Your search keyword '"Koretsune, Takashi"' showing total 298 results

1. Ab initio calculations of longitudinal electrical conductivity using a Wannier-based coherent potential approximation

Author

Namerikawa, Shota and Koretsune, Takashi

Subjects

Condensed Matter - Materials Science

Abstract

We present a longitudinal electrical conductivity calculation method for disordered alloys applicable from a wide range of density functional theory (DFT) codes based on the first-principles Wannier-based coherent potential approximation (Wannier-CPA). For evaluation of electrical conductivity, we employ two complementary methods; the Kubo-Greenwood formula and numerical analytic continuation of the current-current correlation function. We apply the developed method to Ag-Pd alloys and find that the results obtained by the Wannier-CPA reasonably reproduce previous studies by the well-established CPA implementation based on the Korringa-Kohn-Rostoker Green's function method (KKR-CPA)., Comment: 7 pages, 7 figures

Published

2024

2. Orbital paramagnetism without density of states enhancement in nodal-line semimetal ZrSiS

Author

Ozaki, Soshun, Matsuura, Hiroyasu, Tateishi, Ikuma, Koretsune, Takashi, and Ogata, Masao

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Unconventional orbital paramagnetism without enhancement of the density of states was recently discovered in the nodal-line semimetal ZrSiS. Here, we propose a novel interband mechanism of orbital paramagnetism associated with the negative curvature of energy dispersions, which successfully explains the observed anomalous orbital paramagnetism. This negative curvature arises from energy fluctuations along the nodal line, inherent in realistic nodal-line materials. Our new mechanism indicates that such orbital paramagnetism serves as strong evidence for the existence of nodal lines not only in ZrSiS but potentially in various other nodal-line materials as well.

Published

2024

3. High-throughput calculations of antiferromagnets hosting anomalous transport phenomena

Author

Nomoto, Takuya, Minami, Susumu, Yanagi, Yuki, Suzuki, Michi-To, Koretsune, Takashi, and Arita, Ryotaro

Subjects

Condensed Matter - Materials Science

Abstract

We develop a high-throughput computational scheme based on cluster multipole theory to identify new functional antiferromagnets. This approach is applied to 228 magnetic compounds listed in the AtomWork-Adv database, known for their elevated N\'eel temperatures. We conduct systematic investigations of both stable and metastable magnetic configurations of these materials. Our findings reveal that 34 of these compounds exhibit antiferromagnetic structures with zero propagation vectors and magnetic symmetries identical to conventional ferromagnets, rendering them potentially invaluable for spintronics applications. By cross-referencing our predictions with the existing MAGNDATA database and published literature, we verify the reliability of our findings for 26 out of 28 compounds with partially or fully elucidated magnetic structures in the experiments. These results not only affirm the reliability of our scheme but also point to its potential for broader applicability in the ongoing quest for the discovery of new functional magnets.13, Comment: 13 pages, 1 figure

Published

2024

4. Efficient calculation of magnetocrystalline anisotropy energy using symmetry-adapted Wannier functions

Author

Saito, Hiroto and Koretsune, Takashi

Subjects

Condensed Matter - Materials Science

Abstract

Magnetocrystalline anisotropy, a crucial factor in magnetic properties and applications like magnetoresistive random-access memory, often requires extensive $k$-point mesh in first-principles calculations. In this study, we develop a Wannier orbital tight-binding model incorporating crystal and spin symmetries and utilize time-reversal symmetry to divide magnetization components. This model enables efficient computation of magnetocrystalline anisotropy. Applying this method to $\mathrm{L1_0}$ $\mathrm{FePt}$ and $\mathrm{FeNi}$, we calculate the dependence of the anisotropic energy on $k$-point mesh size, chemical potential, spin-orbit interaction, and magnetization direction. The results validate the practicality of the models to the energy order of $10~[\mathrm{\mu eV}/f.u.]$.

Published

2024

5. Electron-doped magnetic Weyl semimetal LixCo3Sn2S2 by bulk-gating

Author

Matsuoka, Hideki, Fujishiro, Yukako, Minami, Susumu, Koretsune, Takashi, Arita, Ryotaro, Tokura, Yoshinori, and Iwasa, Yoshihiro

Subjects

Condensed Matter - Materials Science

Abstract

Manipulating carrier density through gate effects, both in electrostatic charge storage and electrochemical intercalation mode, offers powerful control over material properties, although commonly restricted to ultra-thin films or van der Waals materials. Here we demonstrate the application of gate-driven carrier modulation in the microdevice of magnetic Weyl semimetal Co3Sn2S2, fabricated from a bulk single crystal via focused ion beam (FIB). We discovered a Li-intercalated phase LixCo3Sn2S2 featuring electron doping exceeding 5*1021 cm-3, resulting in the Fermi energy shift of 200 meV. The carrier density dependent anomalous Hall conductivity shows fair agreement with density functional theory (DFT) calculation, which also predicts intercalated Li+ ion stabilization within the anion layer while maintaining the kagome-lattice intact. This likely explains the observed rigid band behavior and constant Curie temperature, contrasting with magnetic site substitution experiments. Our findings suggest ionic gating on FIB devices broadens the scope of gate-tuning in quantum materials.

Published

2023

6. Emergence of high-mobility carriers in topological kagome bad metal Mn$_3$Sn by intense photoexcitation

Author

Matsuda, Takuya, Higo, Tomoya, Kuroda, Kenta, Koretsune, Takashi, Kanda, Natsuki, Hirai, Yoshua, Peng, Hanyi, Matsuo, Takumi, Bareille, Cedric, Varykhalov, Andrey, Yoshikawa, Naotaka, Yoshinobu, Jun, Kondo, Takeshi, Shimano, Ryo, Nakatsuji, Satoru, and Matsunaga, Ryusuke

Subjects

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

Abstract

Kagome-lattice materials offer novel playgrounds of exploring topologically nontrivial states of electrons under influence of many-body interactions. A noncollinear kagome antiferromagnet Mn$_3$Sn has attracted particular interest for application in spintronics owing to the large anomalous Hall effect related to the Weyl dispersion near the Fermi energy. In addition, strong electronic correlation suggesting the Kondo physics has also been implied. However, the effect of correlation on the band topology and their interplay remains elusive. Here, we investigate nonequilibrium Hall transport in a photoexcited Mn$_3$Sn using time-resolved terahertz Faraday rotation spectroscopy. In equilibrium, Mn$_3$Sn is a bad metal close to the Mott-Ioffe-Regal limit with low carrier mobility, and thus only the anomalous Hall effect is discerned. By contrast, intense photoexcitation beyond an approximate threshold gives rise to a clear cyclotron resonance, namely the normal Hall effect, indicating the emergence of unusual carriers with 50 times lighter effective mass and 40 times less scattering. The lifetime of high-mobility carriers as long as a few tens of picoseconds and a threshold-like behavior for the pump fluence are hardly explained by contribution of photoexcited hot carriers. Instead, the emergence of unusual carriers may be accounted for by dielectric screening of the on-site Coulomb interaction by high-density delocalized photocarriers. A possible role of electronic correlation in equilibrium transport in Mn$_3$Sn beyond the single-particle picture is discussed., Comment: 28 pages, 6 figures

