The Breakthrough of Direct Observation of Floquet States in Semiconductors

The Breakthrough of Direct Observation of Floquet States in Semiconductors

The field of solution-processed semiconductor nanocrystals, also known as colloidal quantum dots (QDs), has changed the landscape of quantum effects. While physicists had long understood the concept of size-dependent quantum effects, the realization of this theory into tangible nanodimensional objects was a challenge until the discovery of QDs. These QDs exhibit size-dependent colors that visually display the quantum size effect under ambient conditions. In recent years, researchers worldwide have been exploring various quantum effects using QDs, such as single-photon emission and quantum coherence manipulation.

One of the key phenomena in the study of quantum effects is the Floquet states, which are photon-dressed states that explain coherent interaction between light fields and matter. While Floquet states have been widely theorized, their direct observation has been an experimental hurdle. Recent studies have shown experimental signatures of Floquet-Bloch bands in materials like black phosphorus only under extreme conditions, such as low-temperature, high-vacuum environments, and specific infrared, terahertz, or microwave fields to prevent sample damage.

In a groundbreaking study published in Nature Photonics, Prof. Wu Kaifeng and his team from the Dalian Institute of Chemical Physics of the Chinese Academy of Sciences achieved the first direct observation of Floquet states in semiconductors using all-optical spectroscopy under ambient conditions. The researchers utilized quasi-two-dimensional colloidal nanoplatelets with precise quantum confinement, enabling interband and intersubband transitions in the visible and near-infrared regions.

Experimental Findings

The study revealed that a visible sub-bandgap photon dressed a heavy-hole state to a Floquet state, which could be probed by a near-infrared photon through its transition to another quantized electron state. Surprisingly, the researchers observed dephasing of the Floquet state into real population within hundreds of femtoseconds, contrary to previous assumptions about the transient nature of Floquet states.

Implications and Future Directions

Prof. Wu emphasized the significance of this study, not only for the direct observation of Floquet states in semiconductors but also for uncovering the dynamic physics of these states. The ability to control optical responses and coherent evolution in condensed-matter systems through Floquet states opens up new avenues for engineering quantum and topological properties.

The breakthrough in direct observation of Floquet states in semiconductor materials under ambient conditions represents a significant advancement in the field of quantum effects. This study not only expands the understanding of quantum phenomena but also offers potential applications in controlling surface and interfacial chemical reactions through non-resonant light fields.The thorough analysis and experimentation conducted by Prof. Wu and his team pave the way for further research in utilizing Floquet states for dynamic control in various material systems.

Science

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