Evidence of striped electronic phases in a structurally modulated superlattice

This collection of articles and papers discusses various studies on the properties of two-dimensional (2D) materials, particularly those with incommensurate crystal phases, superlattices, and moiré structures. The research focuses on understanding the electronic, magnetic, and superconducting properties of these materials.

1. H. Z. Cummins’s study, published in 1990, explores the structural incommensurate crystal phases.

2. R. Bistritzer and A. H. MacDonald’s work, published in 2011, discusses moiré bands in twisted double-layer graphene.

3. Y. Cao et al.’s paper, published in 2018, presents correlated insulator behavior at half-filling in magic-angle graphene superlattices.

4. C. Hu et al.’s research, published in 2020, describes a van der Waals antiferromagnetic topological insulator with weak interlayer magnetic coupling.

5. A. Devarakonda et al.’s work, published in 2020, reports on clean 2D superconductivity in a bulk van der Waals superlattice.

6. The same authors’ subsequent paper, published in 2021, discusses signatures of bosonic Landau levels in a finite-momentum superconductor.

7. K. Ma et al.’s research, published in 2022, presents two-dimensional superconductivity in a bulk superlattice van der Waals material Ba6Nb11Se28.

8. E. Persky et al.’s paper, published in 2022, discusses magnetic memory and spontaneous vortices in a van der Waals superconductor.

9. R. R. Gerhardts, D. Weiss, and K. V. Klitzing’s study, published in 1989, investigates novel magnetoresistance oscillations in a periodically modulated two-dimensional electron gas.

10. K. Ensslin and P. M. Petroff’s work, published in 1990, discusses magnetotransport through an antidot lattice in GaAs-AlxGa1−xAs heterostructures.

11. R. Huber et al.’s paper, published in 2022, reports on band conductivity oscillations in a gate-tunable graphene superlattice.

12. K. Yang’s paper, published in 2013, discusses the detection of striped superconductors using magnetic field modulated Josephson effect.

13. K. Yang and D. F. Agterberg’s work, published in 2000, presents the Josephson effect in Fulde-Ferrell-Larkin-Ovchinnikov superconductors.

14. P. M. Lozano et al.’s research, published in 2022, tests for pair density wave order in La1.875Ba0.125CuO4.

15. Q. Li et al.’s paper, published in 2007, discusses two-dimensional superconducting fluctuations in stripe-ordered La1.875Ba0.125CuO4.

16. E. Berg et al.’s work, published in 2007, presents dynamical layer decoupling in a stripe-ordered high-Tc superconductor.

17. J. M. Tranquada’s review, published in 2020, discusses cuprate superconductors as viewed through a striped lens.

18. X. Liu et al.’s paper, published in 2021, discovers a Cooper-pair density wave state in a transition-metal dichalcogenide.

19. Gu et al.’s research, published in 2023, detects a pair density wave state in UTe2.

20. H. Zhao et al.’s paper, published in 2023, reports on smectic pair-density-wave order in EuRbFe4As4.

21. Liu et al.’s paper, published in 2023, presents pair density wave state in a monolayer high-Tc iron-based superconductor.

22. J. M. Tranquada et al.’s work, published in 1995, provides evidence for stripe correlations of spins and holes in copper oxide superconductors.

23. T. Valla et al.’s paper, published in 2006, discusses the ground state of the pseudogap in cuprate superconductors.

24. J. D. Axe et al.’s study, published in 1980, investigates incommensurate structures.

25. A. W. Overhauser’s paper, published in 1968, discusses exchange and correlation instabilities of simple metals.

26. Y. A. Izyumov’s work, published in 1984, explores modulated, or long-periodic, magnetic structures of crystals.

27. M. S. Dresselhaus’s book, published in 1986, discusses intercalation in layered materials.

28. P. Monceau’s review, published in 2012, provides an experimental overview of electronic crystals.

29. P. M. de Wolff, T. Janssen, and A. Janner’s paper, published in 1981, presents the superspace groups for incommensurate crystal structures with a one-dimensional modulation.

