band and one-band) of effective Hamiltonians for the HgBa$_2$CuO$_4$ and three-band effective Hamiltonian for La$_2$CuO$_4$ are derived beyond the level of the constrained-GW approximation combined with the self-interaction correction (cGW-SIC) derived in Hirayama et al. Phys. Rev. B 98, 134501 (2018) by improving the treatment of the interband Hartree energy. The charge gap and antiferromagnetic ordered moment show good agreement with the experimental results when the present effective Hamiltonian is solved, indicating the importance of the present refinement. The obtained Hamiltonians will serve to clarify the electronic structures of these copper oxide superconductors and to elucidate the superconducting mechanism., Comment: 23 pages, 21 figures and supplementary material(22 pages). arXiv admin note: text overlap with arXiv:1708.07498

Published

2019

35. Phonon Angular Momentum Induced by Temperature Gradient

Author

Hamada, Masato, Minamitani, Emi, Hirayama, Motoaki, and Murakami, Shuichi

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Phonon modes in crystals can have angular momenta in general. It nevertheless cancels in equilibrium when the time-reversal symmetry is preserved. In this paper we show that when a temperature gradient is applied and heat current flows in the crystal, the phonon distribution becomes off-equilibrium, and a finite angular momentum is generated by the heat current. This mechanism is analogous to the Edelstein effect in electronic systems. This effect requires crystals with sufficiently low crystallographic symmetries, such as polar or chiral crystal structures. Because of the positive charges of the nuclei, this phonon angular momentum induces magnetization. In addition, when the crystal can freely rotate, this generated phonon angular momentum is converted to a rigidbody rotation of the crystal, due to the conservation of the total angular momentum. Furthermore, in metallic crystals, the phonon angular momentum will be partially converted into spin angular momentum of electrons., Comment: 10 pages, 6 figures, to appear in Phys. Rev. Lett

Published

2018

36. Electrides as a New Platform of Topological Materials

Author

Hirayama, Motoaki, Matsuishi, Satoru, Hosono, Hideo, and Murakami, Shuichi

Subjects

Condensed Matter - Materials Science, Condensed Matter - Other Condensed Matter, Condensed Matter - Superconductivity, Physics - Chemical Physics, Physics - Computational Physics

Abstract

Recent discoveries of topological phases realized in electronic states in solids have revealed an important role of topology, which ubiquitously appears in various materials in nature. Many well-known materials have turned out to be topological materials, and this new viewpoint of topology has opened a new horizon in material science. In this paper we find that electrides are suitable for achieving various topological phases, including topological insulating and topological semimetal phases. In the electrides, in which electrons serve as anions, the bands occupied by the anionic electrons lie near the Fermi level, because the anionic electrons are weakly bound by the lattice. This property of the electrides is favorable for achieving band inversions needed for topological phases, and thus the electrides are prone to topological phases. From such a point of view, we find many topological electrides, Y$_2$C (nodal-line semimetal (NLS)), Sc$_2$C (insulator with $\pi$ Zak phase), Sr$_2$Bi (NLS), HfBr (quantum spin Hall system), and LaBr (quantum anomalous Hall insulator), by using ab initio calculation. The close relationship between the electrides and the topological materials is useful in material science in both fields., Comment: 12 pages, 9 figures

Published

2018

37. Nonreciprocal charge transport in topological superconductor candidate Bi2Te3/PdTe2 heterostructure

Author

Masuko, Makoto, Kawamura, Minoru, Yoshimi, Ryutaro, Hirayama, Motoaki, Ikeda, Yuya, Watanabe, Ryota, He, James Jun, Maryenko, Denis, Tsukazaki, Atsushi, Takahashi, Kei S., Kawasaki, Masashi, Nagaosa, Naoto, and Tokura, Yoshinori

