@article{82842520480042b3a1b63fd5b49cf647,
title = "Mapping the twist-angle disorder and Landau levels in magic-angle graphene",
abstract = "The recently discovered flat electronic bands and strongly correlated and superconducting phases in magic-angle twisted bilayer graphene (MATBG)(1,2) crucially depend on the interlayer twist angle, theta. Although control of the global theta with a precision of about 0.1 degrees has been demonstrated(1-7), little information is available on the distribution of the local twist angles. Here we use a nanoscale on-tip scanning superconducting quantum interference device (SQUID-on-tip)(8) to obtain tomographic images of the Landau levels in the quantum Hall state(9) and to map the local theta variations in hexagonal boron nitride (hBN)-encapsulated MATBG devices with relative precision better than 0.002 degrees and a spatial resolution of a few moire periods. We find a correlation between the degree of theta disorder and the quality of the MATBG transport characteristics and show that even state-of-the-art devices-which exhibit correlated states, Landau fans and superconductivity-display considerable local variation in theta of up to 0.1 degrees, exhibiting substantial gradients and networks of jumps, and may contain areas with no local MATBG behaviour. We observe that the correlated states in MATBG are particularly fragile with respect to the twist-angle disorder. We also show that the gradients of theta generate large gate-tunable in-plane electric fields, unscreened even in the metallic regions, which profoundly alter the quantum Hall state by forming edge channels in the bulk of the sample and may affect the phase diagram of the correlated and superconducting states. We thus establish the importance of theta disorder as an unconventional type of disorder enabling the use of twist-angle gradients for bandstructure engineering, for realization of correlated phenomena and for gate-tunable built-in planar electric fields for device applications.",
author = "A. Uri and S. Grover and Y. Cao and Crosse, {J. A.} and K. Bagani and D. Rodan-Legrain and Y. Myasoedov and K. Watanabe and T. Taniguchi and P. Moon and M. Koshino and P. Jarillo-Herrero and E. Zeldov",
note = "We thank A. Stern and E. Berg for valuable discussions and M. F. da Silva for constructing the COMSOL simulations. This work was supported by the Sagol WIS–MIT Bridge Program, by the European Research Council (ERC) under the European Union{\textquoteright}s Horizon 2020 research and innovation programme (grant no. 785971), by the Israel Science Foundation (ISF, grant no. 994/19), by the Minerva Foundation with funding from the Federal German Ministry of Education and Research, and by the Leona M. and Harry B. Helmsley Charitable Trust grant no. 2018PG-ISL006. Y.C., P.J.-H. and E.Z. acknowledge the support of the MISTI (MIT International Science and Technology Initiatives) MIT–Israel Seed Fund. Work at MIT was supported by the National Science Foundation (NSF, grant no. DMR-1809802), the Center for Integrated Quantum Materials under NSF grant no. DMR-1231319 and the Gordon and Betty Moore Foundation{\textquoteright}s EPiQS Initiative through grant no. GBMF4541 to P.J.-H. for device fabrication, transport measurements and data analysis. This work was performed in part at the Harvard University Center for Nanoscale Systems (CNS), a member of the National Nanotechnology Coordinated Infrastructure Network (NNCI), which is supported by the National Science Foundation under NSF ECCS award no. 1541959. D.R.-L acknowledges partial support from Fundaci{\`o} Bancaria {\textquoteleft}la Caixa{\textquoteright} (LCF/BQ/AN15/10380011) and from the US Army Research Office grant no. W911NF-17-S-0001. M.K. acknowledges the financial support of JSPS KAKENHI grant no. JP17K05496. J.A.C. and P.M. were supported by the Science and Technology Commission of Shanghai Municipality grant no. 19ZR1436400, the NYU–ECNU Institute of Physics at NYU Shanghai and New York University Global Seed Grants for Collaborative Research. J.A.C. acknowledges support from the National Science Foundation of China grant no. 11750110420. This research was carried out on the High Performance Computing resources at NYU Shanghai. K.W. and T.T. acknowledge support from the Elemental Strategy Initiative conducted by the MEXT, Japan, A3 Foresight by JSPS and the CREST (JPMJCR15F3), JST. Contributions - A.U., S.G. and E.Z. designed the experiment. A.U., S.G. and Y.C. performed the measurements. A.U. and S.G. performed the analysis. Y.C., D.R.-L. and P.J.-H. designed and provided the samples and contributed to the analyses of the results. K.B. fabricated the SOTs. Y.M. fabricated the tuning forks. J.A.C. performed the tight-binding calculations with P.M. and M.K., and K.W. and T.T. fabricated the hBN. A.U., S.G. and E.Z. wrote the manuscript. All authors participated in discussions and in writing of the manuscript.",
year = "2020",
month = may,
day = "6",
doi = "https://doi.org/10.1038/s41586-020-2255-3",
language = "الإنجليزيّة",
volume = "581",
pages = "47--52",
journal = "Nature",
issn = "0028-0836",
publisher = "Nature Research",
number = "7806",
}