Published

2023

7. Superconductivity in CaH610 and ThH610 through fully ab initio Eliashberg method and self-consistent Green’s function

Author

Darussalam, Alwan Abdillah and Koretsune, Takashi

Published

2024

8. Interface tool from Wannier90 to RESPACK: wan2respack

Author

Kurita, Kensuke, Misawa, Takahiro, Yoshimi, Kazuyoshi, Ido, Kota, and Koretsune, Takashi

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

We develop the interface tool $\verb|wan2respack|$, which connects $\verb|RESPACK|$ (software that derives the low-energy effective Hamiltonians of solids) with $\verb|Wannier90|$ (software that constructs Wannier functions). $\verb|wan2respack|$ converts the Wannier functions obtained by $\verb|Wannier90|$ into those used in $\verb|RESPACK|$, which is then used to derive the low-energy effective Hamiltonians of solids. In this paper, we explain the basic usage of $\verb|wan2respack|$ and show its application to standard compounds of correlated materials, namely, the correlated metal SrVO$_3$ and the high-$T_{c}$ superconductor La$_2$CuO$_4$. Furthermore, we compare the low-energy effective Hamiltonians of these compounds using Wannier functions obtained by $\verb|Wannier90|$ and those obtained by $\verb|RESPACK|$. We confirm that both types of Wannier functions give the same Hamiltonians. This benchmark comparison demonstrates that $\verb|wan2respack|$ correctly converts Wannier functions in the $\verb|Wannier90|$ format into those in the $\verb|RESPACK|$ format., Comment: 10 pages, 6 figures

Published

2023

9. Light-induced chiral gauge field in a massive 3D Dirac electron system

Author

Yoshikawa, Naotaka, Hirai, Yoshua, Ogawa, Kazuma, Okumura, Shun, Fujiwara, Kohei, Ikeda, Junya, Koretsune, Takashi, Arita, Ryotaro, Mitra, Aditi, Tsukazaki, Atsushi, Oka, Takashi, and Shimano, Ryo

Subjects

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

Abstract

The concept of the chiral gauge field (CGF), originally developed in theoretical particle physics, has now emerged in condensed matter systems in materials known as Weyl semimetals. In general, Weyl semimetals emerge from Dirac semimetals when time-reversal or spatial-inversion symmetries are broken. Recently, it has gained a growing interest to manipulate such topological states of matter by implementing the CGF by shining light to materials. Here we have demonstrated the emergence of CGF in a massive 3D Dirac electron system in the paramagnetic phase of Co3Sn2S2, which exhibits a ferromagnetic Weyl semimetal phase at low temperatures. We first show theoretically that the illumination of circularly polarized light implements the CGF in the paramagnetic state of Co3Sn2S2 and gives rise to a topological Weyl state, which can be realized only in the nonequilibrium state. Then we demonstrated that the presence of light-induced CGF through the observation of light-induced anomalous Hall effect, the behavior of which quantitatively agrees with the calculation from the Floquet theory. The light-induced AHE manifests the Berry curvature which becomes nonzero as the bands split due to the light-induced CGF. Our demonstration paves a new pathway for ultrafast manipulation of topological phases in 3D Dirac semimetals and for further exploring new quantum matter phases which can be only achieved by light.

Published

2022

10. sparse-ir: optimal compression and sparse sampling of many-body propagators

Author

Wallerberger, Markus, Badr, Samuel, Hoshino, Shintaro, Kakizawa, Fumiya, Koretsune, Takashi, Nagai, Yuki, Nogaki, Kosuke, Nomoto, Takuya, Mori, Hitoshi, Otsuki, Junya, Ozaki, Soshun, Sakurai, Rihito, Vogel, Constanze, Witt, Niklas, Yoshimi, Kazuyoshi, and Shinaoka, Hiroshi

Subjects

Physics - Computational Physics, Condensed Matter - Strongly Correlated Electrons

Abstract

We introduce sparse-ir, a collection of libraries to efficiently handle imaginary-time propagators, a central object in finite-temperature quantum many-body calculations. We leverage two concepts: firstly, the intermediate representation (IR), an optimal compression of the propagator with robust a-priori error estimates, and secondly, sparse sampling, near-optimal grids in imaginary time and imaginary frequency from which the propagator can be reconstructed and on which diagrammatic equations can be solved. IR and sparse sampling are packaged into stand-alone, easy-to-use Python, Julia and Fortran libraries, which can readily be included into existing software. We also include an extensive set of sample codes showcasing the library for typical many-body and ab initio methods., Comment: 8 pages, 4 figures

Published

2022

11. Ultrafast Dynamics of Intrinsic Anomalous Hall Effect in the Topological Antiferromagnet Mn3Sn

Author

Matsuda, Takuya, Higo, Tomoya, Koretsune, Takashi, Kanda, Natsuki, Hirai, Yoshua, Peng, Hanyi, Matsuo, Takumi, Yoshikawa, Naotaka, Shimano, Ryo, Nakatsuji, Satoru, and Matsunaga, Ryusuke

Subjects

Condensed Matter - Materials Science

Abstract

We investigate ultrafast dynamics of the anomalous Hall effect (AHE) in the topological antiferromagnet Mn3Sn with sub-100 fs time resolution. Optical pulse excitations largely elevate the electron temperature up to 700 K, and terahertz probe pulses clearly resolves ultrafast suppression of the AHE before demagnetization. The result is well reproduced by microscopic calculation of the intrinsic Berry-curvature mechanism while the extrinsic contribution is clearly excluded. Our work opens a new avenue for the study of nonequilibrium AHE to identify the microscopic origin by drastic control of the electron temperature by light.

Published

2022

12. Wannier-based implementation of the coherent potential approximation with applications to Fe-based transition-metal alloys

Author

Ito, Naohiro, Nomoto, Takuya, Kobayashi, Koji, Mankovsky, Sergiy, Nomura, Kentaro, Arita, Ryotaro, Ebert, Hubert, and Koretsune, Takashi

Subjects

Condensed Matter - Materials Science

Abstract

We develop a formulation of the coherent potential approximation (CPA) on the basis of the Wannier representation to develop a computationally efficient method for the treatment of homogeneous random alloys that is independent on the applied first-principles electric structure code. To verify the performance of this CPA implementation within the Wannier representation, we examine the Bloch spectral function, the density of states (DOS), and the magnetic moment in Fe-based transition-metal alloys Fe-X (X = V, Co, Ni, and Cu), and compare the results with those of the well-established CPA implementation based on the KKR Green's function method. The Wannier-CPA and the KKR-CPA lead to results very close to each other. The presented Wannier-CPA method has a wide potential applicability to other physical quantities and large compound systems because of its low computational effort required., Comment: 10 pages, 7 figures

