Mapping the twist angle and unconventional Landau levels in magic angle graphene
Aviram Uri, Sameer Grover, Yuan Cao, J. A. Crosse, Kousik Bagani,, Daniel Rodan-Legrain, Yuri Myasoedov, Kenji Watanabe, Takashi Taniguchi,, Pilkyung Moon, Mikito Koshino, Pablo Jarillo-Herrero, and Eli Zeldov

TL;DR
This study maps local twist angle variations in magic angle graphene devices with high precision, revealing significant inhomogeneity that impacts electronic properties and the quantum Hall effect, with implications for band structure engineering.
Contribution
It provides the first detailed spatial mapping of local twist angles in magic angle graphene, linking twist inhomogeneity to electronic behavior and device performance.
Findings
Local twist angles vary significantly within devices.
Twist angle gradients create large electric fields affecting quantum Hall states.
Inhomogeneity influences the phase diagram of correlated and superconducting states.
Abstract
The emergence of flat electronic bands and of the recently discovered strongly correlated and superconducting phases in twisted bilayer graphene crucially depends on the interlayer twist angle upon approaching the magic angle . Although advanced fabrication methods allow alignment of graphene layers with global twist angle control of about 0.1, little information is currently available on the distribution of the local twist angles in actual magic angle twisted bilayer graphene (MATBG) transport devices. Here we map the local variations in hBN encapsulated devices with relative precision better than 0.002 and spatial resolution of a few moir periods. Utilizing a scanning nanoSQUID-on-tip, we attain tomographic imaging of the Landau levels in the quantum Hall state in MATBG, which provides a highly sensitive probe of the charge disorder…
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