Chen, Y., Zhu, Z., & Viebahn, K. (2024). Mitigating higher-band heating in Floquet-Hubbard lattices via two-tone driving. arXiv preprint arXiv:2410.12308.
This research paper investigates the effectiveness of a two-tone driving method for mitigating heating to higher energy bands in strongly driven, strongly interacting Fermi-Hubbard systems. The authors aim to determine if this technique, previously demonstrated in non-interacting or weakly driven systems, can improve ground-state coherence in the presence of strong interactions.
The researchers conducted experiments using ultracold potassium-40 atoms loaded into a three-dimensional optical lattice. They implemented a two-frequency driving scheme, with a strong primary drive at frequency ω and a weaker "cancelling" drive at 3ω. By varying the strength of the cancelling drive and the interaction strength between atoms (Hubbard U), they measured the resulting population of atoms excited to the higher energy p-band. The experimental findings were compared with theoretical simulations using exact diagonalization of a two-band Fermi-Hubbard model.
The study demonstrates the potential of two-tone driving for mitigating heating in strongly driven, strongly interacting quantum systems, a crucial step towards realizing robust Floquet engineering protocols. The observed dependence of the optimal cancelling parameters on interaction strength highlights the need for new theoretical approaches to fully capture the physics of these complex systems.
This research contributes to the field of Floquet engineering by providing experimental evidence for a technique to mitigate a major obstacle - heating - in the quest to engineer novel quantum states of matter. The findings have implications for various platforms beyond cold atoms, including condensed matter and quantum optics, where periodic driving is employed.
The theoretical model used in the study simplifies the experimental system by neglecting certain factors like band-dependent interactions and higher-order tunneling terms. Future research could explore these aspects in more detail. Additionally, investigating the performance of the two-tone method with more complex driving waveforms and in higher dimensional systems could further advance the field.
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by Yuanning Che... ที่ arxiv.org 10-17-2024
https://arxiv.org/pdf/2410.12308.pdfสอบถามเพิ่มเติม