Published

2022

38. Ab initio effective Hamiltonians for cuprate superconductors

Author

Hirayama, Motoaki, Yamaji, Youhei, Misawa, Takahiro, and Imada, Masatoshi

Subjects

Condensed Matter - Superconductivity

Abstract

Ab initio low-energy effective Hamiltonians of two typical high-temperature copper-oxide superconductors, whose mother compounds are La$_2$CuO$_4$ and HgBa$_2$CuO$_4$, are derived by utilizing the multi-scale ab initio scheme for correlated electrons (MACE). The effective Hamiltonians obtained in the present study serve as platforms of future studies to accurately solve the low-energy effective Hamiltonians beyond the density functional theory. It allows further study on the superconducting mechanism from the first principles and quantitative basis without adjustable parameters not only for the available cuprates but also for future design of higher Tc in general. More concretely, we derive effective Hamiltonians for three variations, 1)one-band Hamiltonian for the antibonding orbital generated from strongly hybridized Cu $3d_{x^2-y^2}$ and O $2p_\sigma$ orbitals 2)two-band Hamiltonian constructed from the antibonding orbital and Cu $3d_{3z^2-r^2}$ orbital hybridized mainly with the apex oxygen $p_z$ orbital 3)three-band Hamiltonian consisting mainly of Cu $3d_{x^2-y^2}$ orbitals and two O $2p_\sigma$ orbitals. Differences between the Hamiltonians for La$_2$CuO$_4$ and HgBa$_2$CuO$_4$, which have relatively low and high critical temperatures, respectively, at optimally doped compounds, are elucidated. The main differences are summarized as i) the oxygen $2p_\sigma$ orbitals are farther(~3.7eV) below from the Cu $d_{x^2-y^2}$ orbital for the La compound than the Hg compound(~2.4eV) in the three-band Hamiltonian. This causes a substantial difference in the character of the $d_{x^2-y^2}-2p_\sigma$ antibonding band at the Fermi level and makes the effective onsite Coulomb interaction U larger for the La compound than the Hg compound for the two- and one-band Hamiltonians. ii)The ratio of the second-neighbor to the nearest transfer t'/t is also substantially different (~0.26) for the Hg and ~0.15 for the La compound in the one-band Hamiltonian., Comment: 23 pages, 23 figures and supplementary material(18 pages)

Published

2017

39. Topological semimetals studied by ab initio calculations

Author

Hirayama, Motoaki, Okugawa, Ryo, and Murakami, Shuichi

Subjects

Condensed Matter - Materials Science

Abstract

In topological semimetals such as Weyl, Dirac, and nodal-line semimetals, the band gap closes at points or along lines in k space which are not necessarily located at high-symmetry positions in the Brillouin zone. Therefore, it is not straightforward to find these topological semimetals by ab initio calculations because the band structure is usually calculated only along high-symmetry lines. In this paper, we review recent studies on topological semimetals by ab initio calculations. We explain theoretical frameworks which can be used for the search for topological semimetal materials, and some numerical methods used in the ab initio calculations., Comment: 11 pages, 11 figures, to appear in J. Phys. Soc. Jpn

Published

2017

40. Spinless hourglass nodal-line semimetals

Author

Takahashi, Ryo, Hirayama, Motoaki, and Murakami, Shuichi

Subjects

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

Abstract

Nodal-line semimetals, one of the topological semimetals, have degeneracy along nodal lines where the band gap is closed. In many cases, the nodal lines appear accidentally, and in such cases it is impossible to determine whether the nodal lines appear or not, only from the crystal symmetry and the electron filling. In this paper, for spinless systems, we show that in specific space groups at $4N+2$ fillings ($8N+4$ fillings including the spin degree of freedom), presence of the nodal lines is required regardless of the details of the systems. Here, the spinless systems refer to crystals where the spin-orbit coupling is negligible and the spin degree of freedom can be omitted because of the SU(2) spin degeneracy. In this case the shape of the band structure around these nodal lines is like an hourglass, and we call this a spinless hourglass nodal-line semimetal. We construct a model Hamiltonian as an example and we show that it is always in the spinless hourglass nodal-line semimetal phase even when the model parameters are changed without changing the symmetries of the system. We also establish a list of all the centrosymmetric space groups, under which spinless systems always have hourglass nodal lines, and illustrate where the nodal lines are located. We propose that Al$_3$FeSi$_2$, whose space-group symmetry is Pbcn (No. 60), is one of the nodal-line semimetals arising from this mechanism., Comment: 14 pages, 9 figures

Published

2017

41. Band-driven switching of magnetism in a van der Waals magnetic semimetal

Author

Matsuoka, Hideki, primary, Kajihara, Shun, additional, Nomoto, Takuya, additional, Wang, Yue, additional, Hirayama, Motoaki, additional, Arita, Ryotaro, additional, Iwasa, Yoshihiro, additional, and Nakano, Masaki, additional

Published

2024

42. Topological band inversion and chiral Majorana mode in hcp thallium

Author

Hirayama, Motoaki, primary, Nomoto, Takuya, additional, and Arita, Ryotaro, additional