Published

2021

13. Quantum Anomalous Hall Effect in Three-dimensional Topological Insulator/Thin-film Ferromagnetic Metal Bilayer Structure

Author

Arimoto, Katsuhiro, Koretsune, Takashi, and Nomura, Kentaro

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We theoretically show that the three-dimensional (3D) topological insulator (TI)/thin-film ferromagnetic metal (FMM) bilayer structure is possible to be a quantum anomalous Hall (QAH) insulator with a wide global band gap. Studying the band structure and the weight distributions of eigenstates, we demonstrate that the attachment of a metallic thin-film on the 3DTI can shift the topologically non-trivial state into the metal layers due to the hybridization of bands around the original Dirac point. By introducing the magnetic exchange interaction in the thin-film layers, we compute the anomalous Hall conductivity and magnetic anisotropy of the bilayer structure to suggest the appearance of wider gap realizing QAH effect than usual materials, such as magnetically doped thin-films of 3DTI and 3DTI/ferromagnetic insulator heterostructures. Our results indicate that the 3DTI/thin-film FMM bilayer structure may implement the QAH effect even at room temperature, which will pave a way to the experimental realization of other exotic topological quantum phenomena., Comment: 9 pages, 5 figures

Published

2021

14. 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

15. Anomalous transport due to Weyl fermions in the chiral antiferromagnets Mn$_3$$X$, $X$ = Sn, Ge

Author

Chen, Taishi, Tomita, Takahiro, Minami, Susumu, Fu, Mingxuan, Koretsune, Takashi, Kitatani, Motoharu, Muhammad, Ikhlas, Nishio-Hamane, Daisuke, Ishii, Rieko, Ishii, Fumiyuki, Arita, Ryotaro, and Nakatsuji, Satoru

Subjects

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

Abstract

The recent discoveries of strikingly large zero-field Hall and Nernst effects in antiferromagnets Mn$_3$$X$, ($X$ = Sn, Ge) have brought the study of magnetic topological states to the forefront of condensed matter research and technological innovation. These effects are considered fingerprints of Weyl nodes residing near the Fermi energy, promoting Mn$_3$$X$, ($X$ = Sn, Ge) as a fascinating platform to explore the elusive magnetic Weyl fermions. In this review, we provide recent updates on the insights drawn from experimental and theoretical studies of Mn$_3$$X$, ($X$ = Sn, Ge) by combining previous reports with our new, comprehensive set of transport measurements of high-quality Mn$_3$Sn and Mn$_3$Ge single crystals. In particular, we report magnetotransport signatures specific to chiral anomalies in Mn$_3$Ge and planar Hall effect in Mn$_3$Sn, which have not yet been found in earlier studies. The results summarized here indicate the essential role of magnetic Weyl fermions in producing the large transverse responses in the absence of magnetization., Comment: 40 pages, 6 figures

Published

2020

16. Geometrical Hall effect and momentum-space Berry curvature from spin-reversed band pairs

Author

Hirschberger, Max, Nomura, Yusuke, Mitamura, Hiroyuki, Miyake, Atsushi, Koretsune, Takashi, Kaneko, Yoshio, Spitz, Leonie, Taguchi, Yasujiro, Matsuo, Akira, Kindo, Koichi, Arita, Ryotaro, Tokunaga, Masashi, and Tokura, Yoshinori

Subjects

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

Abstract

When nanometric, noncoplanar spin textures with scalar spin chirality (SSC) are coupled to itinerant electrons, they endow the quasiparticle wavefunctions with a gauge field, termed Berry curvature, in a way that bears analogy to relativistic spin-orbit coupling (SOC). The resulting deflection of moving charge carriers is termed geometrical (or topological) Hall effect. Previous experimental studies modeled this signal as a real-space motion of wavepackets under the influence of a quantum-mechanical phase. In contrast, we here compare the modification of Bloch waves themselves, and of their energy dispersion, due to SOC and SSC. Using the canted pyrochlore ferromagnet Nd$_2$Mo$_2$O$_7$ as a model compound, our transport experiments and first-principle calculations show that SOC impartially mixes electronic bands with equal or opposite spin, while SSC is much more effective for opposite spin band pairs., Comment: 14 pages, 4 figures

Published

2020

17. Reaching room temperature superconductivity by optimizing doping in LaH$_{10}$?

Author

Flores-Livas, José A., Wang, Tianchun, Nomoto, Takuya, Koretsune, Takashi, Ma, Yanming, Arita, Ryotaro, and Eremets, Mikhail

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Materials Science

Abstract

Intuitively, doping represents one of the most promising avenues for optimization of best prospect superconductors (SC) such as conventional high-pressure SCs with record critical temperatures. However, doping at high pressure (HP) is very challenging, and there is not a proved route to achieve it in a controlled fashion. Aided by computing simulations, we show that it may be plausible to start by alloying primary materials and subsequently incorporate high ratios of hydrogen at moderates pressures ($\approx$1.5 Mbar). Our theoretical results evidence the possibility to tune the electronic structure of LaH$_{10}$, increase the density of states at the Fermi level by doping of various elements and hence change their superconducting properties. We found aluminium to increase the occupation at the Fermi level by more than 30 %. Incorporation of other elements such as Si, Ge, H, Ir, Ca, and others with a varying percentage also play in favour to tune the electronic structure. More importantly, these predictions lie in experimentally attainable doping levels. Also, for the first time, we shed light on how the formation of defects and vacancies influence on the electronic structure of a HP-hydride superconductor. The concepts presented in this work can be extended to other high-pressure, hydrogen-based superconductors such as H$_3$S. Arguably, doping is one of the promising paths to reach room-temperature superconductivity, a Holy grail of condensed matter physics., Comment: 6 pages, Supplemental Material not included

Published

2020

18. 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

19. Efficient ab initio Migdal-Eliashberg calculation considering the retardation effect in phonon-mediated superconductors

Author

Wang, Tianchun, Nomoto, Takuya, Nomura, Yusuke, Shinaoka, Hiroshi, Otsuki, Junya, Koretsune, Takashi, and Arita, Ryotaro

Subjects

Condensed Matter - Superconductivity

Abstract

We formulate an efficient scheme to perform Migdal-Eliashberg calculation considering the retardation effect from first principles. While the conventional approach requires a huge number of Matsubara frequencies, we show that the intermediate representation of the Green's function [H. Shinaoka et al., Phys. Rev. B 96, 035147 (2017)] dramatically reduces the numerical cost to solve the linearized gap equation. Without introducing any empirical parameter, we demonstrate that we can successfully reproduce the experimental superconducting transition temperature of elemental Nb ($\sim 10$ K) very accurately. The present result indicates that our approach has a superior performance for many superconductors for which $T_{\rm c}$ is lower than ${\mathcal O}(10)$ K, Comment: 8 pages, 4 figures

