APS March Meeting 2024
Monday–Friday, March 4–8, 2024;
Minneapolis & Virtual
Session A07: General Properties of Non-Fermi Liquids
8:00 AM–11:00 AM,
Monday, March 4, 2024
Room: L100H
Sponsoring
Unit:
DCMP
Chair: Juan Mendoza-Arenas, University of Pittsburgh
Abstract: A07.00006 : The orbital magnetic field effect on the electronic density of states of a U(1) quantum spin liquid with spinon Fermi surface*
9:00 AM–9:12 AM
Abstract
Presenter:
Wenyu He
(ShanghaiTech University)
Authors:
Wenyu He
(ShanghaiTech University)
Patrick A Lee
(Massachusetts Institute of Technology)
A quantum spin liquid with a spinon Fermi surface is an exotic insulator that hosts neutral Fermi surfaces inside the insulating gap. In an external magnetic field, it has been pointed out that the neutral Fermi surfaces are Landau quantized to form Landau levels due to the coupling to the induced emergent gauge magnetic field. In this talk, I will present that how the orbital magnetic field affects the electronic density of states of a quantum spin liquid with spinon Fermi surface. We find that the Landau levels from the neutral Fermi surfaces give rise to a set of steps emerging at the upper and lower Hubbard band edges. Each of the Hubbard band edge steps further develop into a band edge resonance peak when a weak gauge binding arising from the gauge field fluctuations is taken into account. Importantly, each Hubbard band edge step and its resulting resonance peak in the weak gauge binding are found to have a corresponding Landau level from the neutral Fermi surfaces, so the Hubbard band edge steps and the band edge resonance peaks provide signatures to the unique feature that characterizes the Landau quantization of the in-gap neutral Fermi surfaces in the spin liquid. We further consider the strong gauge-binding regime where the band edge resonance peaks move into the Mott gap and develop into true in-gap bound states. In the strong gauge binding regime, we solve the Landau-level spectrum of the in-gap bound states in an orbital magnetic field. For the in-gap bound state with a Mexican-hat-like band dispersion, we find that the envelop energy to have a state excited from the bound state Landau levels decreases quadratically with the magnetic field. The quadratic decrease behavior of the envelop energy is consistent with the intuition that applying magnetic field localizes the states and energetically promotes the in-gap bound states formation. Finally, we discuss the connection of our results to the electronic density of states spectra measured in the layered 1T-TaS2. We point out that a quantum spin liquid with a quasibound state in the upper Hubbard band can give the density of states spectra similar to the one measured in the experiment.
*W.-Y. He acknowledges the start-up grant of ShanghaiTech University. P.A.L. acknowledges support by DOE office of Basic Sciences Grant No. DE-FG02-03ER46076.