Your search keyword '"Ko EK"' showing total 3 results

1. Tuning orbital-selective phase transitions in a two-dimensional Hund's correlated system.

Author

Ko EK, Hahn S, Sohn C, Lee S, Lee SB, Sohn B, Kim JR, Son J, Song J, Kim Y, Kim D, Kim M, Kim CH, Kim C, and Noh TW

Subjects

Photoelectron Spectroscopy, Research Design, Sarcomeres

Abstract

Hund's rule coupling (J) has attracted much attention recently for its role in the description of the novel quantum phases of multi-orbital materials. Depending on the orbital occupancy, J can lead to various intriguing phases. However, experimental confirmation of the orbital occupancy dependency has been difficult as controlling the orbital degrees of freedom normally accompanies chemical inhomogeneities. Here, we demonstrate a method to investigate the role of orbital occupancy in J related phenomena without inducing inhomogeneities. By growing SrRuO 3 monolayers on various substrates with symmetry-preserving interlayers, we gradually tune the crystal field splitting and thus the orbital degeneracy of the Ru t 2g orbitals. It effectively varies the orbital occupancies of two-dimensional (2D) ruthenates. Via in-situ angle-resolved photoemission spectroscopy, we observe a progressive metal-insulator transition (MIT). It is found that the MIT occurs with orbital differentiation: concurrent opening of a band insulating gap in the d xy band and a Mott gap in the d xz/yz bands. Our study provides an effective experimental method for investigation of orbital-selective phenomena in multi-orbital materials., (© 2023. The Author(s).)

Published

2023

2. Higher harmonics in planar Hall effect induced by cluster magnetic multipoles.

Author

Song J, Oh T, Ko EK, Lee JH, Kim WJ, Zhu Y, Yang BJ, Li Y, and Noh TW

Abstract

Antiferromagnetic (AFM) materials are attracting tremendous attention due to their spintronic applications and associated novel topological phenomena. However, detecting and identifying the spin configurations in AFM materials are quite challenging due to the absence of net magnetization. Herein, we report the practicality of utilizing the planar Hall effect (PHE) to detect and distinguish "cluster magnetic multipoles" in AFM Nd 2 Ir 2 O 7 (NIO-227) fully strained films. By imposing compressive strain on the spin structure of NIO-227, we artificially induced cluster magnetic multipoles, namely dipoles and A 2 - and T 1 -octupoles. Importantly, under magnetic field rotation, each magnetic multipole exhibits distinctive harmonics of the PHE oscillation. Moreover, the planar Hall conductivity has a nonlinear magnetic field dependence, which can be attributed to the magnetic response of the cluster magnetic octupoles. Our work provides a strategy for identifying cluster magnetic multipoles in AFM systems and would promote octupole-based AFM spintronics., (© 2022. The Author(s).)

Published

2022

3. Colossal flexoresistance in dielectrics.

Author

Park SM, Wang B, Paudel T, Park SY, Das S, Kim JR, Ko EK, Lee HG, Park N, Tao L, Suh D, Tsymbal EY, Chen LQ, Noh TW, and Lee D

Abstract

Dielectrics have long been considered as unsuitable for pure electrical switches; under weak electric fields, they show extremely low conductivity, whereas under strong fields, they suffer from irreversible damage. Here, we show that flexoelectricity enables damage-free exposure of dielectrics to strong electric fields, leading to reversible switching between electrical states-insulating and conducting. Applying strain gradients with an atomic force microscope tip polarizes an ultrathin film of an archetypal dielectric SrTiO 3 via flexoelectricity, which in turn generates non-destructive, strong electrostatic fields. When the applied strain gradient exceeds a certain value, SrTiO 3 suddenly becomes highly conductive, yielding at least around a 10 8 -fold decrease in room-temperature resistivity. We explain this phenomenon, which we call the colossal flexoresistance, based on the abrupt increase in the tunneling conductance of ultrathin SrTiO 3 under strain gradients. Our work extends the scope of electrical control in solids, and inspires further exploration of dielectric responses to strong electromechanical fields.

Published

2020