Your search keyword '"Ewings RA"' showing total 6 results

1. Complete field-induced spectral response of the spin-1/2 triangular-lattice antiferromagnet CsYbSe2.

Author

Xie, Tao, Eberharter, A. A., Xing, Jie, Nishimoto, S., Brando, M., Khanenko, P., Sichelschmidt, J., Turrini, A. A., Mazzone, D. G., Naumov, P. G., Sanjeewa, L. D., Harrison, N., Sefat, Athena S., Normand, B., Läuchli, A. M., Podlesnyak, A., and Nikitin, S. E.

Subjects

SPECTRAL sensitivity, QUANTUM entanglement, SPIN excitations, EXCITATION spectrum, NEUTRON scattering

Abstract

Fifty years after Anderson's resonating valence-bond proposal, the spin-1/2 triangular-lattice Heisenberg antiferromagnet (TLHAF) remains the ultimate platform to explore highly entangled quantum spin states in proximity to magnetic order. Yb-based delafossites are ideal candidate TLHAF materials, which allow experimental access to the full range of applied in-plane magnetic fields. We perform a systematic neutron scattering study of CsYbSe2, first proving the Heisenberg character of the interactions and quantifying the second-neighbor coupling. We then measure the complex evolution of the excitation spectrum, finding extensive continuum features near the 120°-ordered state, throughout the 1/3-magnetization plateau and beyond this up to saturation. We perform cylinder matrix-product-state (MPS) calculations to obtain an unbiased numerical benchmark for the TLHAF and spectacular agreement with the experimental spectra. The measured and calculated longitudinal spectral functions reflect the role of multi-magnon bound and scattering states. These results provide valuable insight into unconventional field-induced spin excitations in frustrated quantum materials. [ABSTRACT FROM AUTHOR]

Published

2023

2. Complete field-induced spectral response of the spin-1/2 triangular-lattice antiferromagnet CsYbSe2.

Author

Xie, Tao, Eberharter, A. A., Xing, Jie, Nishimoto, S., Brando, M., Khanenko, P., Sichelschmidt, J., Turrini, A. A., Mazzone, D. G., Naumov, P. G., Sanjeewa, L. D., Harrison, N., Sefat, Athena S., Normand, B., Läuchli, A. M., Podlesnyak, A., and Nikitin, S. E.

Subjects

SPECTRAL sensitivity, QUANTUM entanglement, SPIN excitations, EXCITATION spectrum, NEUTRON scattering

Abstract

Fifty years after Anderson's resonating valence-bond proposal, the spin-1/2 triangular-lattice Heisenberg antiferromagnet (TLHAF) remains the ultimate platform to explore highly entangled quantum spin states in proximity to magnetic order. Yb-based delafossites are ideal candidate TLHAF materials, which allow experimental access to the full range of applied in-plane magnetic fields. We perform a systematic neutron scattering study of CsYbSe2, first proving the Heisenberg character of the interactions and quantifying the second-neighbor coupling. We then measure the complex evolution of the excitation spectrum, finding extensive continuum features near the 120°-ordered state, throughout the 1/3-magnetization plateau and beyond this up to saturation. We perform cylinder matrix-product-state (MPS) calculations to obtain an unbiased numerical benchmark for the TLHAF and spectacular agreement with the experimental spectra. The measured and calculated longitudinal spectral functions reflect the role of multi-magnon bound and scattering states. These results provide valuable insight into unconventional field-induced spin excitations in frustrated quantum materials. [ABSTRACT FROM AUTHOR]

Published

2023

3. Imaging the formation and surface phase separation of the CE phase.

Author

Zhou, Haibiao, Feng, Qiyuan, Hou, Yubin, Nakamura, Masao, Tokura, Yoshinori, Kawasaki, Masashi, Sheng, Zhigao, and Lu, Qingyou

Subjects

SURFACE phase transformations, ELECTRON configuration, PHASE transitions, MAGNETISM, MAGNETIC force microscopy

Abstract

The CE phase is an extraordinary phase exhibiting the simultaneous spin, charge, and orbital ordering due to strong electron correlation. It is an ideal platform to investigate the role of the multiple orderings in the phase transitions and discover emergent properties. Here, we use a cryogenic high-field magnetic force microscope to image the phase transitions and properties of the CE phase in a Pr0.5Ca0.5MnO3 thin film. In a high magnetic field, we observed a clear suppression of magnetic susceptibility at the charge-ordering insulator transition temperature (TCOI), whereas, at the Néel temperature (TN), no significant change is observed. This observation favors the scenario of strong antiferromagnetic correlation developed below TCOI but raises questions about the Zener polaron paramagnetic phase picture. Besides, we discoverd a phase-separated surface state in the CE phase regime. Ferromagnetic phase domains residing at the surface already exist in zero magnetic field and show ultra-high magnetic anisotropy. Our results provide microscopic insights into the unconventional spin- and charge-ordering transitions and revealed essential attributes of the CE phase, highlighting unusual behaviors when multiple electronic orderings are involved. [ABSTRACT FROM AUTHOR]

Published

2021

4. Singular magnetic anisotropy in the nematic phase of FeSe.

Author

Zhou, Rui, Scherer, Daniel D., Mayaffre, Hadrien, Toulemonde, Pierre, Ma, Mingwei, Li, Yuan, Andersen, Brian M., and Julien, Marc-Henri

Subjects

MAGNETIC anisotropy, SUPERCONDUCTORS, NUCLEAR magnetic resonance, NEUTRON scattering, QUASIPARTICLES