30. L. Esaki and R. Tsu’s work, published in 1970 and 1974, discuss superlattice and negative differential conductivity in semiconductors, respectively.

31. M. Serlin et al.’s paper, published in 2020, reports on the intrinsic quantized anomalous Hall effect in a moiré heterostructure.

32. T. Li et al.’s research, published in 2021, discusses quantum anomalous Hall effect from intertwined moiré bands.

33. T. Kawamoto and K. Takimiya’s paper, published in 2009, presents organic superconductors with an incommensurate anion structure.

34. S. Kuypers et al.’s work, published in 1989, studies the incommensurate misfit layer structure of (SnS)1.17NbS2, ‘SnNbS3’.

35. S. Xie et al.’s research, published in 2018, discusses coherent, atomically thin transition-metal dichalcogenide superlattices with engineered strain.

36. E. Fradkin, S. A. Kivelson, and E. Manousakis’s paper, published in 2000, presents the theory of the nematic phase of the two-dimensional electron gas in a magnetic field.

37. Y. Ando, K. Segawa, S. Komiya, and A. N. Lavrov’s work, published in 2002, discusses electrical resistivity anisotropy from self-organized one-dimensionality in high-temperature superconductors.

38. H. Sakabayashi and R. Okazaki’s paper, published in 2021, presents a crossover from itinerant to localized states in the thermoelectric oxide [Ca2CoO3]0.62[CoO2].

39. R. Jha et al.’s research, published in 2018, discusses anisotropy in the electronic transport properties of Weyl semimetal WTe2 single crystals.

40. D. Shoenberg’s book, published in 1984, discusses magnetic oscillations in metals.

41. S. Spurrier and N. R. Cooper’s paper, published in 2019, presents the theory of quantum oscillations in quasicrystals: quantizing spiral Fermi surfaces.

42. C. W. J. Beenakker’s paper, published in 1989, discusses the guiding-center-drift resonance in a periodically modulated two-dimensional electron gas.

43. R. W. Winkler, J. P. Kotthaus, and K. Ploog’s work, published in 1989, presents Landau band conductivity in a two-dimensional electron system modulated by an artificial one-dimensional superlattice potential.

44. A. L. Schawlow and G. E. Devlin’s paper, published in 1959, discusses the effect of the energy gap on the penetration depth of superconductors.

45. R. Giannetta, A. Carrington, and R. Prozorov’s paper, published in 2022, presents London penetration depth measurements using tunnel diode resonators.

46. R. A. Klemm, A. Luther, and M. R. Beasley’s work, published in 1975, discusses the theory of the upper critical field in layered superconductors.

47. F. R. Gamble et al.’s paper, published in 1971, discusses intercalation complexes of Lewis bases and layered sulfides: a large class of new superconductors.

48. C. C. Agosta’s paper, published in 2018, presents inhomogeneous superconductivity in organic and related superconductors.

49. E. Fradkin, S. A. Kivelson, and J. M. Tranquada’s review, published in 2015, discusses the theory of intertwined orders in high-temperature superconductors.

50. A. Meetsma, G. A. Wiegers, R. J. Haange, and J. L. de Boer’s paper, published in 1990, presents the structure of 2H-TaS2.

51. Y. Tokura and N. Nagaosa’s paper, published in 2018, discusses nonreciprocal responses from non-centrosymmetric quantum materials.

52. M. Smidman, M. B. Salamon, H. Q. Yuan, and D. F. Agterberg’s review, published in 2017, presents superconductivity and spin–orbit coupling in non-centrosymmetric materials.

53. W. Wochner, J. M. Tranquada, D. J. Buttrey, and V. Sachan’s paper, published in 1998, discusses stripe order in La2NiO4+δ with δ = 2/15.

54. E. A. Hewat et al.’s paper, published in 1988, presents the superstructure of the superconductor Bi2Sr2CaCu2O8 by high-resolution electron microscopy.