Published

2024

43. Emergence of topological semimetals in gap closing in semiconductors without inversion symmetry

Author

Murakami, Shuichi, Hirayama, Motoaki, Okugawa, Ryo, and Miyake, Takashi

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

A band gap for electronic states in crystals governs various properties of solids, such as transport, optical and magnetic properties. Its estimation and control have been an important issue in solid state physics. The band gap can be controlled externally by various parameters, such as pressure, atomic compositions and external field. Sometimes, the gap even collapses by tuning some parameter. In the field of topological insulators, such closing of the gap at a time-reversal invariant momentum indicates a band inversion, i.e. it leads to a topological phase transition from a normal insulator to a topological insulator. Here we show that the gap losing in inversion-asymmetric crystals is universal, in the sense that the gap closing always leads either to a Weyl semimetal or a nodal-line semimetal, from an exhaustive study on possible space groups. We here consider three-dimensional spinful systems with time-reversal symmetry. The space group of the system and the wavevector at the gap closing uniquely determine which possibility occurs and where the gap-closing points or lines lie in the wavevector space after closing of the gap. In particular, we show that an insulator-to-insulator transition never happens, which is in sharp contrast with inversion-symmetric systems., Comment: 13 pages, 8 figures

Published

2016

44. Topological Dirac Nodal Lines and Surface Charges in fcc Alkaline Earth Metals

Author

Hirayama, Motoaki, Okugawa, Ryo, Miyake, Takashi, and Murakami, Shuichi

Subjects

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

Abstract

In nodal-line semimetals, the gaps close along loops in ${\bf k}$ space, which are not at high-symmetry points. Typical mechanisms for the emergence of nodal lines involve mirror symmetry and the $\pi$ Berry phase. Here, we show via ab initio calculations that fcc calcium (Ca), strontium (Sr) and ytterbium (Yb) have topological nodal lines with the $\pi$ Berry phase near the Fermi level, when spin-orbit interaction is neglected. In particular, Ca becomes a nodal-line semimetal at high pressure. Owing to nodal lines, the Zak phase becomes either $\pi$ or 0 depending on the wavavector ${\bf k}$, and the $\pi$ Zak phase leads to surface polarization charge. Carriers eventually screen it, leaving behind large surface dipoles. In materials with nodal lines, both the large surface polarization charge and the emergent drumhead surface states enhance Rashba splitting when heavy adatoms are present, as we have shown to occur in Bi/Sr(111) and in Bi/Ag(111)., Comment: 14 pages, 11 figures

Published

2016

45. Low-energy effective Hamiltonians for correlated electron systems beyond density functional theory

Author

Hirayama, Motoaki, Miyake, Takashi, Imada, Masatoshi, and Biermann, Silke

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

We propose a refined scheme of deriving an effective low-energy Hamiltonian for materials with strong electronic Coulomb correlations beyond density functional theory (DFT). By tracing out the electronic states away from the target degrees of freedom in a controlled way by a perturbative scheme we construct an effective model for a restricted low-energy target space incorporating the effects of high-energy degrees of freedom in an effective manner. The resulting effective model can afterwards be solved by accurate many-body solvers. We improve this "multi-scale ab initio scheme for correlated electrons" (MACE) primarily in two directions: (1) Double counting of electronic correlations between the DFT and the low-energy solver is avoided by using the constrained GW scheme. (2) The frequency dependence of the interaction emerging from the partial trace summation is taken into account as a renormalization to the low-energy dispersion. The scheme is successfully tested on the example of SrVO3. Our work opens unexplored ways to understanding the electronic structure of strongly correlated systems beyond current DFT methods., Comment: 20 pages, 17 figures

Published

2015

46. Ab initio Studies of Magnetism in the Iron Chalcogenides FeTe and FeSe

Author

Hirayama, Motoaki, Misawa, Takahiro, Miyake, Takashi, and Imada, Masatoshi

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

The iron chalcogenides FeTe and FeSe belong to the family of iron-based superconductors. We study the magnetism in these compounds in the normal state using the ab initio downfolding scheme developed for strongly correlated electron systems. In deriving ab initio low-energy effective models, we employ the constrained GW method to eliminate the double counting of electron correlations originating from the exchange correlations already taken into account in the density functional theory. By solving the derived ab initio effective models, we reveal that the elimination of the double counting is important in reproducing the bicollinear antiferromagnetic order in FeTe, as is observed in experiments. We also show that the elimination of the double counting induces a unique degeneracy of several magnetic orders in FeSe, which may explain the absence of the magnetic ordering. We discuss the relationship between the degeneracy and the recently found puzzling phenomena in FeSe as well as the magnetic ordering found under pressure., Comment: 10 pages, 7 figures, 5 tables

