Evidence of Floquet electronic steady states in graphene under continuous-wave mid-infrared irradiation
ORAL
Abstract
Light-induced phenomena in materials can exhibit exotic behavior that extends beyond equilibrium properties, offering new avenues for understanding and controlling electronic phases. So far, non-equilibrium phenomena in solids have been predominantly explored using femtosecond laser pulses, which generate transient, ultra-fast dynamics. Here, we investigate the steady non-equilibrium regime in graphene induced by a continuous-wave (CW) mid-infrared laser. Our transport measurements reveal signatures of a long-lived Floquet phase, where a non-equilibrium electronic population is stabilized by the interplay between coherent photoexcitation and incoherent phonon cooling. The observation of non-equilibrium steady states using CW lasers opens a new regime for low-temperature Floquet phenomena, paving the way toward Floquet engineering of steady-state phases of matter.
*We acknowledge support from NSF (projects DMR CMP #2104755, DMR CMP #2104770, and OSI #2329006), FondeCyT (Chile) through grant number 1211038, and the Institute for Quantum Information and Matter, an NSF Physics Frontiers Center (PHY-2317110). The National High Magnetic Field Laboratory (NHMFL) is supported by the National Science Foundation through NSF/DMR-1644779, NSF/DMR-2128556 and the State of Florida. CY is supported by the DOE NNSA Stewardship Science Graduate Fellowship program, which is provided under cooperative agreement number DE-NA0003960.
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Publication:Y. Liu, C. Yang, G. Gaertner, J. Huckabee, A. V. Suslov, G. Refael, F. Nathan, C. Lewandowski, L. E. F. Foa Torres, I. Esin, P. Barbara, N. G. Kalugin, "Evidence of Floquet electronic steady states in graphene under continuous-wave mid-infrared irradiation," arXiv:2410.13930 (2024)