Abstract

FeSe is arguably the simplest, yet the most enigmatic, iron-based superconductor. Its nematic but non-magnetic ground state is unprecedented in this class of materials and stands out as a current puzzle. Here, our nuclear magnetic resonance measurements in the nematic state of mechanically detwinned FeSe reveal that both the Knight-shift and the spin–lattice relaxation rate 1/T1 possess an in-plane anisotropy opposite to that of the iron pnictides LaFeAsO and BaFe2As2. Using a microscopic electron model that includes spin–orbit coupling, our calculations show that an opposite quasiparticle weight ratio between the dxz and dyz orbitals leads to an opposite anisotropy of the orbital magnetic susceptibility, which explains our Knight-shift results. We attribute this property to a different nature of nematic order in the two compounds, predominantly bond type in FeSe and onsite ferro-orbital in pnictides. The T1 anisotropy is found to be inconsistent with existing neutron scattering data in FeSe, showing that the spin fluctuation spectrum reveals surprises at low energy, possibly from fluctuations that do not break C4 symmetry. Therefore, our results reveal that important information is hidden in these anisotropies and they place stringent constraints on the low-energy spin correlations as well as on the nature of nematicity in FeSe. [ABSTRACT FROM AUTHOR]

Published

2020

5. Magnetic excitations in non-collinear antiferromagnetic Weyl semimetal Mn3Sn.

Author

Park, Pyeongjae, Oh, Joosung, Uhlířová, Klára, Jackson, Jerome, Deák, András, Szunyogh, László, Lee, Ki Hoon, Cho, Hwanbeom, Kim, Ha-Leem, Walker, Helen C., Adroja, Devashibhai, Sechovský, Vladimír, and Park, Je-Geun

Subjects

MANGANESE compounds, SEMIMETALS, ANTIFERROMAGNETISM, TOPOLOGY, ELECTRONIC excitation, SPIN waves

Abstract

Mn3Sn has recently attracted considerable attention as a magnetic Weyl semimetal exhibiting concomitant transport anomalies at room temperature. The topology of the electronic bands, their relation to the magnetic ground state and their nonzero Berry curvature lie at the heart of the problem. The examination of the full magnetic Hamiltonian reveals otherwise hidden aspects of these unusual physical properties. Here, we report the full spin wave spectra of Mn3Sn measured over a wide momentum—energy range by the inelastic neutron scattering technique. Using a linear spin wave theory, we determine a suitable magnetic Hamiltonian which not only explains the experimental results but also stabilizes the low-temperature helical phase, consistent with our DFT calculations. The effect of this helical ordering on topological band structures is further examined using a tight binding method, which confirms the elimination of Weyl points in the helical phase. Our work provides a rare example of the intimate coupling between the electronic and spin degrees of freedom for a magnetic Weyl semimetal system. Weyl semimetals: magnetic excitations in Mn3Sn The interplay between the electronic and spin degrees of freedom determines the removal of Weyl points in magnetic semimetal systems. A team led by Je-Geun Park at the Institute for Basic Science and Seoul National University used linear spin wave theory to obtain the full spin wave spectra of antiferromagnetic A-type Mn3Sn across a broad energy-momentum range. The magnetic Hamiltonian obtained via a local moment model was capable of explaining the experimental inelastic neutron scattering data. Additional density functional theory calculations indicated that the Mn3Sn low-temperature magnetic structure involves a helical ordering that eliminates the Weyl points, and consequently reduces Mn3Sn experimental anomalous Hall conductivity. These results indicate how topological Weyl points can be removed by introducing a minor change to the magnetic ground state. [ABSTRACT FROM AUTHOR]

Published

2018

6. Nematic pairing from orbital-selective spin fluctuations in FeSe.

Author

Benfatto, Lara, Valenzuela, Belén, and Fanfarillo, Laura

Subjects

IRON selenides, NEMATIC liquid crystals, SPIN-orbit interactions, FLUCTUATIONS (Physics), IRON-based superconductors

Abstract

FeSe is an intriguing iron-based superconductor. It presents an unusual nematic state without magnetism and can be tuned to increase the critical superconducting temperature. Recently it has been observed a noteworthy anisotropy of the superconducting gaps. Its explanation is intimately related to the understanding of the nematic transition itself. Here, we show that the spin-nematic scenario driven by orbital-selective spin fluctuations provides a simple scheme to understand both phenomena. The pairing mediated by anisotropic spin modes is not only orbital selective but also nematic, leading to stronger pair scattering across the hole and X electron pocket. The delicate balance between orbital ordering and nematic pairing points also to a marked kz dependence of the hole–gap anisotropy. Fe-based superconductors | Understanding the pairing mechanism for FeSe: FeSe is a high-temperature superconductor displaying a complex interplay between structure, magnetism and superconductivity; new theoretical results might now shed light on its pairing mechanism. FeSe is widely studied because its superconducting critical temperature can be tuned over a wide range by chemical intercalation or pressure. Superconductivity appears in a phase that is called nematic, which breaks rotational symmetry but preserves translational symmetry. Experimental measurements show that the superconducting gaps are anisotropic: this is probably related to the nematic transition, in which spin fluctuations seem to play a part. Laura Fanfarillo from the University of Rome and colleagues present a model suggesting that orbital-selective spin fluctuations provide the pairing mechanism, which is at the same time orbital selective and nematic. This explains both the anisotropy of the gaps and its connection to the nematic transition. [ABSTRACT FROM AUTHOR]

Published

2018