Published

2015

47. Evidence for a higher-order topological insulator in a three-dimensional material built from van der Waals stacking of bismuth-halide chains

Author

Noguchi, Ryo, Kobayashi, Masaru, Jiang, Zhanzhi, Kuroda, Kenta, Takahashi, Takanari, Xu, Zifan, Lee, Daehun, Hirayama, Motoaki, Ochi, Masayuki, Shirasawa, Tetsuroh, Zhang, Peng, Lin, Chun, Bareille, Cédric, Sakuragi, Shunsuke, Tanaka, Hiroaki, Kunisada, So, Kurokawa, Kifu, Yaji, Koichiro, Harasawa, Ayumi, Kandyba, Viktor, Giampietri, Alessio, Barinov, Alexei, Kim, Timur K., Cacho, Cephise, Hashimoto, Makoto, Lu, Donghui, Shin, Shik, Arita, Ryotaro, Lai, Keji, Sasagawa, Takao, and Kondo, Takeshi

Published

2021

48. Weyl Node and Spin Texture in Trigonal Tellurium and Selenium

Author

Hirayama, Motoaki, Okugawa, Ryo, Ishibashi, Shoji, Murakami, Shuichi, and Miyake, Takashi

Subjects

Condensed Matter - Materials Science

Abstract

We study Weyl nodes in materials with broken inversion symmetry. We find based on first-principles calculations that trigonal Te and Se have multiple Weyl nodes near the Fermi level. The conduction bands have a spin splitting similar to the Rashba splitting around the H points, but unlike the Rashba splitting the spin directions are radial, forming a hedgehog spin texture around the H points, with a nonzero Pontryagin index for each spin-split conduction band. The Weyl semimetal phase, which has never been observed in real materials without inversion symmetry, is realized under pressure. The evolution of the spin texture by varying the pressure can be explained by the evolution of the Weyl nodes in k space., Comment: 8 pages, 6 figures

Published

2014

49. Iron-based binary ferromagnets for transverse thermoelectric conversion

Author

Sakai, Akito, Minami, Susumu, Koretsune, Takashi, Chen, Taishi, Higo, Tomoya, Wang, Yangming, Nomoto, Takuya, Hirayama, Motoaki, Miwa, Shinji, Nishio-Hamane, Daisuke, Ishii, Fumiyuki, Arita, Ryotaro, and Nakatsuji, Satoru

Published

2020

50. Derivation of Static Low-Energy Effective Models by ab initio Downfolding Method without Double Counting of Coulomb Correlations: Application to SrVO3, FeSe and FeTe

Author

Hirayama, Motoaki, Miyake, Takashi, and Imada, Masatoshi

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Derivation of low-energy effective models by a partial trace summation of the electronic degrees of freedom far away from the Fermi level, called downfolding, is reexamined. We propose an improved formalism free from the double-counting of electron correlation in the low-energy degrees of freedom. In this approach, the exchange-correlation energy in the local density approximation (LDA) is replaced with the constrained self-energy corrections defined by the sum of the contribution from eliminated high-energy degrees of freedom, Sigma H and that from the frequency-dependent part of the partially screened interaction, Delta Sigma L. We apply the formalism to SrVO3 as well as to two iron-based superconductors, FeSe and FeTe. The resultant bandwidths of the effective models are nearly the same as those of the previous downfolding formalism because of striking cancellations of Sigma H and Delta Sigma L. In SrVO3, the resultant bandwidth of the effective low-energy model is 2.56 eV (in comparison to LDA: 2.58 eV, full GW approximation: 2.19 eV). However, in the non-degenerate multi-band materials such as FeSe and FeTe, the momentum dependent self-energy effects yield substantial modifications of the band structures and relative shifts of orbital-energy levels of the effective models. The FeSe model indicates a substantial downward shift of the x2-y2 orbital level, which may lead to an increase in the filling of the x2-y2 orbital above half filling. It suggests a destruction of the orbital selective Mott phase of the x2-y2 orbital in agreement with the experimental absence of the antiferromagnetic phase., Comment: 23 pages, 20 figures, 12 tables; submitted to Physical Review B

Published

2012