Papers
Topics
Authors
Recent
Search
2000 character limit reached

An experimental scheme for determining the Berry phase in two-dimensional quantum materials with a flat band

Published 23 Feb 2024 in cond-mat.mes-hall and cond-mat.mtrl-sci | (2402.15596v2)

Abstract: Experimentally feasible methods to determine the Berry phase, a fundamental quantity characterizing a quantum material, are often needed in applications. We develop an approach to detecting the Berry phase by using a class of two-dimensional (2D) Dirac materials with a flat band, the $\alpha$-$\mathcal{T}_3$ lattices. The properties of this class of quantum materials are controlled by a single parameter $0 \le \alpha \le 1$, where the left and right endpoints correspond to graphene with pseudospin-1/2 and the dice lattice with pseudospin-1 Dirac-Weyl quasiparticles, respectively, and each specific value of $\alpha$ represents a material with a unique Berry phase. Applying a constant electric field to the $\alpha$-$\mathcal{T}_3$ lattice, we calculate the resulting electric current and find a one-to-one correspondence between the current and the Berry phase in both the linear and nonlinear response regimes. In the linear (Kubo) regime, the main physics is the Zitterbewegung effect. In the nonlinear regime, the Schwinger mechanism dominates. Beyond the nonlinear regime, Bloch-Zener oscillations can arise. Measuring the current thus provides an effective and experimentally feasible way to determine the Berry phase for this spectrum of 2D quantum materials.

Definition Search Book Streamline Icon: https://streamlinehq.com
References (26)
  1. S. Pancharatnam, Generalized theory of interference, and its applications. Part I. coherent pencils, Proc. Indian Acad. Sci. A. 44, 247 (1956).
  2. M. V. Berry, Quantal phase factors accompanying adiabatic changes, Proc. R. Soc. A 392, 45 (1984).
  3. D. Xiao, M.-C. Chang, and Q. Niu, Berry phase effects on electronic properties, Rev. Mod. Phys. 82, 1959 (2010).
  4. P. Carmier and D. Ullmo, Berry phase in graphene: Semiclassical perspective, Phys. Rev. B 77, 245413 (2008).
  5. E. Illes, J. P. Carbotte, and E. J. Nicol, Hall quantization and optical conductivity evolution with variable berry phase in the α−T3𝛼subscript𝑇3\alpha\text{$-$}{T}_{3}italic_α - italic_T start_POSTSUBSCRIPT 3 end_POSTSUBSCRIPT model, Phys. Rev. B 92, 245410 (2015).
  6. A. K. Geim and K. S. Novoselov, The rise of graphene, Nat. Mater. 6, 183 (2007).
  7. A. K. Geim and I. V. Grigorieva, Van der Waals heterostructures, Nature 499, 419 (2013).
  8. P. Ajayan, P. Kim, and K. Banerjee, Two-dimensional van der Waals materials, Phys. Today 69, 38 (2016).
  9. J. F. Rodriguez-Nieva and L. S. Levitov, Berry phase jumps and giant nonreciprocity in Dirac quantum dots, Phys. Rev. B 94, 235406 (2016).
  10. R. Sepkhanov, J. Nilsson, and C. Beenakker, Proposed method for detection of the pseudospin-1 2 Berry phase in a photonic crystal with a Dirac spectrum, Phys. Rev. B 78, 045122 (2008).
  11. C.-D. Han and Y.-C. Lai, Optical response of two-dimensional Dirac materials with a flat band, Phys. Rev. B 105, 155405 (2022).
  12. J. D. Malcolm and E. J. Nicol, Magneto-optics of massless Kane fermions: Role of the flat band and unusual Berry phase, Phys. Rev. B 92, 035118 (2015).
  13. F. Wang and Y. Ran, Nearly flat band with Chern number c= 2 on the dice lattice, Phys. Rev. B 84, 241103 (2011).
  14. B. Dóra and R. Moessner, Nonlinear electric transport in graphene: quantum quench dynamics and the Schwinger mechanism, Phys. Rev. B 81, 165431 (2010).
  15. J. Schwinger, On gauge invariance and vacuum polarization, Phys. Rev. 82, 664 (1951).
  16. L. Landau, On the theory of transfer of energy at collisions II, Phys. Z. Sowjetunion 2, 118 (1932).
  17. C. Zener, Non-adiabatic crossing of energy levels, Proc. R. Soc. Lon. A 137, 696 (1932).
  18. F. Bloch, Quantum mechanics of electrons in crystal lattices, Z. Phys 52, 555 (1928).
  19. C. Zener, A theory of the electrical breakdown of solid dielectrics, Proc. R. Soc. Lon. A 145, 523 (1934).
  20. L.-K. Lim, J.-N. Fuchs, and G. Montambaux, Bloch-Zener oscillations across a merging transition of Dirac points, Phys. Rev. Lett. 108, 175303 (2012).
  21. L.-L. Ye and Y.-C. Lai, Irregular Bloch-Zener oscillations in two-dimensional flat-band Dirac materials, Phys. Rev. B 107, 165422 (2023).
  22. J. Wang, J. F. Liu, and C. S. Ting, Recovered minimal conductivity in the α−T3𝛼subscript𝑇3\alpha\text{$-$}{T}_{3}italic_α - italic_T start_POSTSUBSCRIPT 3 end_POSTSUBSCRIPT model, Phys. Rev. B 101, 205420 (2020b).
  23. S. A. Sato and A. Rubio, Nonlinear electric conductivity and THz-induced charge transport in graphene, New J. Phys. 23, 063047 (2021).
  24. S. Vajna, B. Dóra, and R. Moessner, Nonequilibrium transport and statistics of Schwinger pair production in Weyl semimetals, Phys. Rev. B 92, 085122 (2015).
  25. Z. Okvátovity, L. Oroszlány, and B. Dóra, Time-dependent electric transport in nodal loop semimetals, Phys. Rev. B 104, 035130 (2021).
  26. N. Vitanov and B. Garraway, Landau-Zener model: Effects of finite coupling duration, Phys. Rev. A 53, 4288 (1996).
Citations (1)
View on Semantic Scholar

Summary

No one has generated a summary of this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Sign Up to Summarize

Paper to Video (Beta)

Whiteboard

No one has generated a whiteboard explanation for this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Sign Up to Generate

Open Problems

We haven't generated a list of open problems mentioned in this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Generate Now

Continue Learning

We haven't generated follow-up questions for this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Generate Now

Collections

Sign up for free to add this paper to one or more collections.

User Circle Single Streamline Icon: https://streamlinehq.com Sign Up

Tweets

Sign up for free to view the 2 tweets with 6 likes about this paper.

User Circle Single Streamline Icon: https://streamlinehq.com Sign Up for Free