MIT gets first 'direct view' of exotic superconductivity in graphene

MIT physicists have achieved a major breakthrough by obtaining the first direct measurement of unconventional superconductivity in magic-angle twisted tri-layer graphene (MATTG), a material made of three stacked and twisted atom-thin carbon sheets. Using a novel experimental platform that combines electron tunneling with electrical transport measurements, the team directly observed MATTG’s superconducting gap, which exhibits a distinctive V-shaped profile unlike the flat gap seen in conventional superconductors. This finding confirms that the superconducting mechanism in MATTG is fundamentally different and likely arises from strong electronic interactions rather than lattice vibrations, marking a crucial step toward understanding and designing new superconductors. This research advances the global pursuit of room-temperature superconductors, which could revolutionize technology by enabling zero-energy-loss power grids, practical quantum computers, and more efficient medical imaging devices. The study, led by MIT physicists including Jeong Min Park and Shuwen Sun and senior author Pablo Jarillo-Herrero, builds on the emerging field of “twistronics