Anomalies in the Dirac bands in the proximity of correlated electrons
Journal article, 2024

Dirac fermions, particles with zero rest mass, are observed in topological materials and are believed to play a key role in the exotic phenomena in fundamental science and the advancement of quantum technology. Most of the topological systems studied so far are weakly correlated systems and the study of their properties in the presence of electron correlation is an interesting emerging area of research, where the electron correlation is expected to enhance the effective mass of the particles. Here, we studied the properties of Dirac bands in a non-symmorphic layered Kondo lattice system, CeAgSb2, employing high-resolution angle-resolved photoemission spectroscopy and first-principles calculations. In addition to the Dirac cones due to non-symmorphic symmetry, this material hosts Dirac fermions in the squarenet layer in the proximity of a strongly correlated Ce layer exhibiting Kondo behavior. Experimental results reveal crossings of the highly dispersive linear bands at the Brillouin zone boundary due to non-symmorphic symmetry. In addition, there are anisotropic Dirac cones constituted by the squarenet Sb 5p states forming a diamond-shaped nodal line. These Dirac bands are linear in a wide energy range with an unusually high slope. Interestingly, near the local Ce 4f bands, these bands exhibit a change in the slope akin to the formation of a ‘kink’ observed in other materials due to electron-phonon coupling. The emergence of such exotic properties in proximity to strongly correlated electronic states has significant implications in the study of complex quantum materials including unconventional superconductors.

Author

Sawani Datta

Tata Institute of Fundamental Research

Khadiza Ali

Chalmers, Microtechnology and Nanoscience (MC2), Quantum Device Physics

Rahul Verma

Tata Institute of Fundamental Research

Bahadur Singh

Tata Institute of Fundamental Research

Saroj Prasad Dash

Chalmers, Microtechnology and Nanoscience (MC2), Quantum Device Physics

A. Thamizhavel

Tata Institute of Fundamental Research

Kalobaran Maiti

Tata Institute of Fundamental Research

Nanoscale

2040-3364 (ISSN) 20403372 (eISSN)

Vol. 16 29 13861-13866

Subject Categories

Condensed Matter Physics

DOI

10.1039/d4nr01535e

More information

Latest update

8/10/2024