Published

2020

20. Formation mechanism of helical Q structure in Gd-based skyrmion materials

Author

Nomoto, Takuya, Koretsune, Takashi, and Arita, Ryotaro

Subjects

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

Abstract

Using the ab initio local force method, we investigate the formation mechanism of the helical spin structure in GdRu$_2$Si$_2$ and Gd$_2$PdSi$_3$. We calculate the paramagnetic spin susceptibility and find that the Fermi surface nesting is not the origin of the incommensurate modulation, in contrast to the naive scenario based on the Ruderman-Kittel-Kasuya-Yosida mechanism. We then decompose the exchange interactions between the Gd spins into each orbital component, and show that spin-density-wave type interaction between the Gd-5$d$ orbitals is ferromagnetic, but the interaction between the Gd-4$f$ orbitals is antiferromagnetic. We conclude that the competition of these two interactions, namely, the inter-orbital frustration, stabilizes the finite-Q structure., Comment: 5 pages, 4 figures

Published

2020

21. Local force method for the ab initio tight-binding model with spin-dependent hopping

Author

Nomoto, Takuya, Koretsune, Takashi, and Arita, Ryotaro

Subjects

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

Abstract

To estimate the Curie temperature of metallic magnets from first principles, we develop a local force method for the tight-binding model having spin-dependent hopping derived from spin density functional theory. While spin-dependent hopping is crucial for the self-consistent mapping to the effective spin model, the numerical cost to treat such non-local terms in the conventional Green's function scheme is formidably expensive. Here, we propose a formalism based on the kernel polynomial method (KPM), which makes the calculation dramatically efficient. We perform a benchmark calculation for bcc-Fe, fcc-Co, and fcc-Ni and find that the effect of the magnetic non-local terms is particularly prominent for bcc-Fe. We also present several local approximations to the magnetic non-local terms for which we can apply the Green's function method and reduce the numerical cost further by exploiting the intermediate representation of the Green's function. By comparing the results of the KPM and local methods, we discuss which local method works most successfully. Our approach provides an efficient way to estimate the Curie temperature of metallic magnets with a complex spin configuration., Comment: 10 pages, 3 figures

Published

2020

22. Ferromagnetic state above room temperature in a proximitized topological Dirac semimetal

Author

Uchida, Masaki, Koretsune, Takashi, Sato, Shin, Kriener, Markus, Nakazawa, Yusuke, Nishihaya, Shinichi, Taguchi, Yasujiro, Arita, Ryotaro, and Kawasaki, Masashi

Subjects

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

Abstract

We report an above-room-temperature ferromagnetic state realized in a proximitized Dirac semimetal, which is fabricated by growing typical Dirac semimetal Cd$_3$As$_2$ films on a ferromagnetic garnet with strong perpendicular magnetization. Observed anomalous Hall conductivity with substantially large Hall angles is found to be almost proportional to magnetization and opposite in sign to it. Theoretical calculations based on first-principles electronic structure also demonstrate that the Fermi-level dependent anomalous Hall conductivity reflects the Berry curvature originating in the split Weyl nodes. The present Dirac-semimetal/ferromagnetic-insulator heterostructure will provide a novel platform for exploring Weyl-node transport phenomena and spintronic functions lately proposed for topological semimetals., Comment: 15 pages, 4 figures

Published

2019

23. Quantum Crystal Structure in the 250 K Superconducting Lanthanum Hydride

Author

Errea, Ion, Belli, Francesco, Monacelli, Lorenzo, Sanna, Antonio, Koretsune, Takashi, Tadano, Terumasa, Bianco, Raffaello, Calandra, Matteo, Arita, Ryotaro, Mauri, Francesco, and Flores-Livas, José A.

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Materials Science

Abstract

The discovery of superconductivity at 200 K in the hydrogen sulfide system at large pressures [1] was a clear demonstration that hydrogen-rich materials can be high-temperature superconductors. The recent synthesis of LaH$_{10}$ with a superconducting critical temperature (T$_{\text{c}}$) of 250 K [2,3] places these materials at the verge of reaching the long-dreamed room-temperature superconductivity. Electrical and x-ray diffraction measurements determined a weakly pressure-dependent T$_{\text{c}}$ for LaH$_{10}$ between 137 and 218 gigapascals in a structure with a face-centered cubic (fcc) arrangement of La atoms [3]. Here we show that quantum atomic fluctuations stabilize in all this pressure range a high-symmetry Fm-3m crystal structure consistent with experiments, which has a colossal electron-phonon coupling of $\lambda\sim3.5$. Even if ab initio classical calculations neglecting quantum atomic vibrations predict this structure to distort below 230 GPa yielding a complex energy landscape with many local minima, the inclusion of quantum effects simplifies the energy landscape evidencing the Fm-3m as the true ground state. The agreement between the calculated and experimental T$_{\text{c}}$ values further supports this phase as responsible for the 250 K superconductivity. The relevance of quantum fluctuations in the energy landscape found here questions many of the crystal structure predictions made for hydrides within a classical approach that at the moment guide the experimental quest for room-temperature superconductivity [4,5,6]. Furthermore, quantum effects reveal crucial to sustain solids with extraordinary electron-phonon coupling that may otherwise be unstable [7]., Comment: 20 Pages, 14 Figures, 4 Tables

Published

2019

24. Wannier90 as a community code: new features and applications

Author

Pizzi, Giovanni, Vitale, Valerio, Arita, Ryotaro, Blügel, Stefan, Freimuth, Frank, Géranton, Guillaume, Gibertini, Marco, Gresch, Dominik, Johnson, Charles, Koretsune, Takashi, Ibañez-Azpiroz, Julen, Lee, Hyungjun, Lihm, Jae-Mo, Marchand, Daniel, Marrazzo, Antimo, Mokrousov, Yuriy, Mustafa, Jamal I., Nohara, Yoshiro, Nomura, Yusuke, Paulatto, Lorenzo, Poncé, Samuel, Ponweiser, Thomas, Qiao, Junfeng, Thöle, Florian, Tsirkin, Stepan S., Wierzbowska, Małgorzata, Marzari, Nicola, Vanderbilt, David, Souza, Ivo, Mostofi, Arash A., and Yates, Jonathan R.

