Your search keyword '"Reddy, P. V. Sreenivasa"' showing total 3 results

1. Realization of a two-dimensional Weyl semimetal and topological Fermi strings.

Author

Lu Q, Reddy PVS, Jeon H, Mazza AR, Brahlek M, Wu W, Yang SA, Cook J, Conner C, Zhang X, Chakraborty A, Yao YT, Tien HJ, Tseng CH, Yang PY, Lien SW, Lin H, Chiang TC, Vignale G, Li AP, Chang TR, Moore RG, and Bian G

Abstract

A two-dimensional (2D) Weyl semimetal, akin to a spinful variant of graphene, represents a topological matter characterized by Weyl fermion-like quasiparticles in low dimensions. The spinful linear band structure in two dimensions gives rise to distinctive topological properties, accompanied by the emergence of Fermi string edge states. We report the experimental realization of a 2D Weyl semimetal, bismuthene monolayer grown on SnS(Se) substrates. Using spin and angle-resolved photoemission and scanning tunneling spectroscopies, we directly observe spin-polarized Weyl cones, Weyl nodes, and Fermi strings, providing consistent evidence of their inherent topological characteristics. Our work opens the door for the experimental study of Weyl fermions in low-dimensional materials., (© 2024. The Author(s).)

Published

2024

2. Realization of unpinned two-dimensional dirac states in antimony atomic layers.

Author

Lu Q, Cook J, Zhang X, Chen KY, Snyder M, Nguyen DT, Reddy PVS, Qin B, Zhan S, Zhao LD, Kowalczyk PJ, Brown SA, Chiang TC, Yang SA, Chang TR, and Bian G

Abstract

Two-dimensional (2D) Dirac states with linear dispersion have been observed in graphene and on the surface of topological insulators. 2D Dirac states discovered so far are exclusively pinned at high-symmetry points of the Brillouin zone, for example, surface Dirac states at [Formula: see text] in topological insulators Bi 2 Se(Te) 3 and Dirac cones at K and [Formula: see text] points in graphene. The low-energy dispersion of those Dirac states are isotropic due to the constraints of crystal symmetries. In this work, we report the observation of novel 2D Dirac states in antimony atomic layers with phosphorene structure. The Dirac states in the antimony films are located at generic momentum points. This unpinned nature enables versatile ways such as lattice strains to control the locations of the Dirac points in momentum space. In addition, dispersions around the unpinned Dirac points are highly anisotropic due to the reduced symmetry of generic momentum points. The exotic properties of unpinned Dirac states make antimony atomic layers a new type of 2D Dirac semimetals that are distinct from graphene., (© 2022. The Author(s).)

Published

2022

3. Topological charge-entropy scaling in kagome Chern magnet TbMn 6 Sn 6 .

Author

Xu X, Yin JX, Ma W, Tien HJ, Qiang XB, Reddy PVS, Zhou H, Shen J, Lu HZ, Chang TR, Qu Z, and Jia S

Abstract

In ordinary materials, electrons conduct both electricity and heat, where their charge-entropy relations observe the Mott formula and the Wiedemann-Franz law. In topological quantum materials, the transverse motion of relativistic electrons can be strongly affected by the quantum field arising around the topological fermions, where a simple model description of their charge-entropy relations remains elusive. Here we report the topological charge-entropy scaling in the kagome Chern magnet TbMn 6 Sn 6 , featuring pristine Mn kagome lattices with strong out-of-plane magnetization. Through both electric and thermoelectric transports, we observe quantum oscillations with a nontrivial Berry phase, a large Fermi velocity and two-dimensionality, supporting the existence of Dirac fermions in the magnetic kagome lattice. This quantum magnet further exhibits large anomalous Hall, anomalous Nernst, and anomalous thermal Hall effects, all of which persist to above room temperature. Remarkably, we show that the charge-entropy scaling relations of these anomalous transverse transports can be ubiquitously described by the Berry curvature field effects in a Chern-gapped Dirac model. Our work points to a model kagome Chern magnet for the proof-of-principle elaboration of the topological charge-entropy scaling., (© 2022. The Author(s).)

Published

2022