Semiconductor nanocrystals, also known as colloidal quantum dots (QDs), have opened up a new realm of possibilities in the field of quantum physics. The concept of size-dependent quantum effects has long been understood by physicists, but it was not until the discovery of QDs that these theoretical ideas could be transformed into tangible nanodimensional objects.

Over the years, researchers worldwide have been delving into the realm of quantum effects and phenomena using QDs as the material platform. These quantum effects include single-photon emission and quantum coherence manipulation, which have significant implications in the field of quantum physics and technology.

One of the major challenges in the field of quantum physics has been the direct observation of Floquet states, which are essential in explaining quantum phenomena related to the interaction between light and matter. Experimental techniques have been limited, with researchers resorting to complex time- and angle-resolved photoemission spectroscopy in low-temperature, high-vacuum environments to observe these states.

In a groundbreaking study published in Nature Photonics, Prof. Wu Kaifeng and his colleagues from the Dalian Institute of Chemical Physics of the Chinese Academy of Sciences reported the first direct observation of Floquet states in semiconductors using all-optical spectroscopy under ambient conditions. This study marks a significant milestone in the field of quantum physics and semiconductor research.

The researchers utilized quasi-two-dimensional colloidal nanoplatelets, which have atomically precise quantum confinement in the thickness dimension. This unique property results in interband and intersubband transitions in the visible and near-infrared regions, respectively, forming a three-level system that allows for the direct observation of Floquet states.

The study not only provides an all-optical direct observation of Floquet states in semiconductor materials but also uncovers the rich spectral and dynamic physics of these states. This discovery opens up new possibilities for dynamically controlling optical responses and coherent evolution in condensed-matter systems, potentially revolutionizing the field of quantum engineering.

The ability to observe Floquet states in colloidal materials under ambient conditions expands the potential for Floquet engineering. This advancement can lead to the tailoring of quantum and topological properties in solid-state materials and the coherent control of surface/interfacial chemical reactions through nonresonant light fields.

The discovery of Floquet states in semiconductor nanocrystals represents a significant advancement in the field of quantum physics and semiconductor research. This groundbreaking study paves the way for further exploration and manipulation of quantum effects, opening up new possibilities for controlling optical responses and coherent evolution in condensed-matter systems.

Science

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