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Shift photoconductivity in the Haldane model

Published 26 May 2023 in cond-mat.mes-hall | (2305.17035v2)

Abstract: The shift current is part of the second-order optical response of materials with a close connection to topology. Here we report a sign inversion in the band-edge shift photoconductivity of the Haldane model when the system undergoes a topological phase transition. This result is obtained following two complementary schemes. On one hand, we derive an analytical expression for the band-edge shift current in a two-band tight-binding model showing that the sign reversal is driven by the mass term. On the other hand, we perform a numerical evaluation on a continuum version of the Haldane model. This approach allows us to include off-diagonal matrix elements of the position operator, which are discarded in tight-binding models but can contribute significantly to the shift current. Explicit evaluation of the shift current shows that while the model predictions remain accurate in the deep tight-binding regime, significant deviations arise for shallow potential landscapes. Notably, the sign reversal across the topological phase transition is observed in all regimes, implying it is a robust effect that could be observable in a wide range of topological insulators.

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References (31)
  1. V. M. Fridkin, Bulk photovoltaic effect in noncentrosymmetric crystals, Crystallogr. Rep. 46, 654 (2001).
  2. B. I. Sturman and V. M. Fridkin, The photovoltaic and photorefractive effects in noncentrosymmetric materials (Gordon and Breach, Philadelphia, 1992).
  3. E. L. Ivchenko and G. E. Pikus, Superlattices and Other Heterostructures (Springer, Berlin, 1997) Chap. 10.5.
  4. W. Shockley and H. J. Queisser, Detailed balance limit of efficiency of p‐n junction solar cells, Journal of Applied Physics 32, 510 (1961), https://doi.org/10.1063/1.1736034 .
  5. R. von Baltz and W. Kraut, Theory of the bulk photovoltaic effect in pure crystals, Phys. Rev. B 23, 5590 (1981).
  6. H. Wang and X. Qian, Electrically and magnetically switchable nonlinear photocurrent in PT-symmetric magnetic topological quantum materials, npj Computational Materials 6, 199 (2020).
  7. S. Chaudhary, C. Lewandowski, and G. Refael, Shift-current response as a probe of quantum geometry and electron-electron interactions in twisted bilayer graphene, Phys. Rev. Res. 4, 013164 (2022a).
  8. A. M. Schankler, L. Gao, and A. M. Rappe, Large bulk piezophotovoltaic effect of monolayer 2H-MoS2, The Journal of Physical Chemistry Letters 12, 1244 (2021), pMID: 33497221, https://doi.org/10.1021/acs.jpclett.0c03503 .
  9. M. Cheng, Z.-Z. Zhu, and G.-Y. Guo, Strong bulk photovoltaic effect and second-harmonic generation in two-dimensional selenium and tellurium, Phys. Rev. B 103, 245415 (2021).
  10. S. Chaudhary, C. Lewandowski, and G. Refael, Shift-current response as a probe of quantum geometry and electron-electron interactions in twisted bilayer graphene, Phys. Rev. Res. 4, 013164 (2022b).
  11. L. Z. Tan and A. M. Rappe, Effect of wavefunction delocalization on shift current generation, Journal of Physics: Condensed Matter 31, 084002 (2019).
  12. D. Kaplan, T. Holder, and B. Yan, Nonvanishing subgap photocurrent as a probe of lifetime effects, Phys. Rev. Lett. 125, 227401 (2020).
  13. Y.-S. Huang, Y.-H. Chan, and G.-Y. Guo, Large shift currents via in-gap and charge-neutral excitons in a monolayer and nanotubes of bn, Phys. Rev. B 108, 075413 (2023).
  14. J. E. Sipe and A. I. Shkrebtii, Second-order optical response in semiconductors, Phys. Rev. B 61, 5337 (2000).
  15. N. Nagaosa and T. Morimoto, Concept of quantum geometry in optoelectronic processes in solids: Application to solar cells, Adv Mater 29 (2017).
  16. T. Morimoto and N. Nagaosa, Topological nature of nonlinear optical effects in solids, Science Advances 2, e1501524 (2016), https://www.science.org/doi/pdf/10.1126/sciadv.1501524 .
  17. L. Z. Tan and A. M. Rappe, Enhancement of the bulk photovoltaic effect in topological insulators, Physical review letters 116, 237402 (2016).
  18. F. D. M. Haldane, Model for a quantum Hall effect without Landau levels: Condensed-matter realization of the parity anomaly, Physical review letters 61, 2015 (1988).
  19. A. S. T. Pires, A Brief Introduction to Topology and Differential Geometry in Condensed Matter Physics (Morgan & Claypool Publishers, 2019).
  20. Z. Yan, Precise determination of critical points of topological phase transitions via shift current in two-dimensional inversion asymmetric insulators, arXiv:1812.02191 [cond-mat]  (2018).
  21. J. Ibañez-Azpiroz, S. S. Tsirkin, and I. Souza, Ab initio calculation of the shift photocurrent by Wannier interpolation, Phys. Rev. B 97, 245143 (2018).
  22. J. Bennetto and D. Vanderbilt, Semiconductor effective charges from tight-binding theory, Phys. Rev. B 53, 15417 (1996).
  23. B. A. Foreman, Consequences of local gauge symmetry in empirical tight-binding theory, Phys. Rev. B 66, 165212 (2002).
  24. T. G. Pedersen, K. Pedersen, and T. B. Kriestensen, Optical matrix elements in tight-binding calculations, Phys. Rev. B 63, 201101(R) (2001).
  25. T. Sandu, Optical matrix elements in tight-binding models with overlap, Phys. Rev. B 72, 125105 (2005).
  26. J. Ibañez-Azpiroz, F. de Juan, and I. Souza, Assessing the role of interatomic position matrix elements in tight-binding calculations of optical properties, SciPost Physics 12, 070 (2022).
  27. N. Marzari and D. Vanderbilt, Maximally localized generalized wannier functions for composite energy bands, Phys. Rev. B 56, 12847 (1997).
  28. I. Souza, N. Marzari, and D. Vanderbilt, Maximally localized Wannier functions for entangled energy bands, Phys. Rev. B 65, 035109 (2001).
  29. R.-A. Chang and C.-R. Chang, Chern insulator in a ferromagnetic two-dimensional electron system with Dresselhaus spin–orbit coupling, New Journal of Physics 21, 103019 (2019).
  30. C. L. Kane and E. J. Mele, Quantum Spin Hall Effect in Graphene, Phys. Rev. Lett. 95, 226801 (2005).
  31. D. Sticlet and F. Piéchon, Distant-neighbor hopping in graphene and Haldane models, Phys. Rev. B 87, 115402 (2013).
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