Subjects

Condensed Matter - Materials Science, Physics - Computational Physics

Abstract

Wannier90 is an open-source computer program for calculating maximally-localised Wannier functions (MLWFs) from a set of Bloch states. It is interfaced to many widely used electronic-structure codes thanks to its independence from the basis sets representing these Bloch states. In the past few years the development of Wannier90 has transitioned to a community-driven model; this has resulted in a number of new developments that have been recently released in Wannier90 v3.0. In this article we describe these new functionalities, that include the implementation of new features for wannierisation and disentanglement (symmetry-adapted Wannier functions, selectively-localised Wannier functions, selected columns of the density matrix) and the ability to calculate new properties (shift currents and Berry-curvature dipole, and a new interface to many-body perturbation theory); performance improvements, including parallelisation of the core code; enhancements in functionality (support for spinor-valued Wannier functions, more accurate methods to interpolate quantities in the Brillouin zone); improved usability (improved plotting routines, integration with high-throughput automation frameworks), as well as the implementation of modern software engineering practices (unit testing, continuous integration, and automatic source-code documentation). These new features, capabilities, and code development model aim to further sustain and expand the community uptake and range of applicability, that nowadays spans complex and accurate dielectric, electronic, magnetic, optical, topological and transport properties of materials., Comment: 26 pages, 8 figures

Published

2019

25. Importance of self-consistency in first-principles Eliashberg calculation for superconducting transition temperature

Author

Wang, Tianchun, Nomoto, Takuya, Koretsune, Takashi, and Arita, Ryotaro

Published

2023

26. Anomalous thermal Hall effect in the topological antiferromagnetic state

Author

Sugii, Kaori, Imai, Yusuke, Shimozawa, Masaaki, Ikhlas, Muhammad, Kiyohara, Naoki, Tomita, Takahiro, Suzuki, Michi-To, Koretsune, Takashi, Arita, Ryotaro, Nakatsuji, Satoru, and Yamashita, Minoru

Subjects

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

Abstract

The anomalous Hall effect (AHE), a Hall signal occurring without an external magnetic field, is one of the most significant phenomena. However, understanding the AHE mechanism has been challenging and largely restricted to ferromagnetic metals. Here, we investigate the recently discovered AHE in the chiral antiferromagnet Mn3Sn by measuring a thermal analog of the AHE, known as an anomalous thermal Hall effect (ATHE). The amplitude of the ATHE scales with the anomalous Hall conductivity of Mn3Sn over a wide temperature range, demonstrating that the AHE of Mn3Sn arises from a dissipationless intrinsic mechanism associated with the Berry curvature. Moreover, we find that the dissipationless AHE is significantly stabilized by shifting the Fermi level toward the magnetic Weyl points. Thus, in Mn3Sn, the Berry curvature emerging from the proposed magnetic Weyl fermion state is a key factor for the observed AHE and ATHE., Comment: 28 pages, 8 figures

Published

2019

27. Construction of maximally-localized Wannier functions using crystal symmetry

Author

Koretsune, Takashi

Published

2023

28. Giant anomalous Nernst effect and quantum-critical scaling in a ferromagnetic semimetal

Author

Sakai, Akito, Mizuta, Yo Pierre, Nugroho, Agustinus Agung, Sihombing, Rombang, Koretsune, Takashi, Suzuki, Michi-To, Takemori, Nayuta, Ishii, Rieko, Nishio-Hamane, Daisuke, Arita, Ryotaro, Goswami, Pallab, and Nakatsuji, Satoru

Subjects

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

Abstract

In metallic ferromagnets, the Berry curvature of underlying quasiparticles can cause an electric voltage perpendicular to both magnetization and an applied temperature gradient, a phenomenon called the anomalous Nernst effect (ANE). Here, we report the observation of a giant ANE in the full-Heusler ferromagnet Co$_2$MnGa, reaching $S_{yx}\sim -6$ $\mu$V/K at room $T$, one order of magnitude larger than the maximum value reported for a magnetic conductor. With increasing temperature, the transverse thermoelectric conductivity or Peltier coefficient $\alpha_{yx}$ shows a crossover between $T$-linear and $-T \log(T)$ behaviors, indicating the violation of Mott formula at high temperatures. Our numerical and analytical calculations indicate that the proximity to a quantum Lifshitz transition between type-I and type-II magnetic Weyl fermions is responsible for the observed crossover properties and an enhanced $\alpha_{yx}$. The $T$ dependence of $\alpha_{yx}$ in experiments and numerical calculations can be understood in terms of a quantum critical scaling function predicted by the low energy effective theory over more than a decade of temperatures. Moreover, the observation of chiral anomaly or an unsaturated positive longitudinal magnetoconductance also provide evidence for the existence of Weyl fermions in Co$_2$MnGa., Comment: 43 pages, 11 figures, 1 Table, To appear in Nature Physics

Published

2018

29. Electronic Structure Calculation and Superconductivity in $\lambda$-(BETS)$_{2}$GaCl$_{4}$

Author

Aizawa, Hirohito, Koretsune, Takashi, Kuroki, Kazuhiko, and Seo, Hitoshi

Subjects

Condensed Matter - Superconductivity

Abstract

Quasi-two-dimensional molecular conductor $\lambda$-(BETS)$_2$GaCl$_4$ shows superconductivity (SC) below 5.5K, neighboring the dimer-type Mott insulating phase. To elucidate the origin of SC and its gap function, we carry out first-principles band calculation and derive a four-band tight-binding model from the maximally localized Wannier orbitals. Considering the spin-fluctuation-mediated mechanism by adding the Hubbard $U$-term to the model, we analyze the SC gap function by applying the random phase approximation. We show that the SC gap changes its sign four times along the Fermi surface (FS) in the unfolded Brillouin zone, suggestive of a $d$-wave-like SC gap, which only has two-fold symmetry because of the low symmetry of the crystal structure. Decomposing the SC gap into the pairing functions along the crystal axes, we compare the result to similar analysis of the well-studied $\kappa$-type molecular conductors and to the experiments., Comment: 5 pages, 2 figures, 3 tables

Published

2018

30. Large magneto-optical Kerr effect and imaging of magnetic octupole domains in an antiferromagnetic metal

Author

Higo, Tomoya, Man, Huiyuan, Gopman, Daniel B., Wu, Liang, Koretsune, Takashi, Erve, Olaf M. J. van 't, Kabanov, Yury P., Rees, Dylan, Li, Yufan, Suzuki, Michi-To, Patankar, Shreyas, Ikhlas, Muhammad, Chien, C. L., Arita, Ryotaro, Shull, Robert D., Orenstein, Joseph, and Nakatsuji, Satoru

Subjects

Condensed Matter - Materials Science

Abstract

When a polarized light beam is incident upon the surface of a magnetic material, the reflected light undergoes a polarization rotation. This magneto-optical Kerr effect (MOKE) has been intensively studied in a variety of ferro- and ferrimagnetic materials because it provides a powerful probe for electronic and magnetic properties as well as for various applications including magneto-optical recording. Recently, there has been a surge of interest in antiferromagnets (AFMs) as prospective spintronic materials for high-density and ultrafast memory devices, owing to their vanishingly small stray field and orders of magnitude faster spin dynamics compared to their ferromagnetic counterparts. In fact, the MOKE has proven useful for the study and application of the antiferromagnetic (AF) state. Although limited to insulators, certain types of AFMs are known to exhibit a large MOKE, as they are weak ferromagnets due to canting of the otherwise collinear spin structure. Here we report the first observation of a large MOKE signal in an AF metal at room temperature. In particular, we find that despite a vanishingly small magnetization of $M \sim$0.002 $\mu_{\rm B}$/Mn, the non-collinear AF metal Mn$_3$Sn exhibits a large zero-field MOKE with a polar Kerr rotation angle of 20 milli-degrees, comparable to ferromagnetic metals. Our first-principles calculations have clarified that ferroic ordering of magnetic octupoles in the non-collinear Neel state may cause a large MOKE even in its fully compensated AF state without spin magnetization. This large MOKE further allows imaging of the magnetic octupole domains and their reversal induced by magnetic field. The observation of a large MOKE in an AF metal should open new avenues for the study of domain dynamics as well as spintronics using AFMs., Comment: 30 pages, 4 figures