55. S. Parsons’s paper, published in 2003, provides an introduction to twinning.

56. Y. Zhang, N. F. Q. Yuan, and L. Fu’s paper, published in 2020, discusses moiré quantum chemistry: charge transfer in transition metal dichalcogenide superlattices.

57. N. N. T. Nam and M. Koshino’s work, published in 2017, presents lattice relaxation and energy band modulation in twisted bilayer graphene.

58. S. Turkel et al.’s paper, published in 2022, discusses orderly disorder in magic-angle twisted trilayer graphene.

59. J. A. Wilson, F. J. Di Salvo, and S. Mahajan’s paper, published in 1975, discusses charge-density waves and superlattices in the metallic layered transition metal dichalcogenides.

60. W. L. McMillan’s paper, published in 1975, presents the Landau theory of charge-density waves in transition-metal dichalcogenides.

61. G. Kresse and J. Furthmüller’s work, published in 1996, discusses the efficiency of ab-initio total energy calculations for metals and semiconductors using a plane-wave basis set.

62. G. Kresse and J. Furthmüller’s subsequent paper, published in 1996, presents efficient iterative schemes for ab initio total-energy calculations using a plane-wave basis set.

63. P. E. Blöchl’s paper, published in 1994, discusses the projector augmented-wave method.

64. J. P. Perdew, K. Burke, and M. Ernzerhof’s paper, published in 1996, presents the generalized gradient approximation made simple.

65. W. Ku, T. Berlijn, and C.-C. Lee’s paper, published in 2010, discusses unfolding first-principles band structures.

66. R. E. Thomson, B. Burk, A. Zettl, and J. Clarke’s paper, published in 1994, presents scanning tunneling microscopy of the charge-density-wave structure in 1T-TaS2.

67. L. Onsager’s paper, published in 1952, discusses the interpretation of the de Haas-van Alphen effect.

68. L. M. Falicov and P. R. Sievert’s paper, published in 1964, discusses magnetoresistance and magnetic breakdown.

69. E. M. Lifshitz, L. P. Pitaevskii, and L. D. Landau’s book, published in 1981, discusses physical kinetics.

70. F. M. Peeters and P. Vasilopoulos’s paper, published in 1992, presents electrical and thermal properties of a two-dimensional electron gas in a one-dimensional periodic potential.

71. O. E. Raichev’s paper, published in 2018, discusses the effect of Landau quantization on linear magnetoresistance of a periodically modulated two-dimensional electron gas.

72. P. H. Beton et al.’s paper, published in 1990, presents temperature dependence of magnetoresistance oscillations in a two-dimensional electron gas subjected to a periodic potential.

73. A. A. Bykov et al.’s work, published in 2019, discusses modulation of magneto-intersubband oscillations in a one-dimensional lateral superlattice.

74. R. I. Joseph’s paper, published in 1976, discusses demagnetizing factors in nonellipsoidal samples.

75. H. Nakajima, K. Nomura, and T. Sambongi’s paper, published in 1986, presents anisotropic superconducting transition in ZrTe3.

76. K. Yamaya, S. Takayanagi, and S. Tanda’s work, published in 2012, discusses mixed bulk-filament nature in superconductivity of the charge-density-wave conductor ZrTe3.

77. B. I. Halperin and D. R. Nelson’s paper, published in 1979, discusses resistive transition in superconducting films.

78. C. T. T. Van Degrift’s paper, published in 1975, presents a tunnel diode oscillator for 0.001 ppm measurements at low temperatures.

79. T. Coffey et al.’s paper, published in 2000, discusses measuring radio frequency properties of materials in pulsed magnetic fields with a tunnel diode oscillator.

80. M. Weger and I. B. Goldberg’s work, published in 1974, presents a review on the theory of superconductivity.

81. H. J. Monkhorst and J. D. Pack’s paper, published in 1976, presents special points for Brillouin-zone integrations.

82. Replication data for: Evidence of striped electronic phases in a structurally-modulated superlattice, published in 2024, provides data related to the study of striped electronic phases in a structurally-modulated superlattice.

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