Observation of Superconducting Solitons by Terahertz-Light-Driven Persistent Pseudo-Spin Coherence
- URL: http://arxiv.org/abs/2507.22383v1
- Date: Wed, 30 Jul 2025 04:55:55 GMT
- Title: Observation of Superconducting Solitons by Terahertz-Light-Driven Persistent Pseudo-Spin Coherence
- Authors: M. Mootz, C. Vaswani, C. Huang, K. J. Lee, A. Khatri, P. Mandal, J. H. Kang, L. Luo, I. E. Perakis, C. B. Eom, J. Wang,
- Abstract summary: We report the observation of a driven soliton state in epitaxial films of an iron-based superconductor.<n>The transition to this soliton state is marked by the emergence of Floquet-like spectral sidebands.
- Score: 0.619788266425984
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Overcoming the decoherence bottleneck remains a central challenge for advancing coherent superconducting quantum device and information technologies. Solitons -- non-dispersive wave packets stabilized by the collective synchronization of quantum excitations -- offer a robust pathway to mitigating dephasing, yet their realization in superconductors has remained experimentally elusive. Here, we report the observation of a driven soliton state in epitaxial thin films of an iron-based superconductor (Co-doped BaFe$_2$As$_2$), induced by intense, multi-cycle terahertz (THz) periodic driving. The dynamical transition to this soliton state is marked by the emergence of Floquet-like spectral sidebands that exhibit a strongly nonlinear dependence on THz laser field strength and a resonant enhancement with temperature. Quantum kinetic simulations corroborate these observations, allowing us to underpin the emergence of synchronized Anderson pseudo-spin oscillations -- analogous to Dicke superradiance -- mediated by persistent order parameter oscillations. In this coherently driven state, the observed sidebands result from difference-frequency mixing between the THz drive and persistent soliton dynamics. These findings establish a robust framework for coherently driving and controlling superconducting soliton time-crystal-like phases using low dissipation, time-periodic THz fields, enabling prospects for THz-speed quantum gate operations, long-lived quantum memory, and robust quantum sensing based on enhanced macroscopic pseudo-spin coherence.
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