Published

2018

31. Maximally-localized Wannier orbitals and the extended Hubbard model for the twisted bilayer graphene

Author

Koshino, Mikito, Yuan, Noah F. Q., Koretsune, Takashi, Ochi, Masayuki, Kuroki, Kazuhiko, and Fu, Liang

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We develop an effective extended Hubbard model to describe the low-energy electronic properties of the twisted bilayer graphene. By using the Bloch states in the effective continuum model and with the aid of the maximally localized algorithm, we construct the Wannier orbitals and obtain an effective tight-binding model on the emergent honeycomb lattice. We found the Wannier state takes a peculiar three-peak form in which the amplitude maxima are located at the triangle corners surrounding the center. We estimate the direct Coulomb interaction and the exchange interaction between the Wannier states. At the filling of two electrons per super cell, in particular, we find an unexpected coincidence in the direct Coulomb energy between a charge-ordered state and a homogeneous state, which would possibly lead to an unconventional many-body state., Comment: 12 pages, 7 figures

Published

2018

32. First-Principles Evaluation of the Dzyaloshinskii--Moriya Interaction

Author

Koretsune, Takashi, Kikuchi, Toru, and Arita, Ryotaro

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We review recent developments of formulations to calculate the Dzyaloshinskii--Moriya (DM) interaction from first principles. In particular, we focus on three approaches. The first one evaluates the energy change due to the spin twisting by directly calculating the helical spin structure. The second one employs the spin gauge field technique to perform the derivative expansion with respect to the magnetic moment. This gives a clear picture that the DM interaction can be represented as the spin current in the equilibrium within the first order of the spin-orbit couplings. The third one is the perturbation expansion with respect to the exchange couplings and can be understood as the extension of the Ruderman--Kittel--Kasuya--Yosida (RKKY) interaction to the noncentrosymmetric spin-orbit systems. By calculating the DM interaction for the typical chiral ferromagnets Mn$_{1-x}$Fe$_x$Ge and Fe$_{1-x}$Co$_x$Ge, we discuss how these approaches work in actual systems., Comment: invited review paper

Published

2018

33. Large anomalous Nernst effect at room temperature in a chiral antiferromagnet

Author

Ikhlas, Muhammad, Tomita, Takahiro, Koretsune, Takashi, Suzuki, Michi-To, Nishio-Hamane, Daisuke, Arita, Ryotaro, Otani, Yoshichika, and Nakatsuji, Satoru

Subjects

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

Abstract

Temperature gradient in a ferromagnetic conductor may generate a spontaneous transverse voltage drop in the direction perpendicular to both magnetization and heat current. This anomalous Nernst effect (ANE) has been considered to be proportional to the magnetization, and thus observed only in ferromagnets, while recent theories indicate that ANE provides a measure of the Berry curvature at the Fermi energy $E_{\rm F}$. Here we report the observation of a large ANE at zero field in the chiral antiferromagnet Mn$_3$Sn. Despite a very small magnetization $\sim 0.002$ $\mu_{\rm B}/$Mn, the transverse Seebeck coefficient at zero field is $\sim 0.35~\mu$V/K at room temperature and reaches $\sim 0.6~\mu$V/K at 200 K, comparable with the maximum value known for a ferromagnetic metal. Our first-principles calculation reveals that the large ANE comes from a significantly enhanced Berry curvature associated with the Weyl points nearby $E_{\rm F}$. The ANE is geometrically convenient for the thermoelectric power generation, as it enables a lateral configuration of the modules to efficiently cover the heat source. Our observation of the large ANE in an antiferromagnet paves a way to develop a new class of thermoelectric material using topological magnets to fabricate an efficient, densely integrated thermopile., Comment: 43 pages, 10 figures, 2 tables

Published

2017

34. Weak phonon-mediated pairing in BiS$_2$ superconductor from first principles

Author

Morice, Corentin, Akashi, Ryosuke, Koretsune, Takashi, Saxena, Siddharth S., and Arita, Ryotaro

Subjects

Condensed Matter - Superconductivity

Abstract

Superconductivity in novel bismuth-sulphur superconductors has attracted large research efforts, both experimental and theoretical, but a consensus on the nature of superconductivity in these materials has yet to be reached. Using density functional theory for superconductors, we study the electron-phonon pairing mechanism in LaO$_{0.5}$F$_{0.5}$BiS$_2$. We first confirm the presence of a commensurate charge density wave instability, in accordance with previous studies. Using a recently developed integration scheme for the electron-phonon coupling, we found that its strength is much lower than previously calculated, due to improved density of state calculations. We finally conclude that conventional phonon-mediated pairing cannot explain the high superconducting transition temperatures observed in this material.

Published

2017

35. Cluster multipole theory for anomalous Hall effect in antiferromagnets

Author

Suzuki, Michi-To, Koretsune, Takashi, Ochi, Masayuki, and Arita, Ryotaro

Subjects

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

Abstract

We introduce a cluster extension of multipole moments to discuss the anomalous Hall effect (AHE) in both ferromagnetic (FM) and antiferromagnetic (AFM) states in a unified framework. We first derive general symmetry requirements for the AHE in the presence or absence of the spin-orbit coupling, by considering the symmetry of the Berry curvature in k space. The cluster multipole (CMP) moments are then defined to quantify the macroscopic magnetization in non-collinear AFM states, as a natural generalization of the magnetization in FM states. We identify the macroscopic CMP order which induces the AHE. The theoretical framework is applied to the non-collinear AFM states of Mn3Ir, for which an AHE was predicted in a first-principles calculation, and Mn3Z (Z=Sn, Ge), for which a large AHE was recently discovered experimentally. We further compare the AHE in Mn3Z and bcc Fe in terms of the CMP. We show that the AHE in Mn3Z is characterized with the magnetization of a cluster octupole moment in the same manner as that in bcc Fe characterized with the magnetization of the dipole moment., Comment: 12 pages, 11 figures

Published

2016

36. Efficient method to calculate the electron-phonon coupling constant and superconducting transition temperature

Author

Koretsune, Takashi and Arita, Ryotaro

Subjects

Condensed Matter - Superconductivity

Abstract

We show an efficient way to compute the electron-phonon coupling constant, $\lambda$, and the superconducting transition temperature, Tc from first-principles calculations. This approach gives rapid convergence of Tc with respect to the size of the k-point mesh, and is seamlessly connected to the formulation used in large molecular systems such as alkali fullerides where momentum dependence can be neglected. Since the phonon and electron-phonon calculations are time consuming particularly in complicated systems, the present approach will strongly reduce the computational cost, which facilitates high-throughput superconducting material design.

Published

2016

37. Gate-Tuned Thermoelectric Power in Black Phosphorus

Author

Saito, Yu, Iizuka, Takahiko, Koretsune, Takashi, Shimizu, Ryotaro Arita Sunao, and Iwasa, Yoshihiro

Subjects

Condensed Matter - Materials Science

Abstract

The electric field effect is a useful means of elucidating intrinsic material properties as well as for designing functional devices. The electric-double-layer transistor (EDLT) enables the control of carrier density in a wide range, which is recently proved to be an effective tool for the investigation of thermoelectric properties. Here, we report the gate-tuning of thermoelectric power in a black phosphorus (BP) single crystal flake with the thickness of 40 nm. Using an EDLT configuration, we successfully control the thermoelectric power (S), and find that the S of ion-gated BP reached +510 $\mu$V/K at 210 K in the hole depleted state, which is much higher than the reported bulk single crystal value of +340 $\mu$V/K at 300 K. We compared this experimental data with the first-principles-based calculation and found that this enhancement is qualitatively explained by the effective thinning of the conduction channel of the BP flake and non-uniformity of the channel owing to the gate operation in a depletion mode. Our results provide new opportunities for further engineering BP as a thermoelectric material in nanoscale., Comment: 17 pages, 4 figures

Published

2016

38. Doppler shift picture of the Dzyaloshinskii--Moriya interaction

Author

Kikuchi, Toru, Koretsune, Takashi, Arita, Ryotaro, and Tatara, Gen

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We present a physical picture for the emergence of the Dzyaloshinskii--Moriya (DM) interaction based on the idea of the Doppler shift by an intrinsic spin current induced by spin--orbit interaction under broken inversion symmetry. The picture is confirmed by a rigorous effective Hamiltonian theory, which reveals that the DM coefficient is given by the magnitude of the intrinsic spin current. The expression is directly applicable to first principles calculations and clarifies the relation between the interaction and the electronic band structures. Quantitative agreement with experimental results is obtained for the skyrmion compounds Mn$_{1-x}$Fe$_x$Ge and Fe$_{1-x}$Co$_x$Ge., Comment: 5 pages, 4 figures; v2 references added

Published

2016

39. Effect of van Hove singularities on high-Tc superconductivity in H3S

Author

Sano, Wataru, Koretsune, Takashi, Tadano, Terumasa, Akashi, Ryosuke, and Arita, Ryotaro

Subjects

Condensed Matter - Superconductivity

Abstract

One of interesting open questions for the high transition temperature (Tc) superconductivity in sulfur hydrides is why high pressure phases of H3S have extremely high Tc's. Recently, it has been pointed out that the presence of the van Hove singularities (vHs) around the Fermi level is crucial. However, while there have been quantitative estimates of Tc based on the Migdal-Eliashberg theory, the energy dependence of the density of states (DOS) has been neglected to simplify the Eliashberg equation. In this study, we go beyond the constant DOS approximation and explicitly consider the electronic structure over 40eV around the Fermi level. In contrast with the previous conventional calculations, this approach with a sufficiently large number of Matsubara frequencies enables us to calculate Tc without introducing the empirical pseudo Coulomb potential. We show that while H3S has much higher Tc than H2S for which the vHs is absent, the constant DOS approximation employed so far seriously overestimates (underestimates) Tc by ~ 60K (~ 10K) for H3S (H2S). We then discuss the impact of the strong electron-phonon coupling on the electronic structure with and without the vHs and how it affects the superconductivity. Especially, we focus on (1) the feedback effect in the self-consistent calculation of the self-energy, (2) the effect of the energy shift due to the zero-point motion, and (3) the effect of the changes in the phonon frequencies due to strong anharmonicity. We show that the effect of (1)-(3) on Tc is about 10-30K for both H3S and H2S. Eventually, Tc is estimated to be 181K for H3S at 250GPa and 34K for H2S at 140GPa, which explains the pressure dependence of Tc observed in the experiment. In addition, we evaluate the lowest order vertex correction beyond the Migdal-Eliashberg theory and discuss the validity of the Migdal approximation for sulfur hydrides.

Published

2015

40. In-plane electric polarization of bilayer graphene nanoribbons by interlayer bias voltage

Author

Okugawa, Ryo, Tanaka, Junya, Koretsune, Takashi, Saito, Susumu, and Murakami, Shuichi

Subjects

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

Abstract

We theoretically show that an interlayer bias voltage in the AB-stacked bilayer graphene nanoribbons with armchair edges induces an electric polarization along the ribbon. Both tight-binding and ab initio calculations consistently indicate that when the bias voltage is weak, the polarization shows opposite signs depending on the ribbon width modulo three. This nontrivial dependence is explained using a two-band effective model. A strong limit of the bias voltage in the tight-binding model shows either one-third or zero polarization, which agrees with topological argument., Comment: 11 pages, 9 figures, accepted by PRL

Published

2015

41. Control of Dzyaloshinskii-Moriya interaction in Mn$_{1-x}$Fe$_x$Ge: a first-principles study

Author

Koretsune, Takashi, Nagaosa, Naoto, and Arita, Ryotaro

Subjects

Condensed Matter - Materials Science

Abstract

Motivated by the recent experiment on the size and helicity control of skyrmions in Mn$_{1-x}$Fe$_x$Ge [K. Shibata et al., Nature Nanotechnology 8, 732 (2013)], we study how the Dzyaloshinskii-Moriya (DM) interaction changes its size and sign in metallic helimagnets. By means of first-principles calculations, we successfully reproduce the non-trivial sign change of the DM interaction observed in the experiment. While the DM interaction sensitively depends on the carrier density or the detail of the electronic structure such as the size of the exchange splitting, its behavior can be systematically understood in terms of the distribution of anticrossing points in the band structure. By following this guiding principle, we can even induce gigantic anisotropy in the DM interaction by applying a strain to the system. These results pave the new way for skyrmion crystal engineering in metallic helimagnets., Comment: 7 pages, 8 figures, 1 table

Published

2015

42. Superconductivity in CaH6 and ThH10 investigated by fully ab initio Eliashberg method and self-consistent Green's function

Author

Darussalam, Alwan Abdillah, primary and Koretsune, Takashi, additional

Published

2024

43. High-throughput calculations of antiferromagnets hosting anomalous transport phenomena

Author

Nomoto, Takuya, primary, Minami, Susumu, additional, Yanagi, Yuki, additional, Suzuki, Michi-To, additional, Koretsune, Takashi, additional, and Arita, Ryotaro, additional

Published

2024

44. Iron-based binary ferromagnets for transverse thermoelectric conversion

Author

Sakai, Akito, Minami, Susumu, Koretsune, Takashi, Chen, Taishi, Higo, Tomoya, Wang, Yangming, and Nomoto, Takuya

Subjects

Thermoelectric generators -- Materials -- Magnetic properties -- Usage, Ferromagnetic materials -- Usage -- Magnetic properties, Iron -- Usage -- Magnetic properties, Environmental issues, Science and technology, Zoology and wildlife conservation

Abstract

Thermoelectric generation using the anomalous Nernst effect (ANE) has great potential for application in energy harvesting technology because the transverse geometry of the Nernst effect should enable efficient, large-area and flexible coverage of a heat source. For such applications to be viable, substantial improvements will be necessary not only for their performance but also for the associated material costs, safety and stability. In terms of the electronic structure, the anomalous Nernst effect (ANE) originates from the Berry curvature of the conduction electrons near the Fermi energy.sup.1,2. To design a large Berry curvature, several approaches have been considered using nodal points and lines in momentum space.sup.3-10. Here we perform a high-throughput computational search and find that 25 percent doping of aluminium and gallium in alpha iron, a naturally abundant and low-cost element, dramatically enhances the ANE by a factor of more than ten, reaching about 4 and 6 microvolts per kelvin at room temperature, respectively, close to the highest value reported so far. The comparison between experiment and theory indicates that the Fermi energy tuning to the nodal web--a flat band structure made of interconnected nodal lines--is the key for the strong enhancement in the transverse thermoelectric coefficient, reaching a value of about 5 amperes per kelvin per metre with a logarithmic temperature dependence. We have also succeeded in fabricating thin films that exhibit a large ANE at zero field, which could be suitable for designing low-cost, flexible microelectronic thermoelectric generators.sup.11-13. Aluminium- and gallium-doped iron compounds show a large anomalous Nernst effect owing to a topological electronic structure, and their films are potentially suitable for designing low-cost, flexible microelectronic thermoelectric generators., Author(s): Akito Sakai [sup.1] [sup.2] [sup.3] , Susumu Minami [sup.4] [sup.5] , Takashi Koretsune [sup.6] , Taishi Chen [sup.1] [sup.3] , Tomoya Higo [sup.1] [sup.3] , Yangming Wang [sup.1] , [...]

Published

2020

45. Quantum crystal structure in the 250-kelvin superconducting lanthanum hydride

Author

Errea, Ion, Belli, Francesco, Monacelli, Lorenzo, Sanna, Antonio, Koretsune, Takashi, Tadano, Terumasa, Bianco, Raffaello, Calandra, Matteo, Arita, Ryotaro, Mauri, Francesco, and Flores-Livas, José A.

Published

2020

46. X-ray study of ferroic octupole order producing anomalous Hall effect

Author

Kimata, Motoi, Sasabe, Norimasa, Kurita, Kensuke, Yamasaki, Yuichi, Tabata, Chihiro, Yokoyama, Yuichi, Kotani, Yoshinori, Ikhlas, Muhammad, Tomita, Takahiro, Amemiya, Kenta, Nojiri, Hiroyuki, Nakatsuji, Satoru, Koretsune, Takashi, Nakao, Hironori, Arima, Taka-hisa, and Nakamura, Tetsuya

Published

2021

47. Anomalous transport due to Weyl fermions in the chiral antiferromagnets Mn3X, X = Sn, Ge

Author

Chen, Taishi, Tomita, Takahiro, Minami, Susumu, Fu, Mingxuan, Koretsune, Takashi, Kitatani, Motoharu, Muhammad, Ikhlas, Nishio-Hamane, Daisuke, Ishii, Rieko, Ishii, Fumiyuki, Arita, Ryotaro, and Nakatsuji, Satoru

Published

2021

48. Magneto-orbital effect without spin-orbit interactions --- noncentrosymmetric zeolite-templated carbon structure

Author

Koretsune, Takashi, Arita, Ryotaro, and Aoki, Hideo

Subjects

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

Abstract

A peculiar manifestation of orbital angular momentum is proposed for a zeolite-templated carbon system, C36H9. The structure, being a network of nanoflakes in the shape of a "pinwheel", lacks inversion symmetry. While the unit cell is large, the electronic structure obtained with a first-principles density functional theory and captured as an effective tight-binding model in terms of maximally-localized Wannier functions, exhibits an unusual feature that the valence band top comes from two chiral states having orbital magnetic momenta of $\pm 1$. The noncentrosymmetric lattice structure then makes the band dispersion asymmetric, as reminiscent of, but totally different from, spin-orbit systems. The unusual feature is predicted to imply a current-induced orbital magnetism when holes are doped., Comment: 5 pages, 6 figures

Published

2012

49. Synthesis of Ultrahigh-Purity (6,5) Carbon Nanotubes Using a Trimetallic Catalyst

Author

Shiina, Satoru, Murohashi, Tennpei, Ishibashi, Koyo, He, Xing, Koretsune, Takashi, Liu, Zheng, Terashima, Wataru, Kato, Yuichiro K., Inoue, Kazutoshi, Saito, Mitsuhiro, Ikuhara, Yuichi, and Kato, Toshiaki

Abstract

Chirality-controlled synthesis of carbon nanotubes (CNTs) is one of the ultimate goals in the field of nanotube synthesis. At present, direct synthesis achieving a purity of over 90%, which can be called single-chirality synthesis, has been achieved for only two types of chiralities: (14,4) and (12,6) CNTs. Here, we realized an ultrahigh-purity (∼95.8%) synthesis of (6,5) CNTs with a trimetallic catalyst NiSnFe. Partial formation of Ni3Sn crystals was found within the NiSnFe nanoparticles. The activation energy for the selective growth of (6,5) CNTs decreased owing to the formation of Ni3Sn crystals, resulting in the high-purity synthesis of (6,5) CNTs. Transmission electron microscopy (TEM) reveals that one-dimensional (1D) crystals of periodic strip lines with 8.8 Å spacing are formed within the as-grown ultrahigh-purity (6,5) CNTs, which are well-matched with the simulated TEM image of closely packed 37 (6,5) CNTs with 2.8 Å intertube distance, indicating the direct formation of chirality-pure (6,5)-CNT bundle structures. The photoluminescence (PL) lifetime increases more than 20 times by the formation of chirality-pure bundle structures of (6,5) CNTs compared to that of isolated (6,5) CNTs. This can be explained by exciton delocalization or intertube excitons within bundle structures of chirality-pure (6,5) CNTs.

Published

2024

50. Ab initio Derivation of Low-Energy Model for Alkali-Cluster-Loaded Sodalites

Author

Nakamura, Kazuma, Koretsune, Takashi, and Arita, Ryotaro

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

An effective low-energy model describing magnetic properties of alkali-cluster-loaded sodalites is derived by {\em ab initio} downfolding. We start with constructing an extended Hubbard model for maximally localized Wannier functions. {\em Ab initio} screened Coulomb and exchange interactions are calculated by constrained random phase approximation. We find that the system resides in the strong coupling regime and thus the Heisenberg model is derived as a low-energy model of the extended Hubbard model. We obtain antiferromagnetic couplings $\sim$ $O$(10 K), being consistent with the experimental temperature dependence of the spin susceptibility. Importance of considering the screening effect in the derivation of the extended Hubbard model is discussed., Comment: 9 pages, 5 figures, 2 tables